Product Description
| Product Description |
| Warranty | 1 Year | Certification | TS16949 |
| Color | Natural color | Application | Massey Ferguson |
| OEM NO. | 1277261C1 | MOQ | 100 PCS |
| Engravement | Customized | Port | HangZhou/ZheJiang |
Specifications
1.Supply to USA,Europe,and so on
2.Matrial:Body C45 Ball Pin Cr40
3.Professional Perfomance Auto parts supplier
| Detail Images |
| Other Products |
| Our Company |
| Packing & Delivery |
| Certification |
| Our Service |
1. OEM Manufacturing welcome: Product, Package…
2. Sample order
3. We will reply you for your inquiry in 24 hours.
4. after sending, we will track the products for you once every 2 days, until you get the products. When you got the
goods, test them, and give me a feedback.If you have any questions about the problem, contact with us, we will offer
the solve way for you.
| FAQ |
Q1. What is your terms of packing?
A: Generally, we pack our goods in neutral white boxes and brown cartons. If you have legally registered patent,
we can pack the goods in your branded boxes after getting your authorization letters.
Q2. What is your terms of payment?
A: T/T 30% as deposit, and 70% before delivery. We’ll show you the photos of the products and packages
before you pay the balance.
Q3. What is your terms of delivery?
A: EXW, FOB, CFR, CIF, DDU.
Q4. How about your delivery time?
A: Generally, it will take 30 to 60 days after receiving your advance payment. The specific delivery time depends
on the items and the quantity of your order.
Q5. Can you produce according to the samples?
A: Yes, we can produce by your samples or technical drawings. We can build the molds and fixtures.
Q6. What is your sample policy?
A: We can supply the sample if we have ready parts in stock, but the customers have to pay the sample cost and
the courier cost.
Q7. Do you test all your goods before delivery?
A: Yes, we have 100% test before delivery
Q8: 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. /* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
| After-sales Service: | Help Check |
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| Warranty: | 1 Year |
| Type: | Tie Rod End |
| Samples: |
US$ 15/Piece
1 Piece(Min.Order) | Order Sample |
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| Customization: |
Available
| Customized Request |
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Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
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| Payment Method: |
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Initial Payment Full Payment |
| Currency: | US$ |
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| Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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What are the potential challenges in designing and manufacturing universal joints?
Designing and manufacturing universal joints can present various challenges that need to be addressed to ensure optimal performance and reliability. Here’s a detailed explanation:
1. Misalignment Compensation: Universal joints are primarily designed to accommodate angular misalignment between two shafts. Designing a universal joint that can effectively compensate for misalignment while maintaining smooth power transmission can be challenging. The joint must provide flexibility without sacrificing strength or introducing excessive play, which could lead to vibration, noise, or premature wear.
2. Torque Transmission: Universal joints are often used in applications that require the transfer of high torque loads. Designing the joint to handle these loads without failure or excessive wear is a significant challenge. The selection of appropriate materials, heat treatment processes, and bearing designs becomes crucial to ensure the strength, durability, and reliability of the joint.
3. Lubrication and Sealing: Universal joints require proper lubrication to minimize friction, heat generation, and wear between the moving components. Designing an effective lubrication system that ensures sufficient lubricant supply to all critical areas can be challenging. Additionally, designing seals and protective covers to prevent contamination and retain lubrication presents a challenge, as the joint must maintain flexibility while ensuring adequate sealing.
4. Bearing Design and Wear: Universal joints rely on bearings to facilitate smooth rotation and to support the shafts. Designing the bearing arrangement to withstand the loads, maintain proper alignment, and resist wear is essential. Choosing the appropriate bearing type, such as needle bearings or plain bearings, and optimizing their size, material, and lubrication conditions are key challenges in the design process.
5. Manufacturability: Manufacturing universal joints with precision and consistency can be challenging due to their complex geometries and the need for tight tolerances. The manufacturing process must ensure accurate machining, assembly, and balancing of the joint components to achieve proper fit, alignment, and balance. Specialized machining techniques and quality control measures are often required to meet the desired specifications.
6. Cost and Size Optimization: Designing universal joints that are cost-effective and compact while meeting performance requirements can be a challenging task. Balancing the need for robustness, durability, and material efficiency with cost considerations requires careful engineering and optimization. Designers must strike a balance between performance, weight, space constraints, and manufacturing costs to create an efficient and economical universal joint.
7. Application-Specific Considerations: Designing universal joints for specific applications may introduce additional challenges. Factors such as environmental conditions, temperature extremes, exposure to corrosive substances, high-speed operation, or heavy-duty applications need to be carefully considered and addressed in the design and material selection process. Customization and adaptation of universal joints to meet unique application requirements can pose additional challenges.
Addressing these challenges in the design and manufacturing process requires a combination of engineering expertise, material science knowledge, advanced manufacturing techniques, and thorough testing and validation procedures. Collaboration between design engineers, manufacturing engineers, and quality control personnel is crucial to ensure the successful development and production of reliable universal joints.
