Product Description
Product Description
Product Description
| Item | Shaft, axle |
| Application | Cranes, Railway way, mineral Machinery, hydraulic Machinery, Spare parts etc. |
| Design | Can be at the customer’ request, tailor-made, at customer’s design |
| Material | Stainless Steel or Carbon Steel, such as 45#, 65# SAE4140, SAE4150, SAE4160, 42CrMo, stainless steel 410, stainless steel 304, or other required steel |
| Size | Diameter 80mm to 2000mm. Length max.in 6000mm |
| Minimum order | 1Pcs |
Product Real Shot
Manufacturing Process
- Free forged or module forged
- Rough machining process, to remove the surface forged oxidized black leather.
- 100% Ultrasonic Test ASTMA388
- Heat Treatment according to request, Normalized, Quenched, Tempered….
- Hardness test
- Finishing Process to the dimensional state required by the drawing.
- 100% Magnetic Test ASTM E709 and 100% dimensional test
- Painting or oil protecting TECTYL 506 or similiar
- Packing with boxes
Data Needed for Quotation
– Your own drawing
– Your requirement on material and necessary dimensional data
– Ask for recommend
Company Profile
ZheJiang CZPT Machinery Co., Ltd., established in the year of 2012, is a professional supplier of material handling equipment, OEM machinery parts, various forging parts and casting parts.
Ebon’s products scope: cranes, hoists, magnets, grabs, hooks, wheels, drums, axles, lifting beams,bearing box, bearings, couplings,flanges etc. They are applied in wide range of field: Machinery, Mining, Hydro power Transportation, Construction…..
CZPT has 5 reliable manufacturing factories to make sure stable supply and fast delivery for your business.
Our products are also exported to USA, Britain, Japan, South Korea, Russia, Indonesia, Thailand, India, Vietnam, Canada, Argentina, Paraguay etc more than 50 countries.
CZPT team is loyal and committed to your success, and firmly believes that our products and services will increase the value and effectiveness of your business with following characters:
-Professional sales team, market promotion team and logistics team with more then 10 years experience .
-Loyal and Responsible Characters
-Efficient Work, Fast Response
-Responsible Quality Control Team
-Video the manufacturing process, the testing, and packing before delivery
1.Q: How about your delivery time?
A: Generally, it will take 7-30 days after receiving your advance payment. The specific delivery time depends on the items, transportation ways and the quantity of your order.
2.Q: Can you produce according to the samples?
A: Yes, we can produce by your samples or technical drawings.
3.Q: Do you test all your goods before delivery?
A: Yes, we have 100% Ultrasonic test, Magnetic test or Liquid Penetration test before delivery
4.Q: How do you make our business long-term and good relationship?
A: (1) We keep good quality and competitive price to ensure our customers benefit ;
(2) We respect every customer as our friend and we sincerely do business and make friends with them, no matter where they come from.
5.Q: I can’t see the goods or touch the goods, how can I deal with the risk involved?
A: Our quality management system conforms to the requirement of ISO 9001:2015 verified by DNV. We are absolutely worth your trust. We can accept trial order to enhance mutual trust.
| Processing Object: | Metal |
|---|---|
| Molding Style: | Forging |
| Molding Technics: | Pressure Casting |
| Application: | Machinery Parts |
| Material: | Steel |
| Heat Treatment: | Quenching |
| Customization: |
Available
| Customized Request |
|---|
Analytical Approaches to Estimating Contact Pressures in Spline Couplings
A spline coupling is a type of mechanical connection between two rotating shafts. It consists of two parts – a coupler and a coupling. Both parts have teeth which engage and transfer loads. However, spline couplings are typically over-dimensioned, which makes them susceptible to fatigue and static behavior. Wear phenomena can also cause the coupling to fail. For this reason, proper spline coupling design is essential for achieving optimum performance.
Modeling a spline coupling
Spline couplings are becoming increasingly popular in the aerospace industry, but they operate in a slightly misaligned state, causing both vibrations and damage to the contact surfaces. To solve this problem, this article offers analytical approaches for estimating the contact pressures in a spline coupling. Specifically, this article compares analytical approaches with pure numerical approaches to demonstrate the benefits of an analytical approach.
To model a spline coupling, first you create the knowledge base for the spline coupling. The knowledge base includes a large number of possible specification values, which are related to each other. If you modify one specification, it may lead to a warning for violating another. To make the design valid, you must create a spline coupling model that meets the specified specification values.
After you have modeled the geometry, you must enter the contact pressures of the two spline couplings. Then, you need to determine the position of the pitch circle of the spline. In Figure 2, the centre of the male coupling is superposed to that of the female spline. Then, you need to make sure that the alignment meshing distance of the two splines is the same.
Once you have the data you need to create a spline coupling model, you can begin by entering the specifications for the interface design. Once you have this data, you need to choose whether to optimize the internal spline or the external spline. You’ll also need to specify the tooth friction coefficient, which is used to determine the stresses in the spline coupling model 20. You should also enter the pilot clearance, which is the clearance between the tip 186 of a tooth 32 on one spline and the feature on the mating spline.
After you have entered the desired specifications for the external spline, you can enter the parameters for the internal spline. For example, you can enter the outer diameter limit 154 of the major snap 54 and the minor snap 56 of the internal spline. The values of these parameters are displayed in color-coded boxes on the Spline Inputs and Configuration GUI screen 80. Once the parameters are entered, you’ll be presented with a geometric representation of the spline coupling model 20.
Creating a spline coupling model 20
The spline coupling model 20 is created by a product model software program 10. The software validates the spline coupling model against a knowledge base of configuration-dependent specification constraints and relationships. This report is then input to the ANSYS stress analyzer program. It lists the spline coupling model 20’s geometric configurations and specification values for each feature. The spline coupling model 20 is automatically recreated every time the configuration or performance specifications of the spline coupling model 20 are modified.
The spline coupling model 20 can be configured using the product model software program 10. A user specifies the axial length of the spline stack, which may be zero, or a fixed length. The user also enters a radial mating face 148, if any, and selects a pilot clearance specification value of 14.5 degrees or 30 degrees.
A user can then use the mouse 110 to modify the spline coupling model 20. The spline coupling knowledge base contains a large number of possible specification values and the spline coupling design rule. If the user tries to change a spline coupling model, the model will show a warning about a violation of another specification. In some cases, the modification may invalidate the design.
In the spline coupling model 20, the user enters additional performance requirement specifications. The user chooses the locations where maximum torque is transferred for the internal and external splines 38 and 40. The maximum torque transfer location is determined by the attachment configuration of the hardware to the shafts. Once this is selected, the user can click “Next” to save the model. A preview of the spline coupling model 20 is displayed.
The model 20 is a representation of a spline coupling. The spline specifications are entered in the order and arrangement as specified on the spline coupling model 20 GUI screen. Once the spline coupling specifications are entered, the product model software program 10 will incorporate them into the spline coupling model 20. This is the last step in spline coupling model creation.
Analysing a spline coupling model 20
An analysis of a spline coupling model consists of inputting its configuration and performance specifications. These specifications may be generated from another computer program. The product model software program 10 then uses its internal knowledge base of configuration dependent specification relationships and constraints to create a valid three-dimensional parametric model 20. This model contains information describing the number and types of spline teeth 32, snaps 34, and shoulder 36.
When you are analysing a spline coupling, the software program 10 will include default values for various specifications. The spline coupling model 20 comprises an internal spline 38 and an external spline 40. Each of the splines includes its own set of parameters, such as its depth, width, length, and radii. The external spline 40 will also contain its own set of parameters, such as its orientation.
Upon selecting these parameters, the software program will perform various analyses on the spline coupling model 20. The software program 10 calculates the nominal and maximal tooth bearing stresses and fatigue life of a spline coupling. It will also determine the difference in torsional windup between an internal and an external spline. The output file from the analysis will be a report file containing model configuration and specification data. The output file may also be used by other computer programs for further analysis.
Once these parameters are set, the user enters the design criteria for the spline coupling model 20. In this step, the user specifies the locations of maximum torque transfer for both the external and internal spline 38. The maximum torque transfer location depends on the configuration of the hardware attached to the shafts. The user may enter up to four different performance requirement specifications for each spline.
The results of the analysis show that there are two phases of spline coupling. The first phase shows a large increase in stress and vibration. The second phase shows a decline in both stress and vibration levels. The third stage shows a constant meshing force between 300N and 320N. This behavior continues for a longer period of time, until the final stage engages with the surface.
Misalignment of a spline coupling
A study aimed to investigate the position of the resultant contact force in a spline coupling engaging teeth under a steady torque and rotating misalignment. The study used numerical methods based on Finite Element Method (FEM) models. It produced numerical results for nominal conditions and parallel offset misalignment. The study considered two levels of misalignment – 0.02 mm and 0.08 mm – with different loading levels.
The results showed that the misalignment between the splines and rotors causes a change in the meshing force of the spline-rotor coupling system. Its dynamics is governed by the meshing force of splines. The meshing force of a misaligned spline coupling is related to the rotor-spline coupling system parameters, the transmitting torque, and the dynamic vibration displacement.
Despite the lack of precise measurements, the misalignment of splines is a common problem. This problem is compounded by the fact that splines usually feature backlash. This backlash is the result of the misaligned spline. The authors analyzed several splines, varying pitch diameters, and length/diameter ratios.
A spline coupling is a two-dimensional mechanical system, which has positive backlash. The spline coupling is comprised of a hub and shaft, and has tip-to-root clearances that are larger than the backlash. A form-clearance is sufficient to prevent tip-to-root fillet contact. The torque on the splines is transmitted via friction.
When a spline coupling is misaligned, a torque-biased thrust force is generated. In such a situation, the force can exceed the torque, causing the component to lose its alignment. The two-way transmission of torque and thrust is modeled analytically in the present study. The analytical approach provides solutions that can be integrated into the design process. So, the next time you are faced with a misaligned spline coupling problem, make sure to use an analytical approach!
In this study, the spline coupling is analyzed under nominal conditions without a parallel offset misalignment. The stiffness values obtained are the percentage difference between the nominal pitch diameter and load application diameter. Moreover, the maximum percentage difference in the measured pitch diameter is 1.60% under a torque of 5000 N*m. The other parameter, the pitch angle, is taken into consideration in the calculation.
editor by CX 2023-05-23
China Durable Internal Propeller Drive Spline Gear Drive Shaft with Hot selling
Item Description
Merchandise Description
Product Parameters
| Merchandise | Spur Gear Axle Shaft |
| Material | 4140,4340,40Cr,42Crmo,42Crmo4,20Cr,20CrMnti, 20Crmo,35Crmo |
| OEM NO | Customize |
| Certification | ISO/TS16949 |
| Take a look at Necessity | Magnetic Powder Test, Hardness Check, Dimension Take a look at |
| Colour | Paint , Natural Finish ,Machining All About |
| Materials | Aluminum: 5000series(5052…)/6000series(6061…)/7000series(7075…) |
| Steel: Carbon Metal,Middle Steel,Steel Alloy,and so forth. | |
| Stainess Steel: 303/304/316,and so forth. | |
| Copper/Brass/Bronze/Purple Copper,and so on. | |
| Plastic:Ab muscles,PP,Laptop,Nylon,Delrin(POM),Bakelite,and many others. | |
| Dimensions | According to Customer’s drawing or samples |
| Process | CNC machining,Turning,Milling,Stamping,Grinding,Welding,Wire Injection,Chopping,and many others. |
| Tolerance | ≥+/-.03mm |
| Area Therapy | (Sandblast)&(Hard)&(Shade)Anodizing,(Chrome,Nickel,Zinc…)Plating,Painting,Powder Coating,Sprucing,Blackened,Hardened,Lasering,Engraving,etc. |
| File Formats | ProE,SolidWorks,UG,CAD,PDF(IGS,X-T,STP,STL) |
| Sample | Accessible |
| Packing | Spline protect cover ,Wood box ,Waterproof membrane Or for every customers’ requirements. |
Our Advantages
Why Decide on US ???
1. Equipment :
Our company features all required generation products,
which includes Hydraulic push machines, Japanese CNC lathe (TAKISAWA), Korean gear hobbing equipment (I SNT), equipment shaping device, machining centre, CNC grinder, heat treatment line and so on.
two. Processing precision:
We are a professional equipment & equipment shafts manufacturer. Our gears are about 6-7 grade in mass creation.
three. Company:
We have ninety employees, which includes 10 technical staffs. Covering an location of 20000 square meters.
four. Certification :
Oue organization has handed ISO 14001 and TS16949
5.Sample support :
We offer totally free sample for confirmation and client bears the freight charges
six.OEM provider :
Getting our very own manufacturing facility and specialist professionals,we welcome OEM orders as effectively.We can layout and produce the distinct product you want according to your element data
Cooperation Spouse
Business Profile
Our Highlighted Items
|
US $1 / Piece | |
50 Pieces (Min. Order) |
###
| Material: | Alloy Steel |
|---|---|
| Load: | Drive Shaft |
| Axis Shape: | Straight Shaft |
| Appearance Shape: | Round |
| Rotation: | Cw |
| Yield: | 5, 000PCS / Month |
###
| Samples: |
US$ 0/Piece
1 Piece(Min.Order) |
|---|
###
| Customization: |
Available
|
|---|
###
| Item | Spur Gear Axle Shaft |
| Material | 4140,4340,40Cr,42Crmo,42Crmo4,20Cr,20CrMnti, 20Crmo,35Crmo |
| OEM NO | Customize |
| Certification | ISO/TS16949 |
| Test Requirement | Magnetic Powder Test, Hardness Test, Dimension Test |
| Color | Paint , Natural Finish ,Machining All Around |
| Material | Aluminum: 5000series(5052…)/6000series(6061…)/7000series(7075…) |
| Steel: Carbon Steel,Middle Steel,Steel Alloy,etc. | |
| Stainess Steel: 303/304/316,etc. | |
| Copper/Brass/Bronze/Red Copper,etc. | |
| Plastic:ABS,PP,PC,Nylon,Delrin(POM),Bakelite,etc. | |
| Size | According to Customer’s drawing or samples |
| Process | CNC machining,Turning,Milling,Stamping,Grinding,Welding,Wire Injection,Cutting,etc. |
| Tolerance | ≥+/-0.03mm |
| Surface Treatment | (Sandblast)&(Hard)&(Color)Anodizing,(Chrome,Nickel,Zinc…)Plating,Painting,Powder Coating,Polishing,Blackened,Hardened,Lasering,Engraving,etc. |
| File Formats | ProE,SolidWorks,UG,CAD,PDF(IGS,X-T,STP,STL) |
| Sample | Available |
| Packing | Spline protect cover ,Wood box ,Waterproof membrane; Or per customers’ requirements. |
|
US $1 / Piece | |
50 Pieces (Min. Order) |
###
| Material: | Alloy Steel |
|---|---|
| Load: | Drive Shaft |
| Axis Shape: | Straight Shaft |
| Appearance Shape: | Round |
| Rotation: | Cw |
| Yield: | 5, 000PCS / Month |
###
| Samples: |
US$ 0/Piece
1 Piece(Min.Order) |
|---|
###
| Customization: |
Available
|
|---|
###
| Item | Spur Gear Axle Shaft |
| Material | 4140,4340,40Cr,42Crmo,42Crmo4,20Cr,20CrMnti, 20Crmo,35Crmo |
| OEM NO | Customize |
| Certification | ISO/TS16949 |
| Test Requirement | Magnetic Powder Test, Hardness Test, Dimension Test |
| Color | Paint , Natural Finish ,Machining All Around |
| Material | Aluminum: 5000series(5052…)/6000series(6061…)/7000series(7075…) |
| Steel: Carbon Steel,Middle Steel,Steel Alloy,etc. | |
| Stainess Steel: 303/304/316,etc. | |
| Copper/Brass/Bronze/Red Copper,etc. | |
| Plastic:ABS,PP,PC,Nylon,Delrin(POM),Bakelite,etc. | |
| Size | According to Customer’s drawing or samples |
| Process | CNC machining,Turning,Milling,Stamping,Grinding,Welding,Wire Injection,Cutting,etc. |
| Tolerance | ≥+/-0.03mm |
| Surface Treatment | (Sandblast)&(Hard)&(Color)Anodizing,(Chrome,Nickel,Zinc…)Plating,Painting,Powder Coating,Polishing,Blackened,Hardened,Lasering,Engraving,etc. |
| File Formats | ProE,SolidWorks,UG,CAD,PDF(IGS,X-T,STP,STL) |
| Sample | Available |
| Packing | Spline protect cover ,Wood box ,Waterproof membrane; Or per customers’ requirements. |
Stiffness and Torsional Vibration of Spline-Couplings
In this paper, we describe some basic characteristics of spline-coupling and examine its torsional vibration behavior. We also explore the effect of spline misalignment on rotor-spline coupling. These results will assist in the design of improved spline-coupling systems for various applications. The results are presented in Table 1.
Stiffness of spline-coupling
The stiffness of a spline-coupling is a function of the meshing force between the splines in a rotor-spline coupling system and the static vibration displacement. The meshing force depends on the coupling parameters such as the transmitting torque and the spline thickness. It increases nonlinearly with the spline thickness.
A simplified spline-coupling model can be used to evaluate the load distribution of splines under vibration and transient loads. The axle spline sleeve is displaced a z-direction and a resistance moment T is applied to the outer face of the sleeve. This simple model can satisfy a wide range of engineering requirements but may suffer from complex loading conditions. Its asymmetric clearance may affect its engagement behavior and stress distribution patterns.
The results of the simulations show that the maximum vibration acceleration in both Figures 10 and 22 was 3.03 g/s. This results indicate that a misalignment in the circumferential direction increases the instantaneous impact. Asymmetry in the coupling geometry is also found in the meshing. The right-side spline’s teeth mesh tightly while those on the left side are misaligned.
Considering the spline-coupling geometry, a semi-analytical model is used to compute stiffness. This model is a simplified form of a classical spline-coupling model, with submatrices defining the shape and stiffness of the joint. As the design clearance is a known value, the stiffness of a spline-coupling system can be analyzed using the same formula.
The results of the simulations also show that the spline-coupling system can be modeled using MASTA, a high-level commercial CAE tool for transmission analysis. In this case, the spline segments were modeled as a series of spline segments with variable stiffness, which was calculated based on the initial gap between spline teeth. Then, the spline segments were modelled as a series of splines of increasing stiffness, accounting for different manufacturing variations. The resulting analysis of the spline-coupling geometry is compared to those of the finite-element approach.
Despite the high stiffness of a spline-coupling system, the contact status of the contact surfaces often changes. In addition, spline coupling affects the lateral vibration and deformation of the rotor. However, stiffness nonlinearity is not well studied in splined rotors because of the lack of a fully analytical model.
Characteristics of spline-coupling
The study of spline-coupling involves a number of design factors. These include weight, materials, and performance requirements. Weight is particularly important in the aeronautics field. Weight is often an issue for design engineers because materials have varying dimensional stability, weight, and durability. Additionally, space constraints and other configuration restrictions may require the use of spline-couplings in certain applications.
The main parameters to consider for any spline-coupling design are the maximum principal stress, the maldistribution factor, and the maximum tooth-bearing stress. The magnitude of each of these parameters must be smaller than or equal to the external spline diameter, in order to provide stability. The outer diameter of the spline must be at least four inches larger than the inner diameter of the spline.
Once the physical design is validated, the spline coupling knowledge base is created. This model is pre-programmed and stores the design parameter signals, including performance and manufacturing constraints. It then compares the parameter values to the design rule signals, and constructs a geometric representation of the spline coupling. A visual model is created from the input signals, and can be manipulated by changing different parameters and specifications.
The stiffness of a spline joint is another important parameter for determining the spline-coupling stiffness. The stiffness distribution of the spline joint affects the rotor’s lateral vibration and deformation. A finite element method is a useful technique for obtaining lateral stiffness of spline joints. This method involves many mesh refinements and requires a high computational cost.
The diameter of the spline-coupling must be large enough to transmit the torque. A spline with a larger diameter may have greater torque-transmitting capacity because it has a smaller circumference. However, the larger diameter of a spline is thinner than the shaft, and the latter may be more suitable if the torque is spread over a greater number of teeth.
Spline-couplings are classified according to their tooth profile along the axial and radial directions. The radial and axial tooth profiles affect the component’s behavior and wear damage. Splines with a crowned tooth profile are prone to angular misalignment. Typically, these spline-couplings are oversized to ensure durability and safety.
Stiffness of spline-coupling in torsional vibration analysis
This article presents a general framework for the study of torsional vibration caused by the stiffness of spline-couplings in aero-engines. It is based on a previous study on spline-couplings. It is characterized by the following three factors: bending stiffness, total flexibility, and tangential stiffness. The first criterion is the equivalent diameter of external and internal splines. Both the spline-coupling stiffness and the displacement of splines are evaluated by using the derivative of the total flexibility.