In summary, the potential challenges in designing and manufacturing universal joints include misalignment compensation, torque transmission, lubrication and sealing, bearing design and wear, manufacturability, cost and size optimization, and application-specific considerations. Overcoming these challenges requires careful engineering, precision manufacturing processes, and consideration of various factors to achieve high-performance and reliable universal joints.
How do you address the effect of temperature variations on a universal joint?
Addressing the effect of temperature variations on a universal joint involves considering factors such as material selection, lubrication, and thermal expansion. Here’s a detailed explanation:
Temperature variations can have an impact on the performance and durability of universal joints. Extreme temperatures can affect the materials, lubrication, and dimensional stability of the joint components. To address these effects, the following measures can be taken:
- Material Selection: Choosing materials with appropriate temperature resistance is crucial. The materials used in universal joints should have a suitable operating temperature range to withstand the expected temperature variations. For example, selecting heat-resistant alloys or materials with low thermal expansion coefficients can help mitigate the effects of temperature changes.
- Lubrication: Proper lubrication is essential for reducing friction and wear in universal joints, especially under temperature variations. Lubricants with high-temperature stability and viscosity should be selected to ensure adequate lubrication at both low and high temperatures. It’s important to follow the manufacturer’s recommendations regarding lubrication intervals and the use of lubricants suitable for the operating temperature range.
- Thermal Expansion Compensation: Universal joints can experience dimensional changes due to thermal expansion or contraction. These changes can affect the alignment and performance of the joint. To address this, measures such as incorporating design features that allow for thermal expansion compensation, using materials with low thermal expansion coefficients, or incorporating flexible elements can help minimize the impact of temperature variations on the joint’s operation.
- Insulation: In situations where extreme temperatures are anticipated, providing insulation or heat shielding around the universal joint can help maintain more stable operating conditions. Insulation materials can help reduce the transfer of heat to or from the joint, minimizing the temperature variations experienced by the components.
- Temperature Monitoring: Regular monitoring of the operating temperature of the universal joint can help identify any abnormal temperature variations that may indicate issues with lubrication, excessive friction, or other problems. Temperature sensors or thermal imaging techniques can be utilized for monitoring purposes.
It’s important to note that the specific measures taken to address temperature variations may depend on the application, the expected temperature range, and the manufacturer’s recommendations. Additionally, proper maintenance practices, including inspection, cleaning, and lubrication, are essential for ensuring the optimal performance and longevity of universal joints under temperature variations.
In summary, addressing the effect of temperature variations on a universal joint involves considering material selection, lubrication, thermal expansion compensation, insulation, and temperature monitoring. By implementing appropriate measures, the impact of temperature variations on the universal joint’s performance and durability can be minimized.
How do you choose the right size universal joint for your application?
Choosing the right size universal joint for a specific application involves considering several factors to ensure proper function and performance. Here are key steps to guide you in selecting the appropriate size:
- Identify the application requirements: Determine the specific requirements of your application, such as the maximum torque, speed, angular misalignment, and operating conditions. Understanding these parameters will help in selecting a universal joint that can handle the demands of your application.
- Shaft sizes and connection type: Measure the diameter and type of the shafts that need to be connected by the universal joint. Ensure that the joint you choose has compatible connection options for the shafts, such as keyways, splines, or smooth bores.
- Load capacity: Consider the load capacity or torque rating of the universal joint. It should be capable of handling the maximum torque expected in your application without exceeding its rated capacity. Refer to the manufacturer’s specifications and guidelines for load ratings.
- Operating speed: Take into account the operating speed of your application. Universal joints have speed limitations, and exceeding these limits can result in premature wear, heat generation, and failure. Ensure that the selected joint can handle the required rotational speed without compromising performance.
- Angular misalignment: Determine the maximum angular misalignment between the shafts in your application. Different types of universal joints have varying degrees of angular misalignment capabilities. Choose a joint that can accommodate the required misalignment while maintaining smooth operation.
- Environmental conditions: Assess the environmental conditions in which the universal joint will operate. Consider factors such as temperature, humidity, exposure to chemicals or contaminants, and the presence of vibrations or shocks. Select a joint that is designed to withstand and perform reliably in the specific environmental conditions of your application.
- Consult manufacturer guidelines: Refer to the manufacturer’s guidelines, catalog, or technical documentation for the universal joint you are considering. Manufacturers often provide detailed information on the selection criteria, including sizing charts, application guidelines, and compatibility tables. Following the manufacturer’s recommendations will ensure proper sizing and compatibility.
By following these steps and considering the specific requirements of your application, you can choose the right size universal joint that will provide reliable and efficient operation in your system.
editor by CX 2024-04-30
China Custom Universal Joint Double Cardan Joint Coupling for Tractor with high quality
Product Description
Product Description
Universal joint for tractor
Universal joint, also called cardan joint, it is a kind of goods to connect drive shaft and driven shaft.
MIGHTY universal joint, is high precission, speed fast and there are PB, PR, CN, NB series.
pls select from catalog and choose OD, length, and ID.