The stiffness of a spline joint can vary based on the distribution of load along the spline. Variables affecting the stiffness of spline joints include the torque level, tooth indexing errors, and misalignment. To explore the effects of these variables, an analytical formula is developed. The method is applicable for various kinds of spline joints, such as splines with multiple components.
Despite the difficulty of calculating spline-coupling stiffness, it is possible to model the contact between the teeth of the shaft and the hub using an analytical approach. This approach helps in determining key magnitudes of coupling operation such as contact peak pressures, reaction moments, and angular momentum. This approach allows for accurate results for spline-couplings and is suitable for both torsional vibration and structural vibration analysis.
The stiffness of spline-coupling is commonly assumed to be rigid in dynamic models. However, various dynamic phenomena associated with spline joints must be captured in high-fidelity drivetrain models. To accomplish this, a general analytical stiffness formulation is proposed based on a semi-analytical spline load distribution model. The resulting stiffness matrix contains radial and tilting stiffness values as well as torsional stiffness. The analysis is further simplified with the blockwise inversion method.
It is essential to consider the torsional vibration of a power transmission system before selecting the coupling. An accurate analysis of torsional vibration is crucial for coupling safety. This article also discusses case studies of spline shaft wear and torsionally-induced failures. The discussion will conclude with the development of a robust and efficient method to simulate these problems in real-life scenarios.
Effect of spline misalignment on rotor-spline coupling
In this study, the effect of spline misalignment in rotor-spline coupling is investigated. The stability boundary and mechanism of rotor instability are analyzed. We find that the meshing force of a misaligned spline coupling increases nonlinearly with spline thickness. The results demonstrate that the misalignment is responsible for the instability of the rotor-spline coupling system.
An intentional spline misalignment is introduced to achieve an interference fit and zero backlash condition. This leads to uneven load distribution among the spline teeth. A further spline misalignment of 50um can result in rotor-spline coupling failure. The maximum tensile root stress shifted to the left under this condition.
Positive spline misalignment increases the gear mesh misalignment. Conversely, negative spline misalignment has no effect. The right-handed spline misalignment is opposite to the helix hand. The high contact area is moved from the center to the left side. In both cases, gear mesh is misaligned due to deflection and tilting of the gear under load.
This variation of the tooth surface is measured as the change in clearance in the transverse plain. The radial and axial clearance values are the same, while the difference between the two is less. In addition to the frictional force, the axial clearance of the splines is the same, which increases the gear mesh misalignment. Hence, the same procedure can be used to determine the frictional force of a rotor-spline coupling.
Gear mesh misalignment influences spline-rotor coupling performance. This misalignment changes the distribution of the gear mesh and alters contact and bending stresses. Therefore, it is essential to understand the effects of misalignment in spline couplings. Using a simplified system of helical gear pair, Hong et al. examined the load distribution along the tooth interface of the spline. This misalignment caused the flank contact pattern to change. The misaligned teeth exhibited deflection under load and developed a tilting moment on the gear.
The effect of spline misalignment in rotor-spline couplings is minimized by using a mechanism that reduces backlash. The mechanism comprises cooperably splined male and female members. One member is formed by two coaxially aligned splined segments with end surfaces shaped to engage in sliding relationship. The connecting device applies axial loads to these segments, causing them to rotate relative to one another.
editor by czh 2023-03-31
China Hot Sale Sym Gear Shaft Spline Gear Zl30D-11-09 Drive Shaft drive shaft adapter
Problem: New
Guarantee: 1 Yr
Relevant Industries: Building Content Stores, Producing Plant
Weight (KG): 2.3
Showroom Location: None
Video clip outgoing-inspection: Offered
Equipment Check Report: Supplied
Marketing Kind: Common Item
Guarantee of main factors: 1 Yr
Core Parts: equipment
Materials: steel
Model Variety: ZL30D-11-09
Measurement: Shaft diameter within a hundred and twenty
Packaging Specifics: Interior packing: plastic bag + carton + picket scenario
Specification
| Place of Origin | China.ZheJiang |
| model | ZL30D-eleven-09 |
| color | Steel shade, customizable |
| shape | Long axis |
| material | steel |
| size | Shaft diameter within 120 |
The Functions of Splined Shaft Bearings
Splined shafts are the most common types of bearings for machine tools. They are made of a wide variety of materials, including metals and non-metals such as Delrin and nylon. They are often fabricated to reduce deflection. The tooth profile will become deformed with time, as the shaft is used over a long period of time. Splined shafts are available in a huge range of materials and lengths.
Functions
Splined shafts are used in a variety of applications and industries. They are an effective anti-rotational device, as well as a reliable means of transmitting torque. Other types of shafts are available, including key shafts, but splines are the most convenient for transmitting torque. The following article discusses the functions of splines and why they are a superior choice. Listed below are a few examples of applications and industries in which splines are used.
Splined shafts can be of several styles, depending on the application and mechanical system in question. The differences between splined shaft styles include the design of teeth, overall strength, transfer of rotational concentricity, sliding ability, and misalignment tolerance. Listed below are a few examples of splines, as well as some of their benefits. The difference between these styles is not mutually exclusive; instead, each style has a distinct set of pros and cons.
A splined shaft is a cylindrical shaft with teeth or ridges that correspond to a specific angular position. This allows a shaft to transfer torque while maintaining angular correspondence between tracks. A splined shaft is defined as a cylindrical member with several grooves cut into its circumference. These grooves are equally spaced around the shaft and form a series of projecting keys. These features give the shaft a rounded appearance and allow it to fit perfectly into a grooved cylindrical member.
While the most common applications of splines are for shortening or extending shafts, they can also be used to secure mechanical assemblies. An “involute spline” spline has a groove that is wider than its counterparts. The result is that a splined shaft will resist separation during operation. They are an ideal choice for applications where deflection is an issue.
A spline shaft’s radial torsion load distribution is equally distributed, unless a bevel gear is used. The radial torsion load is evenly distributed and will not exert significant load concentration. If the spline couplings are not aligned correctly, the spline connection can fail quickly, causing significant fretting fatigue and wear. A couple of papers discuss this issue in more detail.
Types
There are many different types of splined shafts. Each type features an evenly spaced helix of grooves on its outer surface. These grooves are either parallel or involute. Their shape allows them to be paired with gears and interchange rotary and linear motion. Splines are often cold-rolled or cut. The latter has increased strength compared to cut spines. These types of shafts are commonly used in applications requiring high strength, accuracy, and smoothness.
Another difference between internal and external splined shafts lies in the manufacturing process. The former is made of wood, while the latter is made of steel or a metal alloy. The process of manufacturing splined shafts involves cutting furrows into the surface of the material. Both processes are expensive and require expert skill. The main advantage of splined shafts is their adaptability to a wide range of applications.
In general, splined shafts are used in machinery where the rotation is transferred to an internal splined member. This member can be a gear or some other rotary device. These types of shafts are often packaged together as a hub assembly. Cleaning and lubricating are essential to the life of these components. If you’re using them on a daily basis, you’ll want to make sure to regularly inspect them.
Crowned splines are usually involute. The teeth of these splines form a spiral pattern. They are used for smaller diameter shafts because they add strength. Involute splines are also used on instrument drives and valve shafts. Serration standards are found in the SAE. Both kinds of splines can also contain a ball bearing for high torque. The difference between the two types of splines is the number of teeth on the shaft.
Internal splines have many advantages over external ones. For example, an internal spline shaft can be made using a grinding wheel instead of a CNC machine. It also uses a more accurate and economical process. Furthermore, it allows for a shorter manufacturing cycle, which is essential when splining high-speed machines. In addition, it stabilizes the relative phase between the spline and thread.
Manufacturing methods
There are several methods used to fabricate a splined shaft. Key and splined shafts are constructed from two separate parts that are shaped in a synchronized manner to transfer torque uniformly. Hot rolling is one method, while cold rolling utilizes low temperatures to form metal. Both methods enhance mechanical properties, surface finishes, and precision. The advantage of cold rolling is its cost-effectiveness.
Cold forming is one method, as well as machining and assembling. Cold forming is a unique process that allows the spline to be shaped to the desired shape. The resulting shape provides maximum contact area and torsional strength. Standard splines are available in standard sizes, but custom lengths can also be ordered. CZPT offers various auxiliary equipment, such as mating sleeves and flanged bushings.
Cold forging is another method. This method produces long splined shafts that are used in automobile propellers. After the spline portion is cut out, it is worked on in a hobbing machine. Work hardening enhances the root strength of the splined portion. It can be used for bearings, gears, and other mechanical components. Listed below are the manufacturing methods for splined shafts.
Parallel splines are the simplest of the splined shaft manufacturing methods. Parallel splines are usually welded to shafts, while involute splines are made of metal or non-metals. Splines are available in a wide variety of lengths and materials. The process is usually accompanied by a process called milling. The workpiece rotates to produce the serrated surface.
Splines are internal or external grooves in a splined shaft. They work in combination with keyways to transfer torque. Male and female splines are used in gears. Female and male splines correspond to one another to ensure proper angular correspondence. Involute splines have more surface area and thus are stronger than external splines. Moreover, they help the shaft fit into a grooved cylindrical member without misalignment.
A variety of other methods of manufacturing a splined shaft can be used to produce a splined shaft. Spline shafts can be produced using broaching and shaping, two precision machining methods. Broaching uses a metal tool with successively larger teeth to remove metal and create ridges and holes in the surface of a material. However, this process is expensive and requires special expertise.
Applications
The splined shaft is a mechanical component with a helix-like shape formed by the equal spacing of grooves in a circular ring. The splines can either have parallel or involute sides. The splines minimize stress concentration in stationary joints and can be used in both rotary and linear motion. In some cases, splines are rolled rather than cut. The latter is more durable than cut splines and is often used in applications requiring high strength, accuracy, and smooth finish.
Splined shafts are commonly made of carbon steel. This alloy steel has a low carbon content, making it easy to work with. Carbon steel is a great choice for splines because it is malleable. Generally, high-quality carbon steel provides a consistent motion. Steel alloys are also available that contain nickel, chromium, copper, and other metals. If you’re unsure of the right material for your application, you can consult a spline chart.
Splines are a versatile mechanical component. They are easy to cut and fit. Splines can be internal or external, with teeth positioned at equal intervals on both sides of the shaft. This allows the shaft to engage with the hub around the entire circumference of the hub. It also increases load capacity by creating a constant multiple-tooth point of contact with the hub. For this reason, they’re used extensively in rotary and linear motion.
Splined shafts are used in a wide variety of industries. CZPT Inc. offers custom and standard splined shafts for a variety of applications. When choosing a splined shaft for a specific application, consider the surrounding mated components, torque requirements, and size requirements. These three factors will make it the ideal choice for your rotary equipment. And you’ll be pleased with the end result!
There are many types of splines and their applications are endless. They transfer torque and angular misalignment between parts, and they also enable the axial rotation of assembled components. Therefore, splines are an essential component of machinery and are used in a wide range of applications. This type of shaft can be found in various types of machines, from household appliances to industrial machinery. So, the next time you’re looking for a splined shaft, make sure you look for a splined one.
editor by czh 2023-02-19
China hot sale BM6-800 BMT hydraulic gear pump motor in injection drive shaft axle
Stress: shaft
Framework: hydraulic back
Fat: 32 KGS
Dimension(L*W*H): five hundred*250*250 mm
Guarantee: 1.5 many years, 1.5 several years
Showroom Location: None
Motor Variety: Equipment MOTOR
Displacement: 800, 195 ~ 985 Ml/r
Highest Stream Charge: 698 rpm
Solution title: BM6-800 Hydraulic Motor
Variety: 6000 series , OMT
Application: Medium to Heavy Responsibility Duties
Connection: Regular motor, Wheel motor, Brake motor, Bearingless motor
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Feature: Minimal Speed-higher Torque
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Layout Functions.1. Compact in design and style with disc valving and Geroler 2. Large force capacityshaft seal 3. Style and manufacture of the spline and drives give the motor toughness 4. Wide selection of mounting flanges ,shafts ,ports and velocity offers style flexibility 5. Path of shaft rotation and velocity can be managed simply and efficiently 6. Best blend of higher performance and economic climate in medium duty software SMT(BMT,6000 series)Advantages. 1、Advanced Roller stator Design2、Various option of cc. Flange ,shaft and port3、Constant operating torque4、 High radial and axial bearing ability 5、Long life beneath intense running issue 6、 Custom-made Service is suitable Specification Info.
| Displ.cm3/r | 195 | 245 | 310 | 390 | 490 | 625 | 800 | 985 | ||
| FLOWLPM | Continuous | 150 | 150 | 150 | 150 | 150 | 150 | 150 | 150 | |
| Intermittent | 170 | 210 | 225 | 225 | 225 | 225 | 225 | 225 | ||
| RPMMaxspeed | Continuous | 775 | 615 | 698 | 387 | 307 | 241 | 184 | 153 | |
| Intermittent | 866 | 834 | 485 | 570 | 454 | 355 | 278 | 230 | ||
| Pressure Bar | Continuous | 170 | 170 | 170 | 170 | 170 | 120 | 120 | 120 | |
| Intermittent | 275 | 275 | 275 | 275 | 240 | 140 | 140 | 140 | ||
| TorqueNm | Continuous | 475 | 615 | 775 | 965 | 1215 | 1125 | 1380 | 1570 | |
| Intermittent | 770 | 980 | 1225 | 1455 | 1685 | 1330 | 1650 | 1875 | ||
| Weight kg | 28.one | 28.six | 29.two | 30 | 30.nine | 32.1 | 32.5 | 33.five | ||
The Benefits of Spline Couplings for Disc Brake Mounting Interfaces
Spline couplings are commonly used for securing disc brake mounting interfaces. Spline couplings are often used in high-performance vehicles, aeronautics, and many other applications. However, the mechanical benefits of splines are not immediately obvious. Listed below are the benefits of spline couplings. We’ll discuss what these advantages mean for you. Read on to discover how these couplings work.
Disc brake mounting interfaces are splined
There are two common disc brake mounting interfaces – splined and six-bolt. Splined rotors fit on splined hubs; six-bolt rotors will need an adapter to fit on six-bolt hubs. The six-bolt method is easier to maintain and may be preferred by many cyclists. If you’re thinking of installing a disc brake system, it is important to know how to choose the right splined and center lock interfaces.
Aerospace applications
The splines used for spline coupling in aircraft are highly complex. While some previous researches have addressed the design of splines, few publications have tackled the problem of misaligned spline coupling. Nevertheless, the accurate results we obtained were obtained using dedicated simulation tools, which are not commercially available. Nevertheless, such tools can provide a useful reference for our approach. It would be beneficial if designers could use simple tools for evaluating contact pressure peaks. Our analytical approach makes it possible to find answers to such questions.
The design of a spline coupling for aerospace applications must be accurate to minimize weight and prevent failure mechanisms. In addition to weight reduction, it is necessary to minimize fretting fatigue. The pressure distribution on the spline coupling teeth is a significant factor in determining its fretting fatigue. Therefore, we use analytical and experimental methods to examine the contact pressure distribution in the axial direction of spline couplings.
The teeth of a spline coupling can be categorized by the type of engagement they provide. This study investigates the position of resultant contact forces in the teeth of a spline coupling when applied to pitch diameter. Using FEM models, numerical results are generated for nominal and parallel offset misalignments. The axial tooth profile determines the behavior of the coupling component and its ability to resist wear. Angular misalignment is also a concern, causing misalignment.
In order to assess wear damage of a spline coupling, we must take into consideration the impact of fretting on the components. This wear is caused by relative motion between the teeth that engage them. The misalignment may be caused by vibrations, cyclical tooth deflection, or angular misalignment. The result of this analysis may help designers improve their spline coupling designs and develop improved performance.
CZPT polyimide, an abrasion-resistant polymer, is a popular choice for high-temperature spline couplings. This material reduces friction and wear, provides a low friction surface, and has a low wear rate. Furthermore, it offers up to 50 times the life of metal on metal spline connections. For these reasons, it is important to choose the right material for your spline coupling.
High-performance vehicles
A spline coupler is a device used to connect splined shafts. A typical spline coupler resembles a short pipe with splines on either end. There are two basic types of spline coupling: single and dual spline. One type attaches to a drive shaft, while the other attaches to the gearbox. While spline couplings are typically used in racing, they’re also used for performance problems.
The key challenge in spline couplings is to determine the optimal dimension of spline joints. This is difficult because no commercial codes allow the simulation of misaligned joints, which can destroy components. This article presents analytical approaches to estimating contact pressures in spline connections. The results are comparable with numerical approaches but require special codes to accurately model the coupling operation. This research highlights several important issues and aims to make the application of spline couplings in high-performance vehicles easier.
The stiffness of spline assemblies can be calculated using tooth-like structures. Such splines can be incorporated into the spline joint to produce global stiffness for torsional vibration analysis. Bearing reactions are calculated for a certain level of misalignment. This information can be used to design bearing dimensions and correct misalignment. There are three types of spline couplings.
Major diameter fit splines are made with tightly controlled outside diameters. This close fit provides concentricity transfer from the male to the female spline. The teeth of the male spline usually have chamfered tips and clearance with fillet radii. These splines are often manufactured from billet steel or aluminum. These materials are renowned for their strength and uniform grain created by the forging process. ANSI and DIN design manuals define classes of fit.
Disc brake mounting interfaces
A spline coupling for disc brake mounting interfaces is a type of hub-to-brake-disc mount. It is a highly durable coupling mechanism that reduces heat transfer from the disc to the axle hub. The mounting arrangement also isolates the axle hub from direct contact with the disc. It is also designed to minimize the amount of vehicle downtime and maintenance required to maintain proper alignment.
Disc brakes typically have substantial metal-to-metal contact with axle hub splines. The discs are held in place on the hub by intermediate inserts. This metal-to-metal contact also aids in the transfer of brake heat from the brake disc to the axle hub. Spline coupling for disc brake mounting interfaces comprises a mounting ring that is either a threaded or non-threaded spline.
During drag brake experiments, perforated friction blocks filled with various additive materials are introduced. The materials included include Cu-based powder metallurgy material, a composite material, and a Mn-Cu damping alloy. The filling material affects the braking interface’s wear behavior and friction-induced vibration characteristics. Different filling materials produce different types of wear debris and have different wear evolutions. They also differ in their surface morphology.
Disc brake couplings are usually made of two different types. The plain and HD versions are interchangeable. The plain version is the simplest to install, while the HD version has multiple components. The two-piece couplings are often installed at the same time, but with different mounting interfaces. You should make sure to purchase the appropriate coupling for your vehicle. These interfaces are a vital component of your vehicle and must be installed correctly for proper operation.
Disc brakes use disc-to-hub elements that help locate the forces and displace them to the rim. These elements are typically made of stainless steel, which increases the cost of manufacturing the disc brake mounting interface. Despite their benefits, however, the high braking force loads they endure are hard on the materials. Moreover, excessive heat transferred to the intermediate elements can adversely affect the fatigue life and long-term strength of the brake system.
editor by czh 2023-02-18
China High Precision Metal Processing Automatic Competitive Gear Spline Shaft Forming Equipment Factory with Hot selling
CNC or Not: CNC
Issue: New
Kind: Equipment Milling Machine
Video outgoing-inspection: Supplied
Equipment Check Report: Presented
Advertising and marketing Kind: Ordinary Merchandise
Warranty of core parts: 1 Yr
Main Components: Gearbox, Motor
Guarantee: 1 12 months
Essential Offering Points: Computerized
Excess weight (KG): 35 124410571 the device tool CZPT rail adopts higher-frequency quenching remedy, and thesurface hardness is higher to extend the provider lifestyle of the CZPT rail area. Milling instrument publish and topThe copper (sleeve bearing and inHangZhou turbine) workpieces employed in the equipment tool are created of ZQsn6-6-3 tin bronze, which will increase the support existence of the additional bed and the workpiece. The primary rotating areas of the equipment device are pushed by spiral arc bevel equipment, and the torque is enhanced to minimize wear and sounds. Company Profile HangZhou Hokang Machinery focusing on the plHangZhou, R&D and production of intelligent creation traces for industrial equipment, it has senior plHangZhou engineers, structural engineers, electrical engineers and senior assembly, commissioning, and following-product sales service teams.we have computer software specialist technological staff, a group of university instructors, a generation line plHangZhou engineering staff of production enterprises, and a advertising and marketing crew. Our team has provided a comprehensive established of remedies for a quantity of producing enterprises in the creation line digitalmanufacturing method and the total back-end packaging line, acknowledging the ideal relationship among the creation details administration program at the government stage of the company workshop and versatile production! Customer Photographs FAQ 1. who are we?We are dependent in ZheJiang , China, begin from 2571, Personalized produced for CZPT Heavenly Sword 125JYM125-working day halberd YBR125 bike market to Southeast Asia(twenty.00%),North The us(fifteen.00%),SouthAmerica(15.00%),Africa(15.00%),Domestic Market place(ten.00%),Jap Europe(5.00%),Mid East(5.00%),South Asia(5.00%),Central The united states(3.00%),Oceania(2.00%),Western Europe(2.00%),Japanese Asia(1.00%),Northern Europe(1.00%),Southern Europe(1.00%). There are overall about 11-50 people in our office.2. how can we promise top quality?Often a pre-manufacturing sample just before mass productionAlways final Inspection ahead of shipment3.what can you get from us?various industrial device, cnc device resources, roll forming machine, JGY-15BY micro stepper motor 2 Stage 4 Wire Self-locking reducer gearbox All Steel large torque lower sound gearbox motor foodstuff equipment, packing machine and so on.4. why ought to you buy from us not from other suppliers?HangZhou Hokang Machinery Co.,Ltd. focus on one-stop services remedies for distinct industrial machine, plHangZhou, R&D and manufacturing of smart creation traces for industrial equipment, it has senior plHangZhou engineers,structural engineers, electrical engineers and senior assembly,5. what solutions can we give?Acknowledged Shipping and delivery Conditions: FOB,CFR,CIF,EXW,Express Delivery;Accepted Payment Currency:USD,EUR,CNYAccepted Payment Variety: T/T, Roller chain assembly line stainless steel carbon steel plastic double attachment bending plate double pitch conveyor chain MoneyGramLanguage Spoken:English,Chinese
The Benefits of Spline Couplings for Disc Brake Mounting Interfaces
Spline couplings are commonly used for securing disc brake mounting interfaces. Spline couplings are often used in high-performance vehicles, aeronautics, and many other applications. However, the mechanical benefits of splines are not immediately obvious. Listed below are the benefits of spline couplings. We’ll discuss what these advantages mean for you. Read on to discover how these couplings work.
Disc brake mounting interfaces are splined
There are two common disc brake mounting interfaces – splined and six-bolt. Splined rotors fit on splined hubs; six-bolt rotors will need an adapter to fit on six-bolt hubs. The six-bolt method is easier to maintain and may be preferred by many cyclists. If you’re thinking of installing a disc brake system, it is important to know how to choose the right splined and center lock interfaces.
Aerospace applications
The splines used for spline coupling in aircraft are highly complex. While some previous researches have addressed the design of splines, few publications have tackled the problem of misaligned spline coupling. Nevertheless, the accurate results we obtained were obtained using dedicated simulation tools, which are not commercially available. Nevertheless, such tools can provide a useful reference for our approach. It would be beneficial if designers could use simple tools for evaluating contact pressure peaks. Our analytical approach makes it possible to find answers to such questions.
The design of a spline coupling for aerospace applications must be accurate to minimize weight and prevent failure mechanisms. In addition to weight reduction, it is necessary to minimize fretting fatigue. The pressure distribution on the spline coupling teeth is a significant factor in determining its fretting fatigue. Therefore, we use analytical and experimental methods to examine the contact pressure distribution in the axial direction of spline couplings.
The teeth of a spline coupling can be categorized by the type of engagement they provide. This study investigates the position of resultant contact forces in the teeth of a spline coupling when applied to pitch diameter. Using FEM models, numerical results are generated for nominal and parallel offset misalignments. The axial tooth profile determines the behavior of the coupling component and its ability to resist wear. Angular misalignment is also a concern, causing misalignment.
In order to assess wear damage of a spline coupling, we must take into consideration the impact of fretting on the components. This wear is caused by relative motion between the teeth that engage them. The misalignment may be caused by vibrations, cyclical tooth deflection, or angular misalignment. The result of this analysis may help designers improve their spline coupling designs and develop improved performance.
CZPT polyimide, an abrasion-resistant polymer, is a popular choice for high-temperature spline couplings. This material reduces friction and wear, provides a low friction surface, and has a low wear rate. Furthermore, it offers up to 50 times the life of metal on metal spline connections. For these reasons, it is important to choose the right material for your spline coupling.
High-performance vehicles
A spline coupler is a device used to connect splined shafts. A typical spline coupler resembles a short pipe with splines on either end. There are two basic types of spline coupling: single and dual spline. One type attaches to a drive shaft, while the other attaches to the gearbox. While spline couplings are typically used in racing, they’re also used for performance problems.
The key challenge in spline couplings is to determine the optimal dimension of spline joints. This is difficult because no commercial codes allow the simulation of misaligned joints, which can destroy components. This article presents analytical approaches to estimating contact pressures in spline connections. The results are comparable with numerical approaches but require special codes to accurately model the coupling operation. This research highlights several important issues and aims to make the application of spline couplings in high-performance vehicles easier.
The stiffness of spline assemblies can be calculated using tooth-like structures. Such splines can be incorporated into the spline joint to produce global stiffness for torsional vibration analysis. Bearing reactions are calculated for a certain level of misalignment. This information can be used to design bearing dimensions and correct misalignment. There are three types of spline couplings.
Major diameter fit splines are made with tightly controlled outside diameters. This close fit provides concentricity transfer from the male to the female spline. The teeth of the male spline usually have chamfered tips and clearance with fillet radii. These splines are often manufactured from billet steel or aluminum. These materials are renowned for their strength and uniform grain created by the forging process. ANSI and DIN design manuals define classes of fit.
Disc brake mounting interfaces
A spline coupling for disc brake mounting interfaces is a type of hub-to-brake-disc mount. It is a highly durable coupling mechanism that reduces heat transfer from the disc to the axle hub. The mounting arrangement also isolates the axle hub from direct contact with the disc. It is also designed to minimize the amount of vehicle downtime and maintenance required to maintain proper alignment.
Disc brakes typically have substantial metal-to-metal contact with axle hub splines. The discs are held in place on the hub by intermediate inserts. This metal-to-metal contact also aids in the transfer of brake heat from the brake disc to the axle hub. Spline coupling for disc brake mounting interfaces comprises a mounting ring that is either a threaded or non-threaded spline.
During drag brake experiments, perforated friction blocks filled with various additive materials are introduced. The materials included include Cu-based powder metallurgy material, a composite material, and a Mn-Cu damping alloy. The filling material affects the braking interface’s wear behavior and friction-induced vibration characteristics. Different filling materials produce different types of wear debris and have different wear evolutions. They also differ in their surface morphology.
Disc brake couplings are usually made of two different types. The plain and HD versions are interchangeable. The plain version is the simplest to install, while the HD version has multiple components. The two-piece couplings are often installed at the same time, but with different mounting interfaces. You should make sure to purchase the appropriate coupling for your vehicle. These interfaces are a vital component of your vehicle and must be installed correctly for proper operation.
Disc brakes use disc-to-hub elements that help locate the forces and displace them to the rim. These elements are typically made of stainless steel, which increases the cost of manufacturing the disc brake mounting interface. Despite their benefits, however, the high braking force loads they endure are hard on the materials. Moreover, excessive heat transferred to the intermediate elements can adversely affect the fatigue life and long-term strength of the brake system.
editor by czh 2023-02-18
China 385-10234561 komatsu loader pump WA90L loader excavator gear pump with Hot selling
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Issue: New
After Warranty Support: Video clip complex assistance
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The Different Types of Splines in a Splined Shaft
A splined shaft is a machine component with internal and external splines. The splines are formed in four different ways: Involute, Parallel, Serrated, and Ball. You can learn more about each type of spline in this article. When choosing a splined shaft, be sure to choose the right one for your application. Read on to learn about the different types of splines and how they affect the shaft’s performance.
Involute splines
Involute splines in a splined shaft are used to secure and extend mechanical assemblies. They are smooth, inwardly curving grooves that resist separation during operation. A shaft with involute splines is often longer than the shaft itself. This feature allows for more axial movement. This is beneficial for many applications, especially in a gearbox.
The involute spline is a shaped spline, similar to a parallel spline. It is angled and consists of teeth that create a spiral pattern that enables linear and rotatory motion. It is distinguished from other splines by the serrations on its flanks. It also has a flat top. It is a good option for couplers and other applications where angular movement is necessary.
Involute splines are also called involute teeth because of their shape. They are flat on the top and curved on the sides. These teeth can be either internal or external. As a result, involute splines provide greater surface contact, which helps reduce stress and fatigue. Regardless of the shape, involute splines are generally easy to machine and fit.
Involute splines are a type of splines that are used in splined shafts. These splines have different names, depending on their diameters. An example set of designations is for a 32-tooth male spline, a 2,500-tooth module, and a 30 degree pressure angle. An example of a female spline, a fillet root spline, is used to describe the diameter of the splined shaft.
The effective tooth thickness of splines is dependent on the number of keyways and the type of spline. Involute splines in splined shafts should be designed to engage 25 to 50 percent of the spline teeth during the coupling. Involute splines should be able to withstand the load without cracking.
Parallel splines
Parallel splines are formed on a splined shaft by putting one or more teeth into another. The male spline is positioned at the center of the female spline. The teeth of the male spline are also parallel to the shaft axis, but a common misalignment causes the splines to roll and tilt. This is common in many industrial applications, and there are a number of ways to improve the performance of splines.
Typically, parallel splines are used to reduce friction in a rotating part. The splines on a splined shaft are narrower on the end face than the interior, which makes them more prone to wear. This type of spline is used in a variety of industries, such as machinery, and it also allows for greater efficiency when transmitting torque.
Involute splines on a splined shaft are the most common. They have equally spaced teeth, and are therefore less likely to crack due to fatigue. They also tend to be easy to cut and fit. However, they are not the best type of spline. It is important to understand the difference between parallel and involute splines before deciding on which spline to use.
The difference between splined and involute splines is the size of the grooves. Involute splines are generally larger than parallel splines. These types of splines provide more torque to the gear teeth and reduce stress during operation. They are also more durable and have a longer life span. And because they are used on farm machinery, they are essential in this type of application.
Serrated splines
A Serrated Splined Shaft has several advantages. This type of shaft is highly adjustable. Its large number of teeth allows large torques, and its shorter tooth width allows for greater adjustment. These features make this type of shaft an ideal choice for applications where accuracy is critical. Listed below are some of the benefits of this type of shaft. These benefits are just a few of the advantages. Learn more about this type of shaft.
The process of hobbing is inexpensive and highly accurate. It is useful for external spline shafts, but is not suitable for internal splines. This type of process forms synchronized shapes on the shaft, reducing the manufacturing cycle and stabilizing the relative phase between spline and thread. It uses a grinding wheel to shape the shaft. CZPT Manufacturing has a large inventory of Serrated Splined Shafts.
The teeth of a Serrated Splined Shaft are designed to engage with the hub over the entire circumference of the shaft. The teeth of the shaft are spaced uniformly around the spline, creating a multiple-tooth point of contact over the entire length of the shaft. The results of these analyses are usually satisfactory. But there are some limitations. To begin with, the splines of the Serrated Splined Shaft should be chosen carefully. If the application requires large-scale analysis, it may be necessary to modify the design.
The splines of the Serrated Splined Shaft are also used for other purposes. They can be used to transmit torque to another device. They also act as an anti-rotational device and function as a linear guide. Both the design and the type of splines determine the function of the Splined Shaft. In the automobile industry, they are used in vehicles, aerospace, earth-moving machinery, and many other industries.
Ball splines
The invention relates to a ball-spinned shaft. The shaft comprises a plurality of balls that are arranged in a series and are operatively coupled to a load path section. The balls are capable of rolling endlessly along the path. This invention also relates to a ball bearing. Here, a ball bearing is one of the many types of gears. The following discussion describes the features of a ball bearing.
A ball-splined shaft assembly comprises a shaft with at least one ball-spline groove and a plurality of circumferential step grooves. The shaft is held in a first holding means that extends longitudinally and is rotatably held by a second holding means. Both the shaft and the first holding means are driven relative to one another by a first driving means. It is possible to manufacture a ball-splined shaft in a variety of ways.
A ball-splined shaft features a nut with recirculating balls. The ball-splined nut rides in these grooves to provide linear motion while preventing rotation. A splined shaft with a nut that has recirculating balls can also provide rotary motion. A ball splined shaft also has higher load capacities than a ball bushing. For these reasons, ball splines are an excellent choice for many applications.
In this invention, a pair of ball-spinned shafts are housed in a box under a carrier device 40. Each of the two shafts extends along a longitudinal line of arm 50. One end of each shaft is supported rotatably by a slide block 56. The slide block also has a support arm 58 that supports the center arm 50 in a cantilever fashion.
Sector no-go gage
A no-go gauge is a tool that checks the splined shaft for oversize. It is an effective way to determine the oversize condition of a splined shaft without removing the shaft. It measures external splines and serrations. The no-go gage is available in sizes ranging from 19mm to 130mm with a 25mm profile length.
The sector no-go gage has two groups of diametrally opposed teeth. The space between them is manufactured to a maximum space width and the tooth thickness must be within a predetermined tolerance. This gage would be out of tolerance if the splines were measured with a pin. The dimensions of this splined shaft can be found in the respective ANSI or DIN standards.
The go-no-go gage is useful for final inspection of thread pitch diameter. It is also useful for splined shafts and threaded nuts. The thread of a screw must match the contour of the go-no-go gage head to avoid a no-go condition. There is no substitute for a quality machine. It is an essential tool for any splined shaft and fastener manufacturer.
The NO-GO gage can detect changes in tooth thickness. It can be calibrated under ISO17025 standards and has many advantages over a non-go gage. It also gives a visual reference of the thickness of a splined shaft. When the teeth match, the shaft is considered ready for installation. It is a critical process. In some cases, it is impossible to determine the precise length of the shaft spline.
The 45-degree pressure angle is most commonly used for axles and torque-delivering members. This pressure angle is the most economical in terms of tool life, but the splines will not roll neatly like a 30 degree angle. The 45-degree spline is more likely to fall off larger than the other two. Oftentimes, it will also have a crowned look. The 37.5 degree pressure angle is a compromise between the other two pressure angles. It is often used when the splined shaft material is harder than usual.
editor by czh 2023-02-15
China Totem Spline Shaft, Spline Driving Shaft, Spline Gear Shaft with Hot selling
Merchandise Description
Item Description
Eccentric Axles Shaft, Hollow Shaft/Crankshaft for marine & vessel engine Processing
Camshaft drawing Check out, Make Forging Mildew, Forging Mildew High quality Inspection Verify, Equipment Processing, Examine SizeHardnessSurface Finish and other technical parameters on drawing.
Massive Maritime Vessel Shaft Package deal
Spray anti-rust oil on Eccentric Shaft for crusher, Wrap water-proof cloth around Shaft for CZPT crusher, Put together package deal by shaft form & weight to choose metal body, steel assistance or wood box and so forth.
OEM Tailored Eccentric Shaft
We provide OEM Provider, tailored forging eccentric shaft much more than 1tons massive bodyweight, much more than 3m length, 42CrMo/35CrMo or your specified necessary content of Bent Axle .
Detailed Pictures
Item Parameters
| Size | L | Range: >1m |
| Excess weight | Kg | Variety: >100kg/ Solitary Piece |
| Shaft form | Eccentric Shaft | |
| Materials | Forging 42CrMo/40Cr or Customized | |
| Heat Remedy | Normalizing, Tempering, Induction Harden, and so forth | |
| Sand Blasting | Null | |
| Tests | UTMT | |
| Trademark | TOTEM/OEM | |
| Software | Stone Crusher, Grate Cooler and so forth | |
| Transportation Package deal | Export package (steel body, wood box, etc.) | |
| Origin | China | |
| HS Code | 8483409000 |
TOTEM Service
TOTEM Machinery all the time works to source Gear SHAFT, ECCENTRIC SHAFT, HERRINGBONE Gear, BEVEL Equipment, Interior Equipment and other elements for transmission system & equipment (huge industrial reducer & driver). Which largely use to industrial tools on fields of port facilities, cement, mining, metallurgical market etc.
TOTEM Equipment invests and turns into shareholders of numerous machine processing factories, forging factories, casting factories, relies on these sturdy reliable and high-quality suppliers’ community, to enable consumers fret-cost-free acquire.
TOTEM Philosophy: Good quality-No.1, Integrity- No.1, Support- No.1
24hrs Salesman on-line, assure quick and good feedback. Knowledgeable and Expert Forwarder Ensure Log. transportation.
About TOTEM
1. Workshop & Processing Toughness
two. Testing Services
3. Consumer Inspection & Shipping
Speak to TOTEM
ZheJiang CZPT Machinery Co.,Ltd
Fb: ZheJiang Totem
FAQ
What’s CZPT item processing progress?
Drawing Verify, Make Forging Mould, Forging Mold High quality Inspection Verify, Equipment Processing, Examine SizeHardnessSurface Complete and other technological parameters on drawing.
How about TOTEM’s export package deal?
Spray anti-rust oil on Herringbone Equipment Shaft, Wrap watertight fabric about Equipment Shaft for reducer, Get ready deal by shaft shape&excess weight to select steel frame, steel assistance or picket box and many others.
Could I customize geargear shaft on TOTEM?
We supply tailored Equipment Shaft,Eccentric Shaft,Herringbone Equipment,Inner Equipment,Bevel Gear with large module, much more than 1tons large weight, much more than 3m duration, forging or casting 42CrMo/35CrMo or your specified required substance.
Why can I choose TOTEM?
TOTEM has 24hrs Salesman on-line, ensure rapid and good opinions.
TOTEM Equipment invests and turns into shareholders of numerous device processing factories, forging factories, casting factories, depends on these sturdy trustworthy and high-high quality supplier’s network, to let buyers worry-totally free acquire.
Seasoned and Specialist Forwarder Assure Log. transportation.
|
US $66-588 / Piece | |
1 Piece (Min. Order) |
###
| After-sales Service: | Avaliable |
|---|---|
| Standard: | GB, GOST, ASTM, DIN |
| Surface Treatment: | Normalizing, Tempering, Induction Harden |
| Manufacturing Process: | Forging |
| Material: | Forging |
| Transport Package: | Export Package |
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| Customization: |
Available
|
|---|
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| Length | L | Range: >1m |
| Weight | Kg | Range: >100kg/ Single Piece |
| Shaft shape | Eccentric Shaft | |
| Material | Forging 42CrMo/40Cr or Customized | |
| Heat Treatment | Normalizing, Tempering, Induction Harden, etc | |
| Sand Blasting | Null | |
| Testing | UT\MT | |
| Trademark | TOTEM/OEM | |
| Application | Stone Crusher, Grate Cooler etc | |
| Transport Package | Export package (steel frame, wooden box, etc.) | |
| Origin | China | |
| HS Code | 8483409000 |
|
US $66-588 / Piece | |
1 Piece (Min. Order) |
###
| After-sales Service: | Avaliable |
|---|---|
| Standard: | GB, GOST, ASTM, DIN |
| Surface Treatment: | Normalizing, Tempering, Induction Harden |
| Manufacturing Process: | Forging |
| Material: | Forging |
| Transport Package: | Export Package |
###
| Customization: |
Available
|
|---|
###
| Length | L | Range: >1m |
| Weight | Kg | Range: >100kg/ Single Piece |
| Shaft shape | Eccentric Shaft | |
| Material | Forging 42CrMo/40Cr or Customized | |
| Heat Treatment | Normalizing, Tempering, Induction Harden, etc | |
| Sand Blasting | Null | |
| Testing | UT\MT | |
| Trademark | TOTEM/OEM | |
| Application | Stone Crusher, Grate Cooler etc | |
| Transport Package | Export package (steel frame, wooden box, etc.) | |
| Origin | China | |
| HS Code | 8483409000 |
Stiffness and Torsional Vibration of Spline-Couplings
In this paper, we describe some basic characteristics of spline-coupling and examine its torsional vibration behavior. We also explore the effect of spline misalignment on rotor-spline coupling. These results will assist in the design of improved spline-coupling systems for various applications. The results are presented in Table 1.
Stiffness of spline-coupling
The stiffness of a spline-coupling is a function of the meshing force between the splines in a rotor-spline coupling system and the static vibration displacement. The meshing force depends on the coupling parameters such as the transmitting torque and the spline thickness. It increases nonlinearly with the spline thickness.
A simplified spline-coupling model can be used to evaluate the load distribution of splines under vibration and transient loads. The axle spline sleeve is displaced a z-direction and a resistance moment T is applied to the outer face of the sleeve. This simple model can satisfy a wide range of engineering requirements but may suffer from complex loading conditions. Its asymmetric clearance may affect its engagement behavior and stress distribution patterns.
The results of the simulations show that the maximum vibration acceleration in both Figures 10 and 22 was 3.03 g/s. This results indicate that a misalignment in the circumferential direction increases the instantaneous impact. Asymmetry in the coupling geometry is also found in the meshing. The right-side spline’s teeth mesh tightly while those on the left side are misaligned.
Considering the spline-coupling geometry, a semi-analytical model is used to compute stiffness. This model is a simplified form of a classical spline-coupling model, with submatrices defining the shape and stiffness of the joint. As the design clearance is a known value, the stiffness of a spline-coupling system can be analyzed using the same formula.
The results of the simulations also show that the spline-coupling system can be modeled using MASTA, a high-level commercial CAE tool for transmission analysis. In this case, the spline segments were modeled as a series of spline segments with variable stiffness, which was calculated based on the initial gap between spline teeth. Then, the spline segments were modelled as a series of splines of increasing stiffness, accounting for different manufacturing variations. The resulting analysis of the spline-coupling geometry is compared to those of the finite-element approach.
Despite the high stiffness of a spline-coupling system, the contact status of the contact surfaces often changes. In addition, spline coupling affects the lateral vibration and deformation of the rotor. However, stiffness nonlinearity is not well studied in splined rotors because of the lack of a fully analytical model.
Characteristics of spline-coupling
The study of spline-coupling involves a number of design factors. These include weight, materials, and performance requirements. Weight is particularly important in the aeronautics field. Weight is often an issue for design engineers because materials have varying dimensional stability, weight, and durability. Additionally, space constraints and other configuration restrictions may require the use of spline-couplings in certain applications.
The main parameters to consider for any spline-coupling design are the maximum principal stress, the maldistribution factor, and the maximum tooth-bearing stress. The magnitude of each of these parameters must be smaller than or equal to the external spline diameter, in order to provide stability. The outer diameter of the spline must be at least four inches larger than the inner diameter of the spline.
Once the physical design is validated, the spline coupling knowledge base is created. This model is pre-programmed and stores the design parameter signals, including performance and manufacturing constraints. It then compares the parameter values to the design rule signals, and constructs a geometric representation of the spline coupling. A visual model is created from the input signals, and can be manipulated by changing different parameters and specifications.
The stiffness of a spline joint is another important parameter for determining the spline-coupling stiffness. The stiffness distribution of the spline joint affects the rotor’s lateral vibration and deformation. A finite element method is a useful technique for obtaining lateral stiffness of spline joints. This method involves many mesh refinements and requires a high computational cost.
The diameter of the spline-coupling must be large enough to transmit the torque. A spline with a larger diameter may have greater torque-transmitting capacity because it has a smaller circumference. However, the larger diameter of a spline is thinner than the shaft, and the latter may be more suitable if the torque is spread over a greater number of teeth.
Spline-couplings are classified according to their tooth profile along the axial and radial directions. The radial and axial tooth profiles affect the component’s behavior and wear damage. Splines with a crowned tooth profile are prone to angular misalignment. Typically, these spline-couplings are oversized to ensure durability and safety.
Stiffness of spline-coupling in torsional vibration analysis
This article presents a general framework for the study of torsional vibration caused by the stiffness of spline-couplings in aero-engines. It is based on a previous study on spline-couplings. It is characterized by the following three factors: bending stiffness, total flexibility, and tangential stiffness. The first criterion is the equivalent diameter of external and internal splines. Both the spline-coupling stiffness and the displacement of splines are evaluated by using the derivative of the total flexibility.
The stiffness of a spline joint can vary based on the distribution of load along the spline. Variables affecting the stiffness of spline joints include the torque level, tooth indexing errors, and misalignment. To explore the effects of these variables, an analytical formula is developed. The method is applicable for various kinds of spline joints, such as splines with multiple components.
Despite the difficulty of calculating spline-coupling stiffness, it is possible to model the contact between the teeth of the shaft and the hub using an analytical approach. This approach helps in determining key magnitudes of coupling operation such as contact peak pressures, reaction moments, and angular momentum. This approach allows for accurate results for spline-couplings and is suitable for both torsional vibration and structural vibration analysis.
The stiffness of spline-coupling is commonly assumed to be rigid in dynamic models. However, various dynamic phenomena associated with spline joints must be captured in high-fidelity drivetrain models. To accomplish this, a general analytical stiffness formulation is proposed based on a semi-analytical spline load distribution model. The resulting stiffness matrix contains radial and tilting stiffness values as well as torsional stiffness. The analysis is further simplified with the blockwise inversion method.
It is essential to consider the torsional vibration of a power transmission system before selecting the coupling. An accurate analysis of torsional vibration is crucial for coupling safety. This article also discusses case studies of spline shaft wear and torsionally-induced failures. The discussion will conclude with the development of a robust and efficient method to simulate these problems in real-life scenarios.
Effect of spline misalignment on rotor-spline coupling
In this study, the effect of spline misalignment in rotor-spline coupling is investigated. The stability boundary and mechanism of rotor instability are analyzed. We find that the meshing force of a misaligned spline coupling increases nonlinearly with spline thickness. The results demonstrate that the misalignment is responsible for the instability of the rotor-spline coupling system.
An intentional spline misalignment is introduced to achieve an interference fit and zero backlash condition. This leads to uneven load distribution among the spline teeth. A further spline misalignment of 50um can result in rotor-spline coupling failure. The maximum tensile root stress shifted to the left under this condition.
Positive spline misalignment increases the gear mesh misalignment. Conversely, negative spline misalignment has no effect. The right-handed spline misalignment is opposite to the helix hand. The high contact area is moved from the center to the left side. In both cases, gear mesh is misaligned due to deflection and tilting of the gear under load.
This variation of the tooth surface is measured as the change in clearance in the transverse plain. The radial and axial clearance values are the same, while the difference between the two is less. In addition to the frictional force, the axial clearance of the splines is the same, which increases the gear mesh misalignment. Hence, the same procedure can be used to determine the frictional force of a rotor-spline coupling.
Gear mesh misalignment influences spline-rotor coupling performance. This misalignment changes the distribution of the gear mesh and alters contact and bending stresses. Therefore, it is essential to understand the effects of misalignment in spline couplings. Using a simplified system of helical gear pair, Hong et al. examined the load distribution along the tooth interface of the spline. This misalignment caused the flank contact pattern to change. The misaligned teeth exhibited deflection under load and developed a tilting moment on the gear.
The effect of spline misalignment in rotor-spline couplings is minimized by using a mechanism that reduces backlash. The mechanism comprises cooperably splined male and female members. One member is formed by two coaxially aligned splined segments with end surfaces shaped to engage in sliding relationship. The connecting device applies axial loads to these segments, causing them to rotate relative to one another.
editor by czh 2023-01-16
China Gear Making Transmission Gear Bevel Gear Valve Body Agricultural Machinery Metallurgical Gearbox Spline Shaft with Hot selling
Product Description
Company Profile
Company Profile
HangZhou Xihu (West Lake) Dis. Gain Machinery Co., Ltd., is a manufacture of precision machining from steel plates, castings & closed die forgings. It is founded in 2571 year, covers a total area of about 2000 square meters.
Around 50 people are employed, including 4 engineers.
The company equipped with 10 oblique CZPT CNC Lathes, 35 normal CNC lathes, 6 machining centers, other milling machines and drilling machines.
The Products cover construction parts, auto parts, medical treatment, aerospace, electronics and other fields, exported to Japan, Israel & other Asian countries and Germany, the United States, Canada & other European and American countries.
Certificated by TS16949 quality management system.
Equipment Introduction
Main facility and working range, inspection equipment as follow
| 4 axles CNC Machine Center | 1000mm*600mm*650mm |
| Oblique Xihu (West Lake) Dis. CNC Machine | max φ800mm max length 700mm Tolerance control within 0.01 One time clamping, high accuracy |
| Turning-milling Compound Machining Center | max φ800mm max length 1000mm |
| Other CNC Lathe | Total 30 sets |
| Inspection Equipment | CMM, Projector, CZPT Scale, Micrometer |
| Profiloscope, Hardness tester and so on |
Oblique Xihu (West Lake) Dis. CNC Lathe
Equipped with 10 sets of oblique CZPT CNC Lathes The maximum diameter can be 400-500 mm Precision can reach 0.01mm
Machining Center
6 sets of 4 axles machining center, max SPEC: 1300*70mm, precision can reach 0.01mm
About Products
Quality Control
We always want to be precise, so check dimensions after each production step. We have senior engineers, skilled CNC operator, professional quality inspector. All this makes sure the final goods are high qualified.
Also can do third parity inspection accoring to customer’s reequirments, such as SGS, TUV, ICAS and so on.
Callipers/Height guage
Thread guage
Go/ no go guage
Inside micrometer
Outside micrometer
Micron scale
CMM
Projector
Micrometer
Profiloscope
Hardness tester
Inspection Process
1. Before machining, the engineer will give away the technology card for each process acc. to drawing for quality control.
2. During the machining, the workers will test the dimensions at each step, then marked in the technology card.
3. When machining finished, the professional testing personnel will do 100% retesting again.
Packing Area
In general, the products will be packed in bubble wrap or separated by plywoods firstly.
Then the wrapped products will be put in the wooden cases (no solid wood), which is allowed for export.
Parts can also be packed acc. to customer’s requirement.
| To Be Negotiated | 10 Pieces (Min. Order) |
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| After-sales Service: | Compensate for Unqualified One |
|---|---|
| Warranty: | 1 Years |
| Condition: | New |
| Certification: | ISO9001 |
| Standard: | DIN, ASTM, GOST, GB, JIS |
| Customized: | Customized |
###
| Samples: |
US$ 0.1/Piece
1 Piece(Min.Order) |
|---|
###
| Customization: |
Available
|
|---|
###
| 4 axles CNC Machine Center | 1000mm*600mm*650mm |
| Oblique Guide CNC Machine | max φ800mm max length 700mm Tolerance control within 0.01 One time clamping, high accuracy |
| Turning-milling Compound Machining Center | max φ800mm max length 1000mm |
| Other CNC Lathe | Total 30 sets |
| Inspection Equipment | CMM, Projector, Micron Scale, Micrometer |
| Profiloscope, Hardness tester and so on |
| To Be Negotiated | 10 Pieces (Min. Order) |
###
| After-sales Service: | Compensate for Unqualified One |
|---|---|
| Warranty: | 1 Years |
| Condition: | New |
| Certification: | ISO9001 |
| Standard: | DIN, ASTM, GOST, GB, JIS |
| Customized: | Customized |
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| Samples: |
US$ 0.1/Piece
1 Piece(Min.Order) |
|---|
###
| Customization: |
Available
|
|---|
###
| 4 axles CNC Machine Center | 1000mm*600mm*650mm |
| Oblique Guide CNC Machine | max φ800mm max length 700mm Tolerance control within 0.01 One time clamping, high accuracy |
| Turning-milling Compound Machining Center | max φ800mm max length 1000mm |
| Other CNC Lathe | Total 30 sets |
| Inspection Equipment | CMM, Projector, Micron Scale, Micrometer |
| Profiloscope, Hardness tester and so on |
Standard Length Splined Shafts
Standard Length Splined Shafts are made from Mild Steel and are perfect for most repair jobs, custom machinery building, and many other applications. All stock splined shafts are 2-3/4 inches in length, and full splines are available in any length, with additional materials and working lengths available upon request and quotation. CZPT Manufacturing Company is proud to offer these standard length shafts.
Disc brake mounting interfaces that are splined
There are two common disc brake mounting interfaces, splined and center lock. Disc brakes with splined interfaces are more common. They are usually easier to install. The center lock system requires a tool to remove the locking ring on the disc hub. Six-bolt rotors are easier to install and require only six bolts. The center lock system is commonly used with performance road bikes.
Post mount disc brakes require a post mount adapter, while flat mount disc brakes do not. Post mount adapters are more common and are used for carbon mountain bikes, while flat mount interfaces are becoming the norm on road and gravel bikes. All disc brake adapters are adjustable for rotor size, though. Road bikes usually use 160mm rotors while mountain bikes use rotors that are 180mm or 200mm.
Disc brake mounting interfaces that are helical splined
A helical splined disc brake mounting interface is designed with a splined connection between the hub and brake disc. This splined connection allows for a relatively large amount of radial and rotational displacement between the disc and hub. A loosely splined interface can cause a rattling noise due to the movement of the disc in relation to the hub.
The splines on the brake disc and hub are connected via an air gap. The air gap helps reduce heat conduction from the brake disc to the hub. The present invention addresses problems of noise, heat, and retraction of brake discs at the release of the brake. It also addresses issues with skewing and dragging. If you’re unsure whether this type of mounting interface is right for you, consult your mechanic.
Disc brake mounting interfaces that are helix-splined may be used in conjunction with other components of a wheel. They are particularly useful in disc brake mounting interfaces for hub-to-hub assemblies. The spacer elements, which are preferably located circumferentially, provide substantially the same function no matter how the brake disc rotates. Preferably, three spacer elements are located around the brake disc. Each of these spacer elements has equal clearance between the splines of the brake disc and the hub.
Spacer elements 6 include a helical spring portion 6.1 and extensions in tangential directions that terminate in hooks 6.4. These hooks abut against the brake disc 1 in both directions. The helical spring portion 5.1 and 6.1 have stiffness enough to absorb radial impacts. The spacer elements are arranged around the circumference of the intermeshing zone.
A helical splined disc mount includes a stabilizing element formed as a helical spring. The helical spring extends to the disc’s splines and teeth. The ends of the extension extend in opposite directions, while brackets at each end engage with the disc’s splines and teeth. This stabilizing element is positioned axially over the disc’s width.
Helical splined disc brake mounting interfaces are popular in bicycles and road bicycles. They’re a reliable, durable way to mount your brakes. Splines are widely used in aerospace, and have a higher fatigue life and reliability. The interfaces between the splined disc brake and BB spindle are made from aluminum and acetate.
As the splined hub mounts the disc in a helical fashion, the spring wire and disc 2 will be positioned in close contact. As the spring wire contacts the disc, it creates friction forces that are evenly distributed throughout the disc. This allows for a wide range of axial motion. Disc brake mounting interfaces that are helical splined have higher strength and stiffness than their counterparts.
Disc brake mounting interfaces that are helically splined can have a wide range of splined surfaces. The splined surfaces are the most common type of disc brake mounting interfaces. They are typically made of stainless steel or aluminum and can be used for a variety of applications. However, a splined disc mount will not support a disc with an oversized brake caliper.
editor by czh 2022-12-08
China Big Spline Worm Gear Shaft on Conveyor with Hot selling
Product Description
Product Description
Our Gear types: Straight Teeth Gear, sprocket, Oblique Teeth Cylinder Gear, External Spur Gear, Internal Spur Gear, Gear Shaft etc the standard and non standard according to the drawings or samples.
Material: 45#, 40Cr, 20CrMo, 20CrMoti, 17CrNiMo6, 20CrMnTi or the others
Heat treatment: Medium frequency quenching, high frequency quenching, carburizing and quenching, nitriding, Carbon-Nitriding, Salt bath quenching.
Working Process: Gearh hobbing, Gear shaving, Gear shaping, Gear grinding etc
Precision Grade: GB5-8, JIS 1-4, AGMA 12-9, DIN 6-9
Application area: Auto gearbox, medical equipment, metallurgical machinery, port machinery, lifting equipment, mining machinery, electrical power equipment, light industry equipment, environmental protection machinery.
Detailed Photos
Product Parameters
Take the example of our sprocket or chainwheel
The standard and non standard according to the drawings or samples.
Material: C45, S235JR, CAST STEEL or the others
1, Description: Sprocket, chainwheel
2, Types:
A) Standard sprocket
B) Finished bore sprocket
C) Taper bore sprocket
D) Double plate wheels
E) conveyor sprocket
3, Material: C45, S235JR, Nylon
4, Surface treatment: Zinc-plated, black finish
5, Single A-type, double A-type, Welding hub KB-type, Welding hub C-type etc for your reference.
6. Process: Forging( casting)—lathe- teeth shaping—finishing—oil washing—Packing, made by CNC machine
7. Inspection: All items are checked and tested thoroughly during every working procedure and after the product is finally manufactured to ensure that the best quality product enter into the market.
Packaging & Shipping
Our Advantages
After Sales Service
Our Core range of spur gears, industry sprocket, and roller chains are specifically designed to be interchangeable and versatile, this helps us keep lower stock levels while achieving the customization necessary for so many applications. The core offer has also enabled us to offer excellent pricing levels for low quantities, often prototypes are very expensive due to lack of economies of scale we have tried to help with this as much as possible. HangZhou CZPT can offer bespoke units for larger quantities and offer a Supply Chain service where we work closely with our customers to identify the optimal delivery schedule in accordance with OEM production levels. If you are looking for spur gear, drive shafts, industry sprocket etc, you have come to the right place, our expert technical sales staff will recommend the best possible option for both your application and your pocket. Contact us now to discuss your application.
HangZhou CZPT TRADE CO., LTD is responsible for exporting the above products, and we also import some important products from oversea markets.
Our company has got the right of import and export from the Government department.
It is necessary to get your specific requirement when contacting us,
for example of gear, number of teeth, module, pitch diameter, inner hole diameter, thickness, outside drawing etc. and then we will give the accurate offers.
Therefore, hope to get your feedback soon.
Please watch our process steps as below
(1) process these output shafts
(2)process these spur gears and sprockets
(3) turning machining
(4) assembly preparation
(5) fine process workshop
CHOOSE US FOR:
1. We offer engineer suggestion to your specified design in production improvement and cost saving.
2. R&D and QC department focus on the products to meet your strict requirements.
3. Different surface treatments available, plating, power coating, painting, anodized,polishing, electrophoresis, etc.
4. Different dimensions according to buyer’s request.
5. Various packagings according to specific requirements.
6. Customized and tailored orders are welcome.
7. Good quality and Quick action.
8. Our products have been exported to America, Australia,German,Korea,Indian.
CONFIDENTIAL POLICY:
1) The appointed products are only for you.
2) Your informations&documents are confidential.
3) Your drawings&sketch are confidential.
FAQ
Question:
1.Q:How about CZPT cost?
A: primarily depend on : 1.Drawing, 2.material, 3.weight and quantity.
We need to know the structure of each parts to analyze the mold solution by:
1) –Complete design drawing or actual sample —– the best way
–PDF drawing with complete dimension for each parts
–Clearly photos for each parts with more angle-views to show every features.
2)The materials and surface treatments.
3)The quantity of order.
2.Q:How to control the product processing?
A: The processing report or pictures will be sent to the customer every week/ each month for review.
3.Q:Who will own the mould?
A:Customer, also the CZPT can be kept in our factory for future order.
4.Q:How long do you make your quotation?
A:After receiving detail informations we will quote in 1 to 3 days.
5.Q: Are the samples/prototype free of charge?
A: charged,but it will be returned to buyer when an order confirmed and order quantity is over 5000 pcs.
After your drawing confirmed and charges done for the prototype, we will produce a sample
by CNC machining. And the first trial samples (1-3pcs) will be shipped to buyer
by the DHL /Fedex at buyer’s express account or prepay the express charges.
MOQ? — 200units and accept sample order.
| To Be Negotiated | 200 Pieces (Min. Order) |
###
| Application: | Motor, Machinery, Agricultural Machinery |
|---|---|
| Hardness: | Hardened |
| Gear Position: | External Gear |
| Manufacturing Method: | Rolling Gear |
| Toothed Portion Shape: | Spur Gear |
| Material: | Alloy Steel |
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| Samples: |
US$ 50/Piece
1 Piece(Min.Order) |
|---|
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| Customization: |
Available
|
|---|
| To Be Negotiated | 200 Pieces (Min. Order) |
###
| Application: | Motor, Machinery, Agricultural Machinery |
|---|---|
| Hardness: | Hardened |
| Gear Position: | External Gear |
| Manufacturing Method: | Rolling Gear |
| Toothed Portion Shape: | Spur Gear |
| Material: | Alloy Steel |
###
| Samples: |
US$ 50/Piece
1 Piece(Min.Order) |
|---|
###
| Customization: |
Available
|
|---|
Standard Length Splined Shafts
Standard Length Splined Shafts are made from Mild Steel and are perfect for most repair jobs, custom machinery building, and many other applications. All stock splined shafts are 2-3/4 inches in length, and full splines are available in any length, with additional materials and working lengths available upon request and quotation. CZPT Manufacturing Company is proud to offer these standard length shafts.
Disc brake mounting interfaces that are splined
There are two common disc brake mounting interfaces, splined and center lock. Disc brakes with splined interfaces are more common. They are usually easier to install. The center lock system requires a tool to remove the locking ring on the disc hub. Six-bolt rotors are easier to install and require only six bolts. The center lock system is commonly used with performance road bikes.
Post mount disc brakes require a post mount adapter, while flat mount disc brakes do not. Post mount adapters are more common and are used for carbon mountain bikes, while flat mount interfaces are becoming the norm on road and gravel bikes. All disc brake adapters are adjustable for rotor size, though. Road bikes usually use 160mm rotors while mountain bikes use rotors that are 180mm or 200mm.
Disc brake mounting interfaces that are helical splined
A helical splined disc brake mounting interface is designed with a splined connection between the hub and brake disc. This splined connection allows for a relatively large amount of radial and rotational displacement between the disc and hub. A loosely splined interface can cause a rattling noise due to the movement of the disc in relation to the hub.
The splines on the brake disc and hub are connected via an air gap. The air gap helps reduce heat conduction from the brake disc to the hub. The present invention addresses problems of noise, heat, and retraction of brake discs at the release of the brake. It also addresses issues with skewing and dragging. If you’re unsure whether this type of mounting interface is right for you, consult your mechanic.
Disc brake mounting interfaces that are helix-splined may be used in conjunction with other components of a wheel. They are particularly useful in disc brake mounting interfaces for hub-to-hub assemblies. The spacer elements, which are preferably located circumferentially, provide substantially the same function no matter how the brake disc rotates. Preferably, three spacer elements are located around the brake disc. Each of these spacer elements has equal clearance between the splines of the brake disc and the hub.
Spacer elements 6 include a helical spring portion 6.1 and extensions in tangential directions that terminate in hooks 6.4. These hooks abut against the brake disc 1 in both directions. The helical spring portion 5.1 and 6.1 have stiffness enough to absorb radial impacts. The spacer elements are arranged around the circumference of the intermeshing zone.
A helical splined disc mount includes a stabilizing element formed as a helical spring. The helical spring extends to the disc’s splines and teeth. The ends of the extension extend in opposite directions, while brackets at each end engage with the disc’s splines and teeth. This stabilizing element is positioned axially over the disc’s width.
Helical splined disc brake mounting interfaces are popular in bicycles and road bicycles. They’re a reliable, durable way to mount your brakes. Splines are widely used in aerospace, and have a higher fatigue life and reliability. The interfaces between the splined disc brake and BB spindle are made from aluminum and acetate.
As the splined hub mounts the disc in a helical fashion, the spring wire and disc 2 will be positioned in close contact. As the spring wire contacts the disc, it creates friction forces that are evenly distributed throughout the disc. This allows for a wide range of axial motion. Disc brake mounting interfaces that are helical splined have higher strength and stiffness than their counterparts.
Disc brake mounting interfaces that are helically splined can have a wide range of splined surfaces. The splined surfaces are the most common type of disc brake mounting interfaces. They are typically made of stainless steel or aluminum and can be used for a variety of applications. However, a splined disc mount will not support a disc with an oversized brake caliper.
editor by czh 2022-11-26
China high quality Extended Intermediate Shaft of The Auxiliary Gearbox Shaft Gear Fast Gearbox Transmission Middle Shaft for Auxiliary Box Accessory Drive Wheel Loader Spareparts with Hot selling
Product Description
Pricey buddies!
My identify is Irina Mamoshina. You should pay a instant of your focus : -).
Our firm HangZhou CZPT Worldwide Trade Co., Ltd is engaged in the creation and sale of car components for Chinese unique tools, engines and products assembly. We also generate metal parts ourselves, this sort of as gears, fingers, filters, and so on.
Our items incorporate:
— (Xugong) spare areas for front loaders:
ZL30G, ZL40G, ZL50G, ZL50GL, ZL60G, LW3, A, , B7615-1571/411B/Yuchai YC6B125/YC6108
| N/a | Name in Russian | Name in English | Article number | Qty |
| 1 | Болт полый | Hollow Bolt | 1119238 01119238/SP127284 | 5 |
| 2 | Генератор | Generator | 13031590 | 3 |
| 3 | Головка блока цилиндра в сборе | Cylinder head assembly | 13032055 | 12 |
| 4 | Датчик температуры | Temperature sensor | 612600090107/612600090107 | 6 |
| 5 | Держатель топливных фильтров | Fuel Filter Holder | 12189882-A/13028032 | 2 |
| 6 | Клапан задвижки топливного насоса | Fuel pump valve | TD226B-6-000 | 3 |
| 7 | Коллектор воздушный впуской | Air intake manifold | 13034462/4110000846072 | 1 |
| 8 | Коллектор впускной | Intake manifold | 13022552 | 1 |
| 9 | Коллектор выпуской | Exhaust manifold | 13057673 | 11 |
| 10 | Коромысло | Rocker arm | 12214103/13037791 | 12 |
| 11 | Крепление насоса водяного | Water pump mount block | 13025726/Deutz/TD226 | 1 |
| 12 | Крепление топливных трубок | Mounting of fuel tubes | 12165346 | 10 |
| 13 | Крепление топливных трубок | Mounting of fuel tubes | 12166451 | 10 |
| 14 | Патрубок | Branch pipe | 13033682 | 3 |
| 15 | Патрубок | Branch pipe | 13034046/4110000054257/4110001031038 | 3 |
| 16 | Патрубок системы охлаждения масла двигателя | Engine oil cooling system pipe | 13026006 | 3 |
| 17 | Патрубок тосола | Antifreeze nozzle | 12200696 | 3 |
| 18 | Поддон двигателя | Engine tray | 13036094 | 1 |
| 19 | Пробка поддона | Pallet Stopper | 13022897 | 10 |
| 20 | Прокладка адаптера водяного насоса | Water pump adapter gasket | 12158513/4110000054284/SP105131/W47070170 | 10 |
| 21 | Прокладка водяного насоса двигателя | Engine water pump gasket | 12270869/4110000054285/Weichai-Deutz | 10 |
| 22 | ТНВД | Fuel pump | 13051931/4110000846108 | 1 |
| 23 | Топливопровод | Fuel line | 13024894 | 2 |
| 24 | Трубка охлаждающей жидкости двигателя | Engine coolant tube | 13033390/4110000991012/W47002046 | 2 |
| 25 | Турбокомпрессор | Turbocharger | 13030175КН43/13030175 | 2 |
| 26 | Турбокомпрессор | Turbocharger | 13057501/12272277/K24A/13030850 | 2 |
| 27 | Фиксатор форсунки | Nozzle lock | 12159720 | 18 |
| 28 | Шестерня привода масляного насоса | Oil pump drive gear | 12189557/4110000054013/W010250790/SP128978 | 2 |
| 29 | Шкив коленвала ДВС | Crankshaft pulley of the internal combustion engine | 13032345 | 2 |
| 30 | Амортизатор капота | Hood shock absorber | 2120900570 | 20 |
| 31 | Амортизатор капота (L=480 мм) | Hood shock absorber (L=480 mm) | 29330011391 | 20 |
| 32 | Блок сателлитов бортового редуктора с шестернями (3 сателита) | On-board gearbox satellite unit with gears (3 satellites) | 29070018761 | 1 |
| 33 | Блок сателлитов бортового редуктора с шестернями | Satellite unit of the on-board gearbox with gears | 2907000765 | 1 |
| 34 | Болт | Pin | 01151569/Q150B0816 | 100 |
| 35 | Болт крепления переднего моста | Front axle mounting bolt | М30*110/29070001031 | 100 |
| 36 | Вал соеднительный КПП | Shaft connecting gearbox | 4110000160059 | 1 |
| 37 | Втулка | Bushing | 100*115*137/4043000419 | 6 |
| 38 | Втулка | Bushing | 29250009421 | 6 |
| 39 | Втулка | Bushing | 95*110*144/4043000320 | 6 |
| 40 | Втулка рулевого гидроцилиндра | Steering cylinder sleeve | 4120000560013/4120000560507 | 6 |
| 41 | Втулка рулевого гидроцилиндра | Steering cylinder sleeve | 4120001004406 | 6 |
| 42 | Гидрораспределитель | Hydraulic distributor | 4120000561/SD32-16 | 1 |
| 43 | Гидрораспределитель | Hydraulic distributor | 4120002278/YGDF32-18 | 1 |
| 44 | Гидротрансформатор (Конвертер) в корпусе | Torque converter (Converter) in the housing | 4110000084 | 1 |
| 45 | Гидроусилитель (Шлицевой) | Hydraulic booster (Splined) | BZZ3-E125B | 1 |
| 46 | Гидроцилиндр наклона | Tilt hydraulic cylinder | 4120000601/968 | 1 |
| 47 | Гидроцилиндр поворота | Hydraulic turning cylinder | 4120000560/LG953 | 1 |
| 48 | Гипоидная пара (против часовой) редуктора заднего моста | Hypoid pair (counterclockwise) of the rear axle gearbox | 21909005021 | 1 |
| 49 | Гипоидная пара (против часовой) | Hypoid pair (counterclockwise) | 29090001091/29090000081/3050900203 | 1 |
| 50 | Гипоидная пара (против часовой) | Hypoid pair (counterclockwise) | 3050900203 | 1 |
| 51 | Гипоидная пара (против часовой) | Hypoid pair (counterclockwise) | 21909004931 L | 1 |
| 52 | Гипоидная пара (по часовой) | Hypoid pair (clockwise) | 21909004931 R | 1 |
| 53 | Диск тормозной | Brake disc | 3090900009 LG946 | 2 |
| 54 | Диск тормозной | Brake disc | 918/29070010481 | 2 |
| 55 | Клапан гидрораспределителя | Hydraulic distributor valve | 4120001054001/D32.2A-00 | 1 |
| 56 | Колодка ручного тормоза (комплект 2 шт.) | Handbrake pad (set of 2 pcs.) | 4120000087044+4120000087043 | 10 |
| 57 | Колодка тормозная (квадратная) | Brake pad (square) | 918/ZL15.5.1/Z200266/7200000208 | 20 |
| 58 | Корпус сателитов бортового редуктора | On-board gearbox satellite housing | 29070007661/933/933L/936/936L/938/938L | 1 |
| 59 | Крышка топливного бака | Fuel tank cap | 4120001404 | 2 |
| 60 | Палец планетарной шестерни | PLANETARY GEAR PIN | 3050900043 | 4 |
| 61 | Патрубок радиатора ДЛИНА 850 ДИАМЕТР 45 ВНУТР | Radiator nozzle LENGTH 850 DIAMETER 45 INTERNAL | 02637/LG953 | 2 |
| 62 | Радиатор кондиционера кабины | Cabin air conditioner radiator | 4190001338 | 1 |
| 63 | Реле звукового сигнала | Audio signal relay | 4130000009001 | 5 |
| 64 | Ремкомплект гидроцилиндра ковша | Bucket Hydraulic Cylinder Repair Kit | 4120000868101/k9360300031/LG936 | 2 |
| 65 | Ремкомплект гидроцилиндра подъёма стрелы | Boom Lifting Hydraulic Cylinder Repair Kit | k9360300041/LG936 | 2 |
| 66 | Ремкомплект гидроцилиндра подъёма стрелы | Boom Lifting Hydraulic Cylinder Repair Kit | 918/4120001153001 | 2 |
| 67 | Ремкомплект рулевого гидроцилиндра | Steering cylinder Repair kit | 4120001004007/936 | 2 |
| 68 | Сальник | Oil seal | 80*105*10/4043000256 | 10 |
| 69 | Трос переключения скоростей в сборе (длина 1840мм) | Gearshift cable assembly (length 1840 mm) | 4190000393/1 | 5 |
| 70 | Трос управления гидравликой (1740 мм) | Hydraulic control cable (1740 mm) | 29120010971-1 | 5 |
| 71 | Трубка смазки | Lubrication tube | 29270017601 | 3 |
| 72 | Трубка тормозная заднего моста левая | Rear axle brake tube left | 29220004161 | 3 |
| 73 | Трубка тормозная заднего моста правая | Rear axle brake tube right | 29220004171/УТ000015881 | 3 |
| 74 | Трубка тормозная переднего моста левая | Front axle brake tube left | 29220004131 | 3 |
| 75 | Трубка тормозная переднего моста правая | Front axle brake tube right | 29220004121 | 3 |
| 76 | Указатель давления воздуха | Air pressure indicator | 4130000858 | 3 |
| 77 | Указатель уровня топлива | Fuel level indicator | 4130000209/4130000235/4120000082 | 3 |
| 78 | Фильтр всасывающей магистрали | Suction line filter | 29100010291 | 3 |
| 79 | Фильтр сапуна КПП | Gearbox Breather Filter | 4120005390 | 5 |
| 80 | Фильтр топливного бака-ТОПЛИВОЗАБОРНИК | Fuel tank filter-FUEL INTAKE | 29020008421/958L | 2 |
| 81 | Фонарь задний | Rear light | 4130000270/4130000213 | 6 |
| 82 | Шайба регулировочная | Adjusting washer | 4043000151/60*130*2/4043000151-2 | 50 |
| 83 | Шпонка | Key | 4090000008/GB308-9.525-GCr15 | 10 |
| 84 | Штифт | Pin | 4016000113 | 10 |
| 85 | Вал коленчатый двигателя | Crankshaft of the engine | 13032128/13032128+001/4110000909105/12272496/Deutz WP6G125 | 3 |
| 86 | Держатель ролика | Roller Holder | 13020864/Deutz/TD226B-6G | 4 |
| 87 | Поршневая группа двигателя | Engine piston group | 13020377/Deutz/TBD226B-6D | 1 |
| 88 | Прокладка крышки клапанов двигателя | Engine valve cover gasket | 12270879/Deutz/TD226B-6/WP6G125E22 | 200 |
| 89 | Поршень | Piston | 612600030015/D=126 G2-II/CDM 855/WD615 LonKing | 6 |
| 90 | Болт с гайкой крепления бокового зуба | Bolt with nut for fixing the side tooth | 4043000337/4013000016/(M16*40)/LG933, LG936 | 20 |
| 91 | Вал с шестерней привода насоса диаметр 34 мм, 6 шлицов, 39 зубьев | Shaft with pump drive gear diameter 34 mm, 6 slots, 39 teeth | 29050016421 | 1 |
| 92 | Вал с шестерней привода насоса диаметр 34 мм, 6 шлицов, 42 зубьев | Shaft with pump drive gear diameter 34 mm, 6 slots, 42 teeth | 3030900094 | 1 |
| 93 | Втулка пальца маятника центральная | Pendulum finger central sleeve | 3070900431/LG 952/100x120x110 | 6 |
| 94 | Главная пара заднего моста 7/37 левая (23 шлица, L хвостовика 330 мм) | Main pair of rear axle 7/37 left (23 slots, L shank 330 mm) | 2909000008/2909000007/LG956 | 2 |
| 95 | Зуб ковша правый | Bucket tooth right | 29170036961/LG 933,936 | 10 |
| 96 | Колодка стояночного тормоза | Parking brake pad | 4120000087043/LG933/LG936 | 40 |
| 97 | Мотор отопителя | Heater motor | 4190000160001/LG933/936 | 2 |
| 98 | Насос-дозатор (Гидроруль)(шпонка) | Metering pump (Hydraulic steering)(key) | 250100112/BZZ-125/BZZ3-E125/W083200000B | 2 |
| 99 | Палец 85х245 маятника (рокера) стрелы | Pin 85×245 pendulum (rocker) arrows | 4043000120/LG 933,936 | 5 |
| 100 | Палец 95х250 крепления подъемного цилиндра (у кабины) | Pin 95×250 mounting the lifting cylinder (at the cabin) | 4043000017/LG 952, 953, 956 | 6 |
| 101 | Ремкомплект ПГУ | Pneumatic hydraulic booster repair kit | LG40A-XLB/LG40A | 10 |
| 102 | Ремкомплект ПГУ | Pneumatic hydraulic booster repair kit | 412000009001/LYG60A | 20 |
| 103 | Сальник (железная обойма) пальца тяга-ковш, тяга-коромысло | Oil seal (iron clip), thrust-bucket, thrust-rocker arm | 4043000056/LG952/LG-953/85*100*8 | 30 |
| 104 | Сальник NSK | Oil seal NSK | 75*100*12 | 15 |
| 105 | Щетка с поводком очистителя ветрового стекла (под 2 шлицевых вала) | Brush with windscreen cleaner leash (under 2 spline shafts) | K936022004 | 20 |
| 106 | Каток двубортный | Skating rink double-breasted | 16Y-40-10000/SD16 | 2 |
| 107 | Радиатор масляный | Oil radiator | 4061161/SD22 SHANTUI | 1 |
| 108 | Блок цилиндров двигателя | Engine cylinder block | 330-1002170, 330-1002015A, 330-1002114, B7615-1002000/Yuchai YC6B125/YC6108 | 1 |
| 109 | Вилка переключения высокой и низкой передач | High and low gear shift fork | 860114724/ZL20-030048/4110000038315/860114724/LW300FN | 2 |
| 110 | Гидротрансформатор | Torque converter | 800351249/LW300FN | 2 |
| 111 | Клапан выпускной двигателя | Engine exhaust valve | 330-1007012C, 330-1007012, 330-1007012C, D30-1003103B/Yuchai YC6B125/YC6108 | 12 |
| 112 | Палец рулевого цилиндра | Steering cylinder pin | 251400276/251702703/40*140 | 20 |
| 113 | Палец балансира заднего моста (вилка) | Rear axle balance pin (fork) | 250100212/Z3.8.5/250100212/Z3.8.5/50*145 | 10 |
| 114 | Палец вилка (рама гц ковша) | Pin fork (bucket hydraulic cylinder frame) | Z5G.6.21/251400270/80*240 | 6 |
| 115 | Трубка топливная (обратка форсунок) двигателя | Fuel tube (return of injectors) of the Yuchai engine | 695-1104040, B7604-1104040A/YC6B125/YC6108/Yuchai | 1 |
| 116 | Шайба медная форсунки двигателя | Copper washer of the engine nozzle | 630-1112001-1.2, 630-1112001, 4110001026098, 4110000560089/Yuchai YC6B125/YC6108 | 100 |
| 117 | Палец | Pin | 11D0001/ZL50C.11.2/90×195 LiuGong | 4 |
| 118 | Блок сателлитов бортового редуктора в сборе с сателитами | Satellite unit of the on-board gearbox assembly with satellites | 83513206 | 1 |
| 119 | Болт гайки ступицы | Hub Nut Bolt | 83319015 | 10 |
| 120 | Болт крепления переднего моста в сборе с гайкой | Front axle mounting bolt assembly with nut | 805002107+805201458/LW300F | 20 |
| 121 | Болт крепления подвески заднего моста в сборе с гайкой | Rear axle suspension mounting bolt assembly with nut | 805000671+805201458/M24*2*220 L=21/LW300F | 10 |
| 122 | Болт крепления моста с гайкой | Bridge mounting bolt with nut | ZL50E.6-9/М30/ZL50E.6-9/250400522 | 10 |
| 123 | Болт среднего ножа с гайкой | Middle knife bolt with nut | GB10-88 M16*50 | 50 |
| 124 | Вал карданный | Cardan shaft | 103040002 | 1 |
| 125 | Вал карданный | Cardan shaft | 103040011(7207-577A)GR215/10304002 | 1 |
| 126 | Вал карданный | Cardan shaft | 103040037(PY132L(450)GR215 | 1 |
| 127 | Вал карданный | Cardan shaft | 103040038/(PY132J) GR215 | 1 |
| 128 | Вал карданный | Cardan shaft | 800300191 | 1 |
| 129 | Вал карданный | Cardan shaft | Z3G.4.1-1/252700128/350K.032 | 1 |
| 130 | Вал карданный задний | Rear cardan shaft | 9305264 | 1 |
| 131 | Вал карданный передний (зад. часть) | Front cardan shaft (rear part) | 9322646-2 | 1 |
| 132 | Вал карданный передний (зад. часть) | Front cardan shaft (rear part) | Z3G.4.1-2 | 1 |
| 133 | Вал карданный с подвесным подшипником в сборе | Cardan shaft with outboard bearing assembly | 252906871 | 1 |
| 134 | Вал КПП 2-ой передачи | 2nd gear gearbox shaft | LW300/860114665/ZL20-033002 | 1 |
| 135 | Вал КПП задней передачи | Reverse gear gearbox shaft | LW300/860114664/ZL20-036003 | 1 |
| 136 | Вал основной ступичный | Main hub shaft | 83513201/SP105819/PY180.39.02-01 | 1 |
| 137 | Вилка фланцевая вала карданного промежуточного | Flange fork of the cardan intermediate shaft | Z3.4.2-01/LW300 | 4 |
| 138 | Втулка | Bushing | 50*65*70/250200493/9301647 | 4 |
| 139 | Втулка | Bushing | 55*58*21/Z3G.8-5/251900107 | 4 |
| 140 | Втулка | Bushing | 60*68*75/252600350 | 4 |
| 141 | Втулка | Bushing | 77*90*17/252600717/9364818/300K.5-1A | 4 |
| 142 | Втулка | Bushing | 85513041/95*76*20 | 4 |
| 143 | Втулка | Bushing | 86*100*18/85513042 | 4 |
| 144 | Втулка вала | Shaft bushing | 60*70*27/860114728/zl20-030032 | 4 |
| 145 | Втулка нижняя | Lower bushing | ZL50E-6-2/250400147 | 4 |
| 146 | Упорная втулка подшипника | Thrust bearing sleeve | 85513034 | 3 |
| 147 | Выключатель давления | Pressure switch | 803676181/PS67-15-2MNZ-A-FLSM08-IP-FS5BARR | 2 |
| 148 | Выключатель давления | Pressure switch | 803678456 | 2 |
| 149 | Гайка | Bolt nut | 71270231 | 5 |
| 150 | Гайка | Bolt nut | 75501646/ZL50EX.04.01.01-017/LG50F.04420A | 5 |
| 151 | Гидроцилиндр | Hydraulic cylinder | 020130000/PY160M | 1 |
| 152 | Гидроцилиндр | Hydraulic cylinder | 140015/PY160-G3 | 1 |
| 153 | Гидроцилиндр подъема | Hydraulic lifting cylinder | 120065/PY180-G6 | 1 |
| 154 | Гидроцилиндр подъема правый | Hydraulic lifting cylinder right | 9326008/Z5G.7.1.3A/252100628 | 1 |
| 155 | Гидроцилиндр подъема стрелы (правый) | Boom lifting hydraulic cylinder (right) | 803071259/XGYG01-129 | 1 |
| 156 | Гидроцилиндр подъема стрелы левый | Boom lifting hydraulic cylinder left | 803013063 | 1 |
| 157 | Гидроцилиндр стрелы (левый) | Boom hydraulic cylinder (left) | 252100629/Z5G.7.1.24A/9326009 | 1 |
| 158 | Гипоидная пара (по часовой) | Hypoid pair (clockwise) | 82215102/82215103 | 1 |
| 159 | Датчик давления масла | Oil pressure sensor | 803502505 | 4 |
| 160 | Датчик температуры воды | Water temperature sensor | 803545325 | 4 |
| 161 | Датчик температуры КПП | Gearbox temperature sensor | 803502732 | 4 |
| 162 | Датчик температуры масла КПП | Gearbox Oil temperature sensor | 803502420 | 4 |
| 163 | Зеркало | Mirror | 801902760/LW300FN | 4 |
| 164 | Зуб центральный | Central tooth | Z3.11.1-1/9301653/250100248/860103046 | 20 |
| 165 | Клапан предохранительный | Safety valve | 803004050(LW500FN) | 2 |
| 166 | Клапан приоритета | Priority Valve | FLD-30Z/ZL30G | 2 |
| 167 | Клапан тормозной | Brake valve | 101000059 | 1 |
| 168 | Колодка тормозная | Brake pad | 103070018/PY180-H.2.6.3 | 4 |
| 169 | Кольцо | Ring | 130*3.1(GB1235-76) | 5 |
| 170 | Кольцо | Ring | 53000013/130-135-30 | 5 |
| 171 | Кольцо нижнего пальца сочленения | Ring of the lower pin of the articulation | 80*5,7/GB1235-76 | 10 |
| 172 | Кольцо стопорное | Locking ring | 52100009 (d-45) | 10 |
| 173 | Корпус планетарной передачи | Planetary Transmission Housing | 83513202/SP115141 | 1 |
| 174 | Корпус тормозного механизма | Brake mechanism housing | PY180-H.2.6.1 | 1 |
| 175 | Кран воздухозаборника | Air intake valve | 252101539 | 2 |
| 176 | Крестовина редуктора моста | Bridge Gearbox Crosspiece | 275101723 | 5 |
| 177 | Кронштейн медной направляющей | Copper guide bracket | 001210005/001210530/PY180G.10.1-1 | 2 |
| 178 | Крышка | Cap | 85513019 | 1 |
| 179 | Крышка нижнего подшипника | Lower bearing cover | 252900353 | 1 |
| 180 | Кулак поворотный левый | Left rotary fist | 1500028 | 1 |
| 181 | Кулак поворотный правый | Right rotary fist | 1500026 | 1 |
| 182 | Накладка | Overlay | 0011312001/GR215.12.2/PY180G.12-7/001210031 | 2 |
| 183 | Накладка | Overlay | 001210030/PY180G.12-6A | 2 |
| 184 | Направляющие медные | Copper guides | 001210007/PY180G.10.1-3/001210007/381600371 | 2 |
| 185 | Насос водяной | Water pump | 860121354/J3600-1307020C | 2 |
| 186 | Насос гидравлический | Hydraulic pump | CBT-E316/CBN-F316 | 1 |
| 187 | Насос гидравлический | Hydraulic pump | CBG2040/JHP2040/W060600000 | 1 |
| 188 | Насос гидравлический (13 шлицов) для фронтального погрузчика | Hydraulic pump (13 slots) for front loader | CBGJ1032/changlin zlm30-5 | 1 |
| 189 | Насос гидравлический (шпонка) | Hydraulic pump (key) | CBGJ2080/5002029/860102735/5002029/860102633/803004540 | 1 |
| 190 | Насос гидравлический (шпонка) | Hydraulic pump (key) | CBGj2100/5000035 | 1 |
| 191 | Насос гидравлический | Hydraulic pump | P5100-F100CX/BL0351/803004078 | 1 |
| 192 | Нож | Knife | 2130*150*20/GR215A | 1 |
| 193 | Нож NEW | Knife NEW | 2130*152*19/GR215A | 1 |
| 194 | Обойма маслосъемная | Oil-removing clip | 83021509 | 2 |
| 195 | Обойма подшипника | Bearing cage | 85513015 | 2 |
| 196 | Палец | Pin | 60*135/252600335/9358267/300K.5-2 | 4 |
| 197 | Палец гидроцилиндра ковша задний (ухо) | Bucket rear hydraulic cylinder pin (ear) | 251702733/60*167 | 4 |
| 198 | Палец | Pin | 60*212 LW330F (II).8.4 | 4 |
| 199 | Палец стрелового цилиндра (Ухо) | Arrow cylinder Pin (Ear) | 251700192/60*230/LW300FN | 4 |
| 200 | Палец ковша нижний | Bucket bottom pin | ZL50GA.7.1/65*200 | 4 |
| 201 | Палец | Pin | 85*220/252903797/4043004230 | 4 |
| 202 | Палец сочленения | Joint pin | GR215PY180G.14-6 | 4 |
| 203 | Палец сочленения | Joint pin | GR215PY180G.14-7 | 4 |
| 204 | Переключатель скоростей (L= 2500 мм) | Speed switch (L= 2500 mm) | LW520G.2.1A/800302763 | 1 |
| 205 | Подшипник | Bearing | 54100005/32022/B120400012/2007122E | 3 |
| 206 | Подшипник | Bearing | 32026X/54100007 | 3 |
| 207 | Подшипник | Bearing | 33113/54100059/54100014/7813 | 3 |
| 208 | Подшипник подвесной | Suspension bearing | 860111011/ZL50G | 2 |
| 209 | Полуось левая | Left half-axis | W44002006/80513003 | 1 |
| 210 | Полуось правая | Right half-axis | 80513004/SP105549/W44002007/80513005 | 1 |
| 211 | Прокладка поддона картера | Sump pallet gasket | ZL20-030020/LW300FN/4110000038130 | 4 |
| 212 | РВД гидроцилиндр наклона ковша | High pressure hose bucket tilt cylinder | 251702648/300FS.7.1.3/LW300FN | 1 |
| 213 | Редуктор моста (против часовой) | Bridge reducer (counterclockwise) | 4.Z3.2.00A | 1 |
| 214 | Редуктор моста | Bridge reducer | 83513200 | 1 |
| 215 | Редуктор переднего моста (по часовой) | Front axle gearbox (clockwise) | 250300319/800302262 | 1 |
| 216 | Реле | Relay | 803604498/XGJD02(JD2914J) | 5 |
| 217 | Ролик 6х30 подшипника игольчатого | Needle bearing roller 6×30 | 75600330 | 10 |
| 218 | Сиденье оператора (без подлокотников) | Operator’s seat (without armrests) | 801902761/XGZY01-II/FS16D-03/LW300F | 1 |
| 219 | Ступица передняя | Front hub | PY180G.17.7 | 1 |
| 220 | Трос ручного тормоза 160 см | Hand brake cable 160 cm | ZL50E.9.12 | 2 |
| 221 | Трос управления гидравликой (L-2,10 м) | Hydraulic control cable (L-2.10 m) | 9101525/LW500 | 2 |
| 222 | Трубка обратки | Return tube | LW300F P7604-1104040A | 2 |
| 223 | Тяга рулевая | Steering rod | 001500031 | 1 |
| 224 | Механический указатель давления масла двигателя 0-1МРа | Mechanical engine oil Pressure Gauge 0-1MRa | 803502459/LW300 | 2 |
| 225 | Указатель температуры воды | Water temperature indicator | 803502410/4130000215 | 2 |
| 226 | Фильтр гидравлический | Hydraulic filter | 101010157 | 10 |
| 227 | Фильтр гидравлическй | Hydraulic filter | 50G2-06027 | 10 |
| 228 | Фильтр гидробака обратной магистрали (200*190) | Return line hydraulic tank filter (200*190) | 250400462/ZL50E.7.3.4/LW560F.7.1.13.2/9314932/ZL50G | 10 |
| 229 | КПП фильтр сетка | Gear shift box filter grid | ZL40A.30.4.2/4110000184138 | 10 |
| 230 | Фильтр топливный грубой очистки | Coarse fuel filter | 860118458/D00-305-01+A/4110000186393 | 10 |
| 231 | Фланец | Flange | 250300341/ZL50.2A.1A.3.1-2A/9352558 | 2 |
| 232 | Фланец | Flange | 252600573 | 2 |
| 233 | Фланец | Flange | Z5G.6-10 | 2 |
| 234 | Фланец | Flange | Z5G.6-11 | 2 |
| 235 | Фланец вала гидромуфты | Hydraulic coupling shaft flange | 860114582/ZL30D-11-12/LW300 | 2 |
| 236 | Фланец вала карданного | Cardan shaft flange | 860118415 | 2 |
| 237 | Фланец насоса | Pump flange | CBGj3125/LW300F (251700223/300F.7.2-2/9364967) | 2 |
| 238 | Верхний фланец поворота | Upper turning flange | Z3G.8-1 | 2 |
| 239 | Фонарь задний | Rear light | 803506733 | 4 |
| 240 | Червь | Worm drive (worm) | HX8000A-15 | 1 |
| 241 | Шайба | Puck | 001210108 | 4 |
| 242 | Шайба | Puck | 001210110 | 4 |
| 243 | Шайба | Puck | 52060006 | 10 |
| 244 | Шайба | Puck | 75600457 | 10 |
| 245 | Шестерня | Gear | НХ8000А-14 | 1 |
| 246 | Шестерня на полуось | Gear on the half-axle | 83000802/W44003100/W041400471/860115239 | 2 |
| 247 | Шестерня сателлита | Satellite Gear | 83000801/29070012711/W041400491/860115217 | 2 |
| 248 | Шестерня солнечная (РАЗБОРНАЯ ПОД СТОПОР) Z-67/61 шлиц | Solar gear (COLLAPSIBLE UNDER THE STOPPER) Z-67/61 slot | ZL60D.24.1-19-1/ZL60D.24.1-23/ZL60D.24.1-3/LG50F.04428A-1 | 1 |
| 249 | Солнечная шестерня | Солнечная шестерня | 77500938/77500940/77500938BD | 1 |
| 250 | Шестерня солнечная Z=49 | Solar gear Z=49 | SP109914/76101031 | 1 |
| 251 | Шкворень (длинный) | Pin (long) | 001500021 | 2 |
| 252 | Шпилька колеса с гайкой | Wheel stud with nut | 250300312/250300296 | 100 |
| 253 | Шпилька колесная с гайкой | Wheel stud with nut | 3382 | 100 |
| 254 | Шпилька колесная с гайкой | Wheel stud with nut | 3399 | 100 |
| 255 | Шпилька колесная с гайкой | Wheel stud with nut | 3700 | 100 |
| 256 | Шпилька колесная с гайкой | Wheel stud with nut | 5143 | 100 |
| 257 | Шпилька колесная с гайкой | Wheel stud with nut | 7936 | 100 |
| 258 | Шпилька колесная с гайкой | Wheel stud with nut | 805200052/29070000621 | 100 |
| 259 | Шпилька колесная с гайкой | Wheel stud with nut | 9106 | 100 |
| 260 | Вал карданный | Cardan shaft | Z320730160 | 1 |
| 261 | Вал карданный | Cardan shaft | Z5B366100 | 1 |
| 262 | Вал карданный задний | Rear cardan shaft | Z520100030 | 1 |
| 263 | Вал привода насоса ГМП | Hydromechanical transmission pump drive shaft | W020200151/W021300030B | 1 |
| 264 | Втулка | Bushing | 60*75*28/Z3B00303000 | 6 |
| 265 | Втулка | Bushing | 75*66*60/Z3B00303200 | 6 |
| 266 | Втулка | Bushing | 80*95*40/MG19002139 | 4 |
| 267 | Втулка | Bushing | MG19026014 | 6 |
| 268 | Втулка | Bushing | MG19026023 | 6 |
| 269 | Втулка вала (6*10 шлицов) | Shaft sleeve (6*10 slots) | 6 | |
| 270 | Втулка ковша | Bucket bushing | Z3100105602 | 4 |
| 271 | Втулка сочленения | Joint bushing | 80*95*78/Z620030370 | 4 |
| 272 | Гидрораспределитель | Hydraulic distributor | W42020000 | 1 |
| 273 | Гидроусилитель руля | Power steering | W42009000 | 1 |
| 274 | Гидроцилиндр выдвижения среднего отвала | Hydraulic cylinder for extending the middle blade | W42028000/80*50*630 | 1 |
| 275 | Гидроцилиндр выдвижения среднего отвала W42030000/80*45*1175 | Hydraulic cylinder for extending the middle blade | W42030000 | 1 |
| 276 | Диск ступичный | Hub disk | MG19026027 | 1 |
| 277 | Диск тормозной | Brake disc | W043100220 | 1 |
| 278 | Зуб боковой (левый) | Side tooth (left) | Z510010882 | 4 |
| 279 | Зуб боковой (правый) | Side tooth (right) | Z510010891 | 4 |
| 280 | Зуб боковой левый | Left side tooth | W110008115B | 2 |
| 281 | Зуб боковой правый | Right lateral tooth | W110008117B | 2 |
| 282 | Клапан гидроцилиндра | Hydraulic cylinder valve | W42000031/S1CH4-18-220G | 2 |
| 283 | Кулак поворотный (левый) | Rotary fist (left) | MG19026005 | 1 |
| 284 | Накладка | Overlay | MG19005032 | 2 |
| 285 | Насос гидравлический | Hydraulic pump | W42053000/PGM511A0190B-03 | 1 |
| 286 | Опора промежуточная | Intermediate support | W040300000 | 1 |
| 287 | Опора промежуточная | Intermediate support | W045000000 | 1 |
| 288 | Палец | Finger | 45*160/MG19026008 | 2 |
| 289 | Палец | Finger | 45*190/MG19026013 | 4 |
| 290 | Палец | Finger | 60*140/Z310020640 | 4 |
| 291 | Палец | Finger | Z320020660/60*200 | 4 |
| 292 | Палец | Pin | Z320020691 | 4 |
| 293 | Палец | Pin | Z510010561/6571L303200/80*235 | 2 |
| 294 | Палец | Pin | Z5100107902/80*268 | 2 |
| 295 | Палец | Pin | Z5100200732/70*325 | 4 |
| 296 | Палец | Pin | Z510020671/6571P301100/80*253 | 4 |
| 297 | Палец | Pin | Z510020731/6571L303000/70*323 | 4 |
| 298 | Палец | Pin | Z510020861/50*145 | 4 |
| 299 | Палец сочленения | Joint pin | Z310010280 | 2 |
| 300 | Верхний палец сочленения | Upper pin articulation | Z520031220 | 2 |
| 301 | Палец сочленения нижний | Joint finger lower | Z520030591 | 2 |
| 302 | Палец стрела-гидроцилиндр стрелы | Finger Arrow-Boom hydraulic cylinder | Z310010040 | 2 |
| 303 | Пластина | Plate | MG19026010 | 10 |
| 304 | Пластина | Plate | MG19026051 | 10 |
| 305 | Пластина | Plate | MG19026082 | 10 |
| 306 | Пластина проставочная | Spacer plate | MG19004034 | 10 |
| 307 | Пластина проставочная | Spacer plate | MG19004036 | 10 |
| 308 | Пластина проставочная | Spacer plate | W44000014 | 10 |
| 309 | Подшипник | Bearing | 50308/В121134023 | 2 |
| 310 | Подшипник | Bearing | B120406028/32212 | 2 |
| 311 | Подшипник | Bearing | W44000002 | 2 |
| 312 | Редуктор моста передний | Front axle gearbox | W041400701 | 1 |
| 313 | Ремкомплект гидроцилиндра наклона ковша | Bucket Tilt Hydraulic Cylinder Repair Kit | W054300000B/W054300010B | 2 |
| 314 | Ремкомплект КПП (КОМПЛЕКТ) | GEARBOX Repair KIT (KIT) | TR1-200 | 2 |
| 315 | Сальник (кассетный) | Oil seal (cassette) | W043100453/130*170*15 | 6 |
| 316 | Сальник | Oil seal | 130*150*12/Z510010860 | 6 |
| 317 | Сальник | Oil seal | W44000004 | 6 |
| 318 | Сальник | Oil seal | W44000010 | 6 |
| 319 | Фильтр гидравлический | Hydraulic filter | W110015510А/YL-161-100 | 6 |
| 320 | Фильтр гидравлический | Hydraulic filter | W42000008 | 6 |
| 321 | Фильтр сапуна гидробака | Hydraulic tank breather filter | W380000010A | 10 |
| 322 | Фильтр сапуна гидробака | Hydraulic tank breather filter | W380000010A | 10 |
| 323 | Фильтр трансмиссии | Transmission filter | W110012551 | 10 |
| 324 | Фильтр трансмиссии | Transmission filter | W154200010 | 10 |
| 325 | Фильтр трансмиссии | Transmission filter | Z510210890 | 10 |
| 326 | Фильтр-элемент | Filter element | W110015510A/YL-161-00 | 10 |
| 327 | Фланец | Flange | MG19002140 | 2 |
| 328 | Фланец | Flange | MG19013002 | 2 |
| 329 | Фланец | Flange | Z310390130 | 2 |
| 330 | Блок фрикционов в сборе | Friction block assembly | NZ51021043000 | 1 |
| 331 | Блок фрикционов в сборе | Friction block assembly | NZ51021058000 | 1 |
| 332 | Втулка | Bushing | 50*65*36/4043000290 | 6 |
| 333 | Втулка | Bushing | 80*100*120/Z5100100102 | 6 |
| 334 | Диск фрикционный | Friction disc | Z510210460 | 20 |
| 335 | Сальник | Oil seal | 70*90*10/B160420007/LG50F.11006/LG853.11.08 | 6 |
| 336 | Втулка | Bushing | Z30.8-3B | 2 |
| 337 | Втулка | Bushing | Z60F.12-12/90*100*39 | 2 |
| 338 | Втулка | Bushing | Z60F.12-13 | 2 |
| 339 | Втулка | Bushing | Z60F.12-3 | 2 |
| 340 | Втулка крепления моста | Bridge mounting sleeve | Z30.8-4A | 2 |
| 341 | Диск тормозной | Brake disc | Z583-06-20A | 2 |
| 342 | Диск фрикционный | Friction disc | Z50B.4.2-7 | 20 |
| 343 | Зуб боковой левый | Left side tooth | ZL50.7A.2-1 | 2 |
| 344 | Зуб боковой правый | Right lateral tooth | ZL50.7A.2-2 | 2 |
| 345 | Центральный зуб | Central tooth | ZL50.7-4 | 6 |
| 346 | Клапан тормозной | Brake valve | W-18-00097/CL50A-3514002 | 1 |
| 347 | Клапан трансмиссии | Transmission valve | Z30.4.13 | 1 |
| 348 | Колодка тормозная на погрузчик | Brake pad for loader | ZL50E-II-001/Changlin 956, ZLM50E-5 | 10 |
| 349 | Муфта включения | Switching coupling | Z50B.2.1-3 | 1 |
| 350 | Муфта включения | Switching coupling | Z50B.2.1-30 | 1 |
| 351 | Ремкомплект гидроцилиндра опрокидывания ковша | Bucket Tipping Hydraulic Cylinder Repair Kit | zlm50E-5 | 1 |
| 352 | Ремкомплект гидроцилиндра подъема стрелы | Boom Lifting Hydraulic Cylinder Repair Kit | zlm50E-6 | 1 |
| 353 | Ремкомплект гидроцилиндра рулевого | Steering cylinder Repair kit | zlm50E-5 | 1 |
| 354 | Ремкомплект суппорта тормозного | Brake Caliper Repair Kit | Z30.6.3B-RKT | 1 |
| 355 | Сальник | Oil seal | 50*80*12/B-G09877A-00023 | 6 |
| 356 | Фильтр гидравлический | Hydraulic filter | Z50B.14.21-4 | 5 |
| 357 | Фильтр гидравлический | Hydraulic filter | Z50E.14.1.3 | 5 |
| 358 | Фильтр трансмиссии | Transmission filter | W-15-00057 | 6 |
| 359 | Вал насоса КПП | Gearbox pump shaft | Z55S030000002T9 | 1 |
| 360 | Муфта резиновая | Rubber coupling | Z35F0105021B | 2 |
| 361 | Насос КПП | Gear Shift Pump | Z50E0301 | 1 |
| 362 | Ремкомплект суппорта | Caliper Repair Kit | CG50.6.2-10+CG50.6.2-9 | 1 |
| 363 | Суппорт тормозной | Brake caliper | Z5EII0501 | 4 |
| 364 | Вал | Shaft | 154-13-41651 | 1 |
| 365 | Вал | Shaft | 154-13-51650 | 1 |
| 366 | Вал | Shaft | 175-30-34210 | 1 |
| 367 | Вал карданный | Cardan shaft | ZL50G3-04004/81Z130011 | 1 |
| 368 | Вал карданный | Cardan shaft | ZL30GII-04400 | 1 |
| 369 | Вал карданный задний | Rear cardan shaft | ZL50G3-04001 | 1 |
| 370 | Вал карданный передний | Front cardan shaft | ZL30GII-04200 | 1 |
| 371 | Вал карданный передний | Front cardan shaft | ZL50G3-04009 | 1 |
| 372 | Вал натяжения гусеницы | Caterpil. tension shaft | 16L-40-62000 | 1 |
| 373 | Вал сателита | Satellite Shaft | 154-15-42521 | 1 |
| 374 | Вал шестерня | Shaft gear | 154-27-11327 | 1 |
| 375 | Венец зубчатый фрикционов КПП | Gear ring of gearshift clutches | 16Y-15-00004 | 1 |
| 376 | Водило с сателитами в сборе №2 (среднее) | Driver No. 2 (medium) with satellites assembled | 154-15-42321T | 1 |
| 377 | Водило сателлитов | Satellite driver | 16Y-15-00006 | 1 |
| 378 | Втулка (направляющая) | Bushing (guide) | 154-30-12170 | 4 |
| 379 | Втулка | Bushing 2 | 14Y82-00016/16Y80-30006/16L80-00007 | 4 |
| 380 | Втулка | Bushing 12 | 60*70*20/DG930A-09010A | 4 |
| 381 | Втулка | Bushing 13 | DG930A-09003A/60*70*39 | 4 |
| 382 | Втулка | Bushing 14 | ZL30GII-11004/50*70*100 | 4 |
| 383 | Втулка | Bushing 15 | ZL30GII-11007A/70*90*120 | 4 |
| 384 | Втулка балансира | Balancer bushing 1 | 16Y-31-00001 | 4 |
| 385 | Втулка балансира | Balancer bushing 2 | ZL50G2-10005 | 4 |
| 386 | Втулка сочленения верхняя | Upper joint bushing | ZL50G2-09006 | 2 |
| 387 | Втулка ковша верхняя | Bucket upper sleeve | ZL50G2-11000-5 | 4 |
| 388 | Втулка ковша нижняя | Bucket bottom sleeve | ZL50G2-11000-3 | 4 |
| 389 | Втулка конической передачи | Conical Transmission Bushing | 16Y-16-00021 | 4 |
| 390 | Втулка полуоси | Half-axle bushing 1 | 16Y-18-00006 | 4 |
| 391 | Втулка полуоси | Half-axle bushing 2 | 16Y-18-01000 | 4 |
| 392 | Гайка | Nut bolt | 16Y-80-00008 | 6 |
| 393 | Гайка полуоси | Axle nut | 16Y-18-00031 | 6 |
| 394 | Гайка ступицы | Hub Nut | ZL60D.24.1-11 | 6 |
| 395 | Генератор | Generator | 612630060248 | 2 |
| 396 | Генератор | Generator | C6121/6N9294/5C9088 | 2 |
| 397 | Гидротрансформатор (Конвертер) | Torque Converter (Converter) | 16Y-11-00000/YJ380 | 1 |
| 398 | Головка блока цилиндров в сборе | Cylinder head assembly | 3418684/3418529 | 1 |
| 399 | Головка блока цилиндров ДВС (НЕ В СБОРЕ) | Engine cylinder head (NOT ASSEMBLED) | 7N8866 | 1 |
| 400 | Диск КПП (поршень) | Gearbox disc (piston) | 16Y-15-00026 | 2 |
| 401 | Диск нажимной | Push disk | 16Y-16-01002 | 2 |
| 402 | Диск фрикционный | Friction disc | 16Y-16-00010 | 10 |
| 403 | Диск фрикционный | Friction disc | 16Y-16-02000 | 10 |
| 404 | Диск фрикционный КПП | Friction gearbox disc | 16Y-15-09000 | 10 |
| 405 | Диск фрикционный КПП | Friction gearbox disc | 175-15-12713 | 10 |
| 406 | Доукон малый (КОМПЛЕКТ) | Doukon Small (SET) | 198-30-16612+170-27-12340 | 5 |
| 407 | Зуб боковой правый (правый) | Right lateral tooth (right) | ZL50G2-11100-2Y | 4 |
| 408 | Кардан (муфта в сборе) | Cardan (coupling assembly) | 175-20-30000 | 1 |
| 409 | Клаксон | Klaxon | D2711-10500/D2700-10500 | 3 |
| 410 | Клапан ГТР | Torque Converter Valve | 16Y-11-30000 | 1 |
| 411 | Клапан регулировки давления | Pressure control valve | 154-49-51100 | 1 |
| 412 | Клапан редукционный главный в сборе | Main pressure reducing valve assembly | 701-30-51002 | 1 |
| 413 | Кольца поршневые (комплект 18 шт.) | Piston rings (set of 18 pcs.) | (3082580+3103159+3012332+3103157)/3803471/3801755 | 2 |
| 414 | Кольца поршневые (КОМПЛЕКТ) | Piston rings (SET) | 4058967+4058968+4058969 | 2 |
| 415 | Кольцо | Ring | 07018-12605/004904015A0201750 | 3 |
| 416 | Кольцо круглого сечения | Circular ring | 07000-02145 | 10 |
| 417 | Кольцо круглого сечения | Circular ring | 07000-05145 | 10 |
| 418 | Кольцо круглого сечения | Circular ring | 07000-05280 | 10 |
| 419 | Кольцо уплотнительное (цвет.мет) | Sealing ring (non-ferrous metal) | 07018-12205 | 2 |
| 420 | Кольцо уплотнительное (цвет.мет) | Sealing ring (non-ferrous metal) | 154-15-49260 | 2 |
| 421 | Кольцо уплотнительное | Sealing ring | 07018-12455 | 3 |
| 422 | Корпус | Body | 16Y-15-00076 | 1 |
| 423 | Корпус в ГТР | Housing in the torque converter | 234-13-11211 | 1 |
| 424 | Крестовина карданного вала | Cardan shaft crosspiece | SD16 16Y-12-00100 | 5 |
| 425 | Кронштейн сварной правый | Right welded bracket | 16Y-40-19100 | 1 |
| 426 | Крышка подшипника (левого) | Bearing cover (left) | 16Y-16-06000 | 1 |
| 427 | Крышка подшипника (правого) | Bearing cover (right) | 16Y-16-05000 | 1 |
| 428 | Насос трансмиссии | Transmission pump | 07433-71103 | 1 |
| 429 | Опора промежуточная | Intermediate support | ZL50G2-04303/ZL50G2-04304/ZL50G2-04302 | 1 |
| 430 | Палец | Finger | ZL30GII-11002 | 2 |
| 431 | Палец | Finger | ZL30GII-11700 | 2 |
| 432 | Палец | Finger | ZL30GII-11800 | 2 |
| 433 | Палец | Finger | ZL50G2-09300 | 2 |
| 434 | Палец | Finger | ZL50G2-11010D | 2 |
| 435 | Палец гидроцилиндра подъема стрелы | Boom lifting hydraulic cylinder finger | ZL30GII-11600 | 2 |
| 436 | Палец ковша верхний | Bucket upper finger | ZL50G2-11600/80*265 | 2 |
| 437 | Палец ковша нижний | Bucket bottom finger | 70*250/ZL50G2-11500 | 2 |
| 438 | Подшипник | Bearing | C4G2213 | 2 |
| 439 | Подшипник КПП игольчатый | Gearbox needle bearing | 16Y-15-01000/SD16 | 2 |
| 440 | Полукольца | Half – rings | 7N9342/C06AL-1003652+A/4110000186070 | 2 |
| 441 | Полуось | Half – axis | 16Y-18-00001 | 1 |
| 442 | Реле выключателя (масса аккумулятора) | Switch relay (battery weight) | D2600-60000 | 1 |
| 443 | Ремкомплект КПП | Gearbox repair kit | 154-15-01000/SD22 | 2 |
| 444 | Сальник | Oil seal | 07013-00090/07013-10090 | 5 |
| 445 | Сальник вала КПП | Gearbox shaft seal | 16Y-15-11000 | 5 |
| 446 | Статор/ходовое колесо в ГТР | Stator/running wheel in the torque converter | SD22 154-13-42110 | 1 |
| 447 | Ступица | Hub | 158-18-00002 | 1 |
| 448 | Ступица | Hub | 16Y-16-03001 | 1 |
| 449 | Тормоз ленточный в сборе | Belt brake assembly | 16Y-17-04000 | 1 |
| 450 | Трубка | A tube | 209958-20/209958 | 1 |
| 451 | Трубка | A tube | 4914213-20/4914213 | 1 |
| 452 | Трубки топливные | Fuel tubes | 26AB201+26AB202+26AB203 | 1 |
| 453 | Турбина конвертера | Converter Turbine | 16Y-11-00001 | 1 |
| 454 | Турбинное колесо в ГТР | Turbine wheel in the torque converter | 154-13-41510/SD22 | 1 |
| 455 | Фланец | Flange | 16Y-15-00009 | 1 |
| 456 | Фланец | Flange | 175-27-31463 | 1 |
| 457 | Фланец | Flange | DG930A-09002A | 1 |
| 458 | Фланец | Flange | DG930A-09007 | 1 |
| 459 | Фланец | Flange | DG930A-09008 | 1 |
| 460 | Фланец шарнира карданного в ГТР | The flange of the cardan joint in the torque converter | 16Y-11-10000 | 1 |
| 461 | Цилиндр | Cylinder | 154-30-11141 | 1 |
| 462 | Шестерня (сателит) | Gear (satellite) | 154-15-42420 | 2 |
| 463 | Шестерня | Gear | 154-15-32490 | 1 |
| 464 | Шестерня | Gear | 154-27-11314/154-27-11313 | 1 |
| 465 | Шестерня | Gear | 16Y-11-00008 | 1 |
| 466 | Шестерня | Gear | 16Y-15-00028 | 1 |
| 467 | Шестерня | Gear | 16Y-18-00036 | 1 |
| 468 | Шестерня ТНВД | Fuel pump gear | C07AB-1064497+B | 1 |
| 469 | Шпилька (ключ) | Hairpin (key) | 154-27-11330 | 3 |
| 470 | Гидроцилиндр рулевой | Steering hydraulic cylinder | DG958-05200 | 1 |
| 471 | Блок фрикционов (муфта) | Friction block (clutch) | 4644251042 | 1 |
| 472 | Гайка | Nut bolt | 0637006018 | 10 |
| 473 | Джойстик | Joystick | 6006 040 002/6006040002/4110000367002 | 1 |
| 474 | Диск фрикционный | Friction disc | 769129011 | 10 |
| 475 | Диск фрикционный | Friction disc | 0769129022 | 10 |
| 476 | Диск фрикционный | Friction disc | 4642308330/4110000076068/7200001650 | 10 |
| 477 | Диск фрикционный | Friction disc | 4642308331/4110000076107 | 10 |
| 478 | Диск фрикционный | Friction disc | 4642308332/4110000076069/7200001651 | 10 |
| 479 | Диск фрикционный SP100006/0501309329/4110000076159/7200001649 | Friction disc | SP100006 | 10 |
| 480 | Колодка комплект | Pad Kit | 0501003821/0501003819 | 3 |
| 481 | Кольцо | Ring | 0634303118 | 10 |
| 482 | Кольцо | Ring | 0634303466 | 10 |
| 483 | Кольцо | Ring | 0634306287 | 5 |
| 484 | Кольцо | Ring | 0634306523 | 10 |
| 485 | Кольцо | Ring | 0634313529/57×3/ZFN744 | 10 |
| 486 | Кольцо | Ring | 0769124115/0730513180 | 5 |
| 487 | Кольцо стопорное | Locking ring | 0630502048/7200001508 | 5 |
| 488 | Кольцо стопорное | Locking ring | 0630502048/7200001508 | 5 |
| 489 | Пластина стопорная | Locking plate | 4644330006 | 5 |
| 490 | Подшипник игольчатый | Needle bearing | 0635303204 | 2 |
| 491 | Подшипник игольчатый | Needle bearing | 0735358069 | 2 |
| 492 | Подшипник игольчатый | Needle bearing | 0750115109/45х53х27.8 | 2 |
| 493 | Подшипник игольчатый | Needle bearing | 0750115182 | 2 |
| 494 | Поршень | The piston | 4642308185 | 3 |
| 495 | Прокладка | Pad | 4644311209 | 3 |
| 496 | Пружина | Spring | 0732041226 | 5 |
| 497 | Ролик | Roller | 0750119048 | 2 |
| 498 | Рукав клапана | Valve sleeve | 4644320042 | 2 |
| 499 | Соединение гибкое (КОМПЛЕКТ 2 ШТ.) | Flexible connection (SET OF 2 PCS.) | 4644230239+4644330239 | 2 |
| 500 | Фланец | Flange | 4644303815 | 1 |
| 501 | Фланец | Flange | YD13302001 | 1 |
| 502 | Шайба | Puck | 4627303027 | 2 |
| 503 | Шайба проставочная пластиковая | Plastic spacer washer | 0730150777/7200001626 | 2 |
| 504 | Шайба регулировочная | Adjusting washer | 769120468 | 10 |
| 505 | Шестерня | Gear | 4644252016/4644352010 | 1 |
| 506 | Шпилька | stud | 0636610014A | 10 |
| 507 | Шпилька | stud | 0636610014B | 10 |
| 508 | Шпонка | Key | 0631501052/A6x4x28/7200001492 | 10 |
| 509 | Шпонка | Key | A6×6×28/DIN6885/0631501514 | 10 |
| 510 | Вал карданный передний подвесной | Front suspension cardan shaft | 41C0120 | 1 |
| 511 | Втулка | Bushing | 130*130*110/55A0411 | 4 |
| 512 | Диск колесный | Wheel drive | H=550 D=760 51C0031/SP116324 | 1 |
| 513 | Крышка планетарного мех. | Planetary Gear Cover | 53A0009/ZL50C.2-21 | 1 |
| 514 | Опора промежуточная | Intermediate support | 41C0038 | 1 |
| 515 | Палец | Pin | 75*305/11D0793 | 2 |
| 516 | Палец | Pin | 90*230/11D0044/ZL50CI.11.2 | 2 |
| 517 | Палец | Pin | 90*240/11D0066 | 2 |
| 518 | Палец рулевого цилиндра | Steering cylinder pin | 90*290/11D0792 | 2 |
| 519 | Палец рулевого цилиндра | Steering cylinder pin | 60A2099 | 2 |
| 520 | Патрубок нижний | Lower branch pipe | 32A0109 | 2 |
| 521 | Подушка кабины | Cabin cushion | 35C0156 | 2 |
| 522 | Полуось | Half – axis | 62A0065 | 1 |
| 523 | Редуктор переднего моста | Front axle gearbox | 41C0605/41C0086/41C0086X1T0/41C0086X2T0/41C0605X1 | 1 |
| 524 | Реле сигнала поворота | Turn signal relay | 31B0018/SG253 | 2 |
| 525 | Ремкомплект гидроцилиндра опрокидывания | Tipping Hydraulic Cylinder Repair Kit | SP102915 | 2 |
| 526 | Ремкомплект для трансмиссии | Repair kit for transmission | SP103882/S/ZL50C.6 | 2 |
| 527 | Фильтр гидравлический | Фильтр гидравлический | 53C0021 | 5 |
| 528 | Болт крепления моста задний | Rear axle mounting bolt | 404003D/M30x1.5, L=110 CDM855 | 6 |
| 529 | Болт крепления моста передний | Front axle mounting bolt | 504003C/M30*1.5, l-145 CDM 855 | 6 |
| 530 | Вал карданный передний | Front cardan shaft | LG30F.04I.02/CDM 833 (304100d) | 1 |
| 531 | Вал карданный средний/задний | Вал карданный средний/задний | LG855.04.04/CDM 855 (LG50F.04203A) | 1 |
| 532 | Вал карданный верхний | Upper cardan shaft | YZ18JF.4.2A/CDM520 | 1 |
| 533 | Вал карданный задний/средний | Rear/middle cardan shaft | LG855.04.03/CDM855 | 1 |
| 534 | Вал карданный нижний | Lower cardan shaft | LG520A6.04.01 | 1 |
| 535 | Вал первой передачи в сборе | First gear shaft assembly | LG30.5.1/ZL30E.5.1/CDM833 | 1 |
| 536 | Вал первой передачи в сборе | First gear shaft assembly | CDM855 403100 | 1 |
| 537 | Втулка рычага управления ковшом | Bucket control lever sleeve | CDM855/856 LG50F.11015/120*140*106 | 4 |
| 538 | Втулка | Bushing | 55*72*70/LG50F.11032A | 4 |
| 539 | Втулка соединения рамы верхняя | Upper frame connection sleeve | LG30F.10 I-004/60*70*45*90 | 4 |
| 540 | Втулка нижняя рычага подъема стрелы | The lower sleeve of the boom lifting lever | LG843.11-007/511003/60916010019/CDM833/843/65*80*90 | 4 |
| 541 | Втулка сочленения нижняя | Joint bushing lower | CDM855 LG853.10-002 (LG50E.10010A)/75*85*65 | 4 |
| 542 | Втулка сочленения нижняя | Joint bushing lower | LG30F10I-009 | 4 |
| 543 | Выключатель стоп-сигнала (лягушка) | Brake light switch (frog) | 55C0039 | 3 |
| 544 | Диск фрикциона с внешними зубами | Clutch disc with external teeth | ZL30E.10.5.1-6/4110000218036/55C0039/853.15.30/JN150/46C0039/6040502006/803604504/ CDM833 | 10 |
| 545 | Диск фрикционный | Friction disc | 403505-506/ZL40A.30.1.1A-2/P-04-04-126/36C0002/LG853.03.01.05.01 | 5 |
| 546 | Диск фрикционный ведущий КПП | Friction drive drive gearbox | ZL30E.5.1-12 | 5 |
| 547 | Зуб ковша погрузчика боковой | Loader side bucket tooth | LG50F.11132B/CDM855 | 4 |
| 548 | Клапан поставки масла | Oil supply valve | CDM855E/843 WYF-65 LG50EX.07.11.04 | 1 |
| 549 | Кольцо | Ring | ZL30D-11-08/4110000084048 | 4 |
| 550 | Кольцо | Ring | ZL30D-11-19 | 4 |
| 551 | Кольцо уплотнительное | Sealing ring | D=40 CDM833 ZL30E.5.1-7 | 4 |
| 552 | Крышка подшипника сочленения | Joint Bearing Cover | d=86, D=180, CDM 510013C (LG50E.10007A) LG853.10-005 | 1 |
| 553 | Насос гидравлический сдвоенный 14 шлицов | Hydraulic double pump 14 slots | CBG2080/CDM833 | 1 |
| 554 | Отопитель кабины | Cabin heater | 6041080016\LG853.15.29 | 1 |
| 555 | Палец рукояти | Handle pin | LG833.11.06/LG30F.11.06(311010D)/CDM833/80*346 | 2 |
| 556 | Палец | pin | LG833.10V.04/65*230 | 2 |
| 557 | Палец сателлита | Satellite Pin | LG50F.04409A | 2 |
| 558 | Патрубок интеркуллера с ТРУБКОЙ | Intercooler pipe with TUBE | 612600111826/d=98, D=110, l=290 CDM855 | 2 |
| 559 | Патрубок радиатора (уголок) | Radiator nozzle (corner) | 612600160028/CDM855 | 2 |
| 560 | Педаль тормоза с тормозным клапаном | Brake pedal with brake valve | LG856.08.07/CDM853/856D | 1 |
| 561 | Редуктор по часовой передний | Gearbox clockwise front | LG30F.04300A | 1 |
| 562 | Ремкомплект гидроцилиндра ковша | Bucket Hydraulic Cylinder Repair Kit | CDM 855 (110*125) | 1 |
| 563 | Ремкомплект КПП (сальники) | Gearbox repair kit (oil seals) | CDM833/CDM835 | 2 |
| 564 | Ремкомплект цилиндра подъема стрелы | Boom Lifting Cylinder Repair Kit | 90×105/ZL50C | 2 |
| 565 | Рычаг ковша | Bucket lever | CDM833 LG30F.11.02 | 1 |
| 566 | Сальник | Oil seal | 4120000558012/HG4-339-66/55*80*12 CDM833 | 10 |
| 567 | Сальник | Oil seal | 403101/70*78*5 CDM843/855 | 10 |
| 568 | Сателлит бортового редуктора 18 зубьев | Satellite of the on-board gearbox 18 teeth | 404020/D=127.4, d=54.6 CDM855 | 2 |
| 569 | Стеклоочиститель с держателем большой длина 70мм | Wiper with holder large length 70 mm | CDM855 | 1 |
| 570 | Фильтр гидравлический | Hydraulic filter | 307525-527D/CDM833/LG833 | 5 |
| 571 | Шайба бортового редуктора | Side gear washer | 404025/60203100367/860115703 | 5 |
| 572 | Шестерня ведомая | Driven gear | YJ315L-00006 | 1 |
| 573 | Бендикс стартера | Starter bendix | А70-3708010В YC6108G | 1 |
| 574 | Клапан электромагнитный остановки двигателя | Electromagnetic engine stop valve | A7019-1115100 | 1 |
| 575 | Колпачок маслосьемный | Oil-removing cap | M6600-1003105 | 12 |
| 576 | Кольцо гильзы цилиндра (1 шт) | Кольцо гильзы цилиндра (1 шт) | A3000-1002063/SP106197/SP106810/SP140709 | 5 |
| 577 | Кольцо гильзы цилиндра КОМПЛЕКТ (12 шт.) | Cylinder Liner Ring SET (12 pcs.) | A3000-1002063/SP106197/SP106810/SP140709 | 5 |
| 578 | Насос масляный | Oil pump | D30-1011100 | 2 |
| 579 | Насос масляный | Oil pump | 1AQ000-1011100A/YCD4R11G | 2 |
| 580 | Патрубок радиатора нижний | Radiator pipe lower | B7648-1303002, B76481303002 | 2 |
| 581 | Прокладка поддона картера | Sump pallet gasket | J3200-1009012/4110000561221/1640H-1009000 | 3 |
| 582 | ТНВД | High pressure Fuel pump | D7002-1111100 | 1 |
| 583 | Турбокомпрессор | Turbocharger | JP60C1G302-1118100-502 | 1 |
| 584 | Болт ГБЦ двигателя Deutz | Cylinder head bolt of the Deutz engine | 13054119, 13037377, 4110000054230, 12200620/TD226B-6/WP6G125E22 | 60 |
| 585 | Болт шатунный | Connecting rod bolt | 12167047/4110000054126, W010250040/SP105397 | 60 |
| 586 | Маслозаборник Deutz | Deutz oil intake | 13020429 | 3 |
| 587 | Ремкомплект прокладок ДВС | Repair kit of internal combustion engine gaskets | WP6G125 | 15 |
| 588 | Термостат для двигателей | Thermostat for engines | 13061335 4110002989034/TD226В (DEUTZ), WP4, WP6 | 10 |
| 589 | Фильтр топливный тонкой очистки | Fuel fine filter | 13020488, 7200002385, CX0712B/Deutz TD226 LG936 | 500 |
| 590 | Втулка | Bushing | 54A0008/ZL50C.11-11/63х75х110 LiuGong | 10 |
| 591 | Втулка пальца ковша | Bucket finger Sleeve | 55A0281/ZL30.11-2/CLG836 LiuGong/63х75х70 | 10 |
| 592 | Втулка | Bushing | 54A0006/ZL50C.11-7/75х87х80 LiuGong | 5 |
| 593 | Ремкомплект гидроцилиндра опрокидывания | Tipping Hydraulic Cylinder Repair Kit | SP100595/S/ZL30.10.2/LiuGong | 3 |
| 594 | Ремкомплект гидроцилиндра подъема | Hydraulic Lifting Cylinder Repair Kit | SP100594/S/ZL30.10.1/d=70 LiuGong | 5 |
| 595 | Ремкомплект суппорта | Caliper Repair Kit | rk-45C0004/ZL50C.2.2/LiuGong | 50 |
| 596 | Фильтр гидравлический | Hydraulic filter | 53C0015/SFM-829/LiuGong | 10 |
| 597 | Пара главная редуктора переднего моста 37зубьев/8зубев/19 шлицов | A pair of front axle main gear 37 teeth/8 teeth/19 slots | 43A0148/43A0129/SP113474/LiuGong | 2 |
| 598 | Болт с гайкой крепления бокового зуба | Bolt with nut for fixing the side tooth | 4043000337/4013000016/(M16*40) LG933, LG936 | 30 |
| 599 | Вал карданный средний | Cardan shaft medium | 2050900053/LG936 | 1 |
| 600 | Вал с шестерней привода насоса диаметр 34 мм, 6 шлицов, 42 зубьев | Shaft with pump drive gear diameter 34 mm, 6 slots, 42 teeth | 3030900094 | 4 |
| 601 | Вентилятор кабины | Cabin fan | 4190000608/LG933, LG936 | 4 |
| 602 | Втулка пальца балансира | The bushing of the balancer finger | 3110900006, 29270007831, 915100005/LG930-1, LG933, LG936/50х62х36 | 10 |
| 603 | Втулка стрелы центральная (соед с цилиндром) | Central boom sleeve (connection to the cylinder) | 4043000121/LG 933, 936/60х75х50 | 15 |
| 604 | Втулка пальца ковша | Bucket finger Sleeve | 4043000218, 4120000867011/4120000868008/LG933, LG936/60х75х58 | 30 |
| 605 | Втулка пальца стрелы нижняя | Boom finger lower sleeve | 4043000026, 29160000021/LG 952/80х95х90 | 20 |
| 606 | Втулка маятника (рокера) центральная | The hub of the pendulum (rocker) is central | 4043000124/LG 933, 936/85х100х125 | 10 |
| 607 | Гайка нижнего пальца сочленения передней полурамы | Nut of the lower finger of the articulation of the front half frame | 29250001061/LG930-1, LG933, LG936(М28) | 20 |
| 608 | Гидроусилитель (Шлицевой) | Гидроусилитель (Шлицевой) | BZZ3-E125B | 2 |
| 609 | Датчик заднего хода | Reverse gear sensor | 4130001294/4130000278/4130001296/LG956 LG933L LG936L LG953 | 15 |
| 610 | Датчик температуры воды | Water temperature sensor | 4130001058 | 10 |
| 611 | Зуб ковша правый | Bucket tooth right | 29170036961/LG 933,936 | 20 |
| 612 | Колодка стояночного тормоза | Parking brake pad | 4120000087043/LG933/LG936 | 100 |
| 613 | Колодка тормозная | Brake pad | 4120001739016/LG 933, 936, 952, 953, 956, 968 | 300 |
| 614 | Колодка тормозная | Brake pad | 4120001827001/918 | 50 |
| 615 | Колодка тормозная прямоугольная | Rectangular brake pad | 4110000012013 | 200 |
| 616 | Крестовина карданного вала (L-153 мм, уши 71 мм, 8 отв) | Cardan shaft crosspiece (L-153 mm, ears 71 mm, 8 holes) | T160, G5-7126 | 20 |
| 617 | Крышка сапуна гидробака | Hydraulic tank breather cover | 4120001088/29100009991 | 5 |
| 618 | Мотор отопителя | Heater motor | 4190000160001/LG933/936 | 4 |
| 619 | Насос-дозатор (Гидроруль) | Metering pump (Hydraulic steering) | BZZ-800/4120001805/BZZ5-E800 LG 952, 953, 956 | 3 |
| 620 | Палец (коромысло-рама) | 100х245 | 2070900104/ ZL50.7.8A | 4 |
| 621 | Палец гидроцилиндра поворота | 40х118 | 29250001101 | 20 |
| 622 | Палец, без подошвы гидроцилиндра поворота передней полурамы | Finger, without the sole of the hydraulic cylinder turning the front half frame | 3110900011, 29250004081, 29270001121/LG930-1, 933, 936/40х124 | 20 |
| 623 | Палец, ухо стрелы центральный | Finger, arrow ear central | 4043000119/LG930-1, 933, 936/60х150 | 20 |
| 624 | Палец крепления подъемного цилиндра стрелы (у кабины) | Boom lifting cylinder mounting pin (at the cab) | 4043000110, 4043000205/LG 936/60х235 | 16 |
| 625 | Палец крепления стрелы к раме (у кабины) | Boom attachment finger to the frame (at the cabin) | 4043000111, 4043000204/LG 933, 936/65х235 | 6 |
| 626 | Палец сочленения тяги ковша с ковшом | Bucket thrust joint finger with bucket | 4043000346/70х170 | 10 |
| 627 | Палец стрелы центральный | Arrow central finger | 4043000014/LG952, 953, 956/85х215 | 6 |
| 628 | Палец маятника (рокера) стрелы | Finger of the pendulum (rocker) arrow | 4043000120/LG 933, 936/85х245 | 6 |
| 629 | Палец рокера ковша верхний | Bucket Rocker upper finger | 4043000060/LG 952, 953, 956, 958/85х265 | 6 |
| 630 | Ремкомплект ПГУ | Pneumatic hydraulic booster repair kit | 412000009001/LYG60A | 30 |
| 631 | Сальник пальца рабочего оборудования ковш-стрела, тяга-ковш, тяга-коромысло | Oil seal of the finger of the working equipment bucket-boom, thrust-bucket, thrust-rocker arm | 4043000059/9321672(128*150*12) | 50 |
| 632 | Сальник (железная обойма) пальца стрела-ковш, тяга-ковш, стрела-ГЦ стрелы | Oil seal (iron clip), arrow-bucket, thrust-bucket, arrow-hydraulic cylinder of the boom | 4043000127/LG930-1,933/60*75*8 | 60 |
| 633 | Суппорт тормозной | Brake caliper | 45C0004, 71A0018, ZL50C.2.2-8/LG944/LG946 | 25 |
| 634 | Суппорт тормозной | Brake caliper | 4120001739, ZL40LG09-ZDQ, 408100C, 4110000012 | 60 |
| 635 | Термостат уточка | Duckling thermostat | 615G00060016/4110000556085/71С ZL50G/WD615 | 10 |
| 636 | Трос газа | Gas cable | 2010900170/L=2300/956 | 6 |
| 637 | Фильтр гидравлический | Hydraulic filter | 29100004061/LG 936 | 20 |
| 638 | Фланец пальца сочленения полурам верхний | The flange of the joint finger is hollow upper | 29250004011/LG936 | 30 |
| 639 | Фланец пальца сочленения полурам нижний | The flange of the joint finger is hollow bottom | 29250004021/LG 936 | 30 |
| 640 | Шайба регулировочная (сочл палец-втулка) | Adjusting washer (pin-sleeve joint) | 4043000125/60*100*1 LG-933, 936 | 150 |
| 641 | Шайба регулировочная (сочл палец-втулка) | Adjusting washer (pin-sleeve joint) | 4043000198/65*140*2 LG-933, 936 | 20 |
| 642 | Шестерня сателлита | Шестерня сателлита | 3050900041 | 2 |
| 643 | Щетка с поводком очистителя ветрового стекла (под 2 шлицевых вала) | Brush with windscreen cleaner leash (under 2 spline shafts) | K936022004 | 30 |
| 644 | Колпачок маслосъёмный двигателя (ОРИГИНАЛ) | Engine oil removal cap (ORIGINAL) | D04-107-30+C/Shanghai D6114ZG2B | 60 |
| 645 | Привод вентилятора в сборе | Fan drive assembly | 16AZ009/C6121 | 1 |
| N/a | Name in Russian | Name in English | Article number | Qty |
| 1 | Болт полый | Hollow Bolt | 1119238 01119238/SP127284 | 5 |
| 2 | Генератор | Generator | 13031590 | 3 |
| 3 | Головка блока цилиндра в сборе | Cylinder head assembly | 13032055 | 12 |
| 4 | Датчик температуры | Temperature sensor | 612600090107/612600090107 | 6 |
| 5 | Держатель топливных фильтров | Fuel Filter Holder | 12189882-A/13028032 | 2 |
| 6 | Клапан задвижки топливного насоса | Fuel pump valve | TD226B-6-000 | 3 |
| 7 | Коллектор воздушный впуской | Air intake manifold | 13034462/4110000846072 | 1 |
| 8 | Коллектор впускной | Intake manifold | 13022552 | 1 |
| 9 | Коллектор выпуской | Exhaust manifold | 13057673 | 11 |
| 10 | Коромысло | Rocker arm | 12214103/13037791 | 12 |
| 11 | Крепление насоса водяного | Water pump mount block | 13025726/Deutz/TD226 | 1 |
| 12 | Крепление топливных трубок | Mounting of fuel tubes | 12165346 | 10 |
| 13 | Крепление топливных трубок | Mounting of fuel tubes | 12166451 | 10 |
| 14 | Патрубок | Branch pipe | 13033682 | 3 |
| 15 | Патрубок | Branch pipe | 13034046/4110000054257/4110001031038 | 3 |
| 16 | Патрубок системы охлаждения масла двигателя | Engine oil cooling system pipe | 13026006 | 3 |
| 17 | Патрубок тосола | Antifreeze nozzle | 12200696 | 3 |
| 18 | Поддон двигателя | Engine tray | 13036094 | 1 |
| 19 | Пробка поддона | Pallet Stopper | 13022897 | 10 |
| 20 | Прокладка адаптера водяного насоса | Water pump adapter gasket | 12158513/4110000054284/SP105131/W47070170 | 10 |
| 21 | Прокладка водяного насоса двигателя | Engine water pump gasket | 12270869/4110000054285/Weichai-Deutz | 10 |
| 22 | ТНВД | Fuel pump | 13051931/4110000846108 | 1 |
| 23 | Топливопровод | Fuel line | 13024894 | 2 |
| 24 | Трубка охлаждающей жидкости двигателя | Engine coolant tube | 13033390/4110000991012/W47002046 | 2 |
| 25 | Турбокомпрессор | Turbocharger | 13030175КН43/13030175 | 2 |
| 26 | Турбокомпрессор | Turbocharger | 13057501/12272277/K24A/13030850 | 2 |
| 27 | Фиксатор форсунки | Nozzle lock | 12159720 | 18 |
| 28 | Шестерня привода масляного насоса | Oil pump drive gear | 12189557/4110000054013/W010250790/SP128978 | 2 |
| 29 | Шкив коленвала ДВС | Crankshaft pulley of the internal combustion engine | 13032345 | 2 |
| 30 | Амортизатор капота | Hood shock absorber | 2120900570 | 20 |
| 31 | Амортизатор капота (L=480 мм) | Hood shock absorber (L=480 mm) | 29330011391 | 20 |
| 32 | Блок сателлитов бортового редуктора с шестернями (3 сателита) | On-board gearbox satellite unit with gears (3 satellites) | 29070018761 | 1 |
| 33 | Блок сателлитов бортового редуктора с шестернями | Satellite unit of the on-board gearbox with gears | 2907000765 | 1 |
| 34 | Болт | Pin | 01151569/Q150B0816 | 100 |
| 35 | Болт крепления переднего моста | Front axle mounting bolt | М30*110/29070001031 | 100 |
| 36 | Вал соеднительный КПП | Shaft connecting gearbox | 4110000160059 | 1 |
| 37 | Втулка | Bushing | 100*115*137/4043000419 | 6 |
| 38 | Втулка | Bushing | 29250009421 | 6 |
| 39 | Втулка | Bushing | 95*110*144/4043000320 | 6 |
| 40 | Втулка рулевого гидроцилиндра | Steering cylinder sleeve | 4120000560013/4120000560507 | 6 |
| 41 | Втулка рулевого гидроцилиндра | Steering cylinder sleeve | 4120001004406 | 6 |
| 42 | Гидрораспределитель | Hydraulic distributor | 4120000561/SD32-16 | 1 |
| 43 | Гидрораспределитель | Hydraulic distributor | 4120002278/YGDF32-18 | 1 |
| 44 | Гидротрансформатор (Конвертер) в корпусе | Torque converter (Converter) in the housing | 4110000084 | 1 |
| 45 | Гидроусилитель (Шлицевой) | Hydraulic booster (Splined) | BZZ3-E125B | 1 |
| 46 | Гидроцилиндр наклона | Tilt hydraulic cylinder | 4120000601/968 | 1 |
| 47 | Гидроцилиндр поворота | Hydraulic turning cylinder | 4120000560/LG953 | 1 |
| 48 | Гипоидная пара (против часовой) редуктора заднего моста | Hypoid pair (counterclockwise) of the rear axle gearbox | 21909005021 | 1 |
| 49 | Гипоидная пара (против часовой) | Hypoid pair (counterclockwise) | 29090001091/29090000081/3050900203 | 1 |
| 50 | Гипоидная пара (против часовой) | Hypoid pair (counterclockwise) | 3050900203 | 1 |
| 51 | Гипоидная пара (против часовой) | Hypoid pair (counterclockwise) | 21909004931 L | 1 |
| 52 | Гипоидная пара (по часовой) | Hypoid pair (clockwise) | 21909004931 R | 1 |
| 53 | Диск тормозной | Brake disc | 3090900009 LG946 | 2 |
| 54 | Диск тормозной | Brake disc | 918/29070010481 | 2 |
| 55 | Клапан гидрораспределителя | Hydraulic distributor valve | 4120001054001/D32.2A-00 | 1 |
| 56 | Колодка ручного тормоза (комплект 2 шт.) | Handbrake pad (set of 2 pcs.) | 4120000087044+4120000087043 | 10 |
| 57 | Колодка тормозная (квадратная) | Brake pad (square) | 918/ZL15.5.1/Z200266/7200000208 | 20 |
| 58 | Корпус сателитов бортового редуктора | On-board gearbox satellite housing | 29070007661/933/933L/936/936L/938/938L | 1 |
| 59 | Крышка топливного бака | Fuel tank cap | 4120001404 | 2 |
| 60 | Палец планетарной шестерни | PLANETARY GEAR PIN | 3050900043 | 4 |
| 61 | Патрубок радиатора ДЛИНА 850 ДИАМЕТР 45 ВНУТР | Radiator nozzle LENGTH 850 DIAMETER 45 INTERNAL | 02637/LG953 | 2 |
| 62 | Радиатор кондиционера кабины | Cabin air conditioner radiator | 4190001338 | 1 |
| 63 | Реле звукового сигнала | Audio signal relay | 4130000009001 | 5 |
| 64 | Ремкомплект гидроцилиндра ковша | Bucket Hydraulic Cylinder Repair Kit | 4120000868101/k9360300031/LG936 | 2 |
| 65 | Ремкомплект гидроцилиндра подъёма стрелы | Boom Lifting Hydraulic Cylinder Repair Kit | k9360300041/LG936 | 2 |
| 66 | Ремкомплект гидроцилиндра подъёма стрелы | Boom Lifting Hydraulic Cylinder Repair Kit | 918/4120001153001 | 2 |
| 67 | Ремкомплект рулевого гидроцилиндра | Steering cylinder Repair kit | 4120001004007/936 | 2 |
| 68 | Сальник | Oil seal | 80*105*10/4043000256 | 10 |
| 69 | Трос переключения скоростей в сборе (длина 1840мм) | Gearshift cable assembly (length 1840 mm) | 4190000393/1 | 5 |
| 70 | Трос управления гидравликой (1740 мм) | Hydraulic control cable (1740 mm) | 29120010971-1 | 5 |
| 71 | Трубка смазки | Lubrication tube | 29270017601 | 3 |
| 72 | Трубка тормозная заднего моста левая | Rear axle brake tube left | 29220004161 | 3 |
| 73 | Трубка тормозная заднего моста правая | Rear axle brake tube right | 29220004171/УТ000015881 | 3 |
| 74 | Трубка тормозная переднего моста левая | Front axle brake tube left | 29220004131 | 3 |
| 75 | Трубка тормозная переднего моста правая | Front axle brake tube right | 29220004121 | 3 |
| 76 | Указатель давления воздуха | Air pressure indicator | 4130000858 | 3 |
| 77 | Указатель уровня топлива | Fuel level indicator | 4130000209/4130000235/4120000082 | 3 |
| 78 | Фильтр всасывающей магистрали | Suction line filter | 29100010291 | 3 |
| 79 | Фильтр сапуна КПП | Gearbox Breather Filter | 4120005390 | 5 |
| 80 | Фильтр топливного бака-ТОПЛИВОЗАБОРНИК | Fuel tank filter-FUEL INTAKE | 29020008421/958L | 2 |
| 81 | Фонарь задний | Rear light | 4130000270/4130000213 | 6 |
| 82 | Шайба регулировочная | Adjusting washer | 4043000151/60*130*2/4043000151-2 | 50 |
| 83 | Шпонка | Key | 4090000008/GB308-9.525-GCr15 | 10 |
| 84 | Штифт | Pin | 4016000113 | 10 |
| 85 | Вал коленчатый двигателя | Crankshaft of the engine | 13032128/13032128+001/4110000909105/12272496/Deutz WP6G125 | 3 |
| 86 | Держатель ролика | Roller Holder | 13020864/Deutz/TD226B-6G | 4 |
| 87 | Поршневая группа двигателя | Engine piston group | 13020377/Deutz/TBD226B-6D | 1 |
| 88 | Прокладка крышки клапанов двигателя | Engine valve cover gasket | 12270879/Deutz/TD226B-6/WP6G125E22 | 200 |
| 89 | Поршень | Piston | 612600030015/D=126 G2-II/CDM 855/WD615 LonKing | 6 |
| 90 |