Shaft hole could be custermized, or with keyway.
| MAIN PRODUCTS |
1) Timing Belt Pulley (Synchronous Pulley), Timing Bar, Clamping Plate;
2) Forging, Casting, Stamping Part;
3) V Belt Pulley and Taper Lock Bush; Sprocket, Idler and Plate Wheel;Spur Gear, Bevel Gear, Rack;
4) Shaft Locking Device: could be alternative for Ringfeder, Sati, Chiaravalli, Tollok, etc.;
5) Shaft Coupling:including Miniature couplings, Curved tooth coupling, Chain coupling, HRC coupling, Normex coupling, Type coupling, GE Coupling, torque limiter, Universal Joint;
6) Shaft Collars: including Setscrew Type, Single Split and Double Splits;
7) Timing Belt: including Rubber and PU timing belts for industrial;
8) Universal joint, bearings
9) Other customized Machining MFG Parts according to drawings (OEM).
| OUR SERVICE |
1) Competitive price and good quality
2) Used for transmission systems.
3) Excellent performance, long using life
4) Could be developed according to your drawings or data sheet
5) Packaging: follow the customers’ requirements or as our usual package
6) Brand name: per every customer’s requirement.
7) Flexible minimum order quantity
8) Sample can be supplied
Product Parameters
Packaging & Shipping
All the products can be packed in cartons,or,you can choose the pallet packing.
MADE IN CHINA can be pressed on wooden cases.Land,air,sea transportation are available.UPS,DHL,TNT,
FedEx and EMS are all supported.
Company Profile
About Mighty Machinery
ZheJiang Mighty Machinery Co., Ltd., specializes in manufacturing Mechanical Power Transmission Products. After over 13 years hard work, MIGHTY have already get the certificate of ISO9001:2000 and become a holding company for 3 manufacturing factories.
MIGHTY anvantage
1, Abundant experience in the mechanical processing industries.
2,Large quality of various material purchase and stock in warhouse which ensure the low cost for the material and production in time.
3,Now have 5 technical staff, we have strong capacity for design and process design, and more than 70 worker now work in our FTY and double shift eveyday.
4,Strick quality control are apply in the whole prodution. we have incoming inspection,process inspection and final production inspection which can ensure the perfect of the goods quality.
5,Long time cooperate with the Global Buyer, make us easy to understand the csutomer and handle the export.
FAQ
Q: Are you trading company or manufacturer ?
A: We are factory.
Q: How long is your delivery time?
A: Generally it is 5-10 days if the goods are in stock. or it is 15-20 days if the goods are not in stock, it is according to quantity.
Q: Do you provide samples ? is it free or extra ?
A: Yes, we could offer the sample for free charge but do not pay the cost of freight.
Q: What is your terms of payment ?
A: Payment=1000USD, 30% T/T in advance ,balance before shippment.
If you have any questions, pls feel free to contact me as below:
Types of Splines
There are 4 types of splines: Involute, Parallel key, helical, and ball. Learn about their characteristics. And, if you’re not sure what they are, you can always request a quotation. These splines are commonly used for building special machinery, repair jobs, and other applications. The CZPT Manufacturing Company manufactures these shafts. It is a specialty manufacturer and we welcome your business.
Involute splines
The involute spline provides a more rigid and durable structure, and is available in a variety of diameters and spline counts. Generally, steel, carbon steel, or titanium are used as raw materials. Other materials, such as carbon fiber, may be suitable. However, titanium can be difficult to produce, so some manufacturers make splines using other constituents.
When splines are used in shafts, they prevent parts from separating during operation. These features make them an ideal choice for securing mechanical assemblies. Splines with inward-curving grooves do not have sharp corners and are therefore less likely to break or separate while they are in operation. These properties help them to withstand high-speed operations, such as braking, accelerating, and reversing.
A male spline is fitted with an externally-oriented face, and a female spline is inserted through the center. The teeth of the male spline typically have chamfered tips to provide clearance with the transition area. The radii and width of the teeth of a male spline are typically larger than those of a female spline. These specifications are specified in ANSI or DIN design manuals.
The effective tooth thickness of a spline depends on the involute profile error and the lead error. Also, the spacing of the spline teeth and keyways can affect the effective tooth thickness. Involute splines in a splined shaft are designed so that at least 25 percent of the spline teeth engage during coupling, which results in a uniform distribution of load and wear on the spline.
Parallel key splines
A parallel splined shaft has a helix of equal-sized grooves around its circumference. These grooves are generally parallel or involute. Splines minimize stress concentrations in stationary joints and allow linear and rotary motion. Splines may be cut or cold-rolled. Cold-rolled splines have more strength than cut spines and are often used in applications that require high strength, accuracy, and a smooth surface.
A parallel key splined shaft features grooves and keys that are parallel to the axis of the shaft. This design is best suited for applications where load bearing is a primary concern and a smooth motion is needed. A parallel key splined shaft can be made from alloy steels, which are iron-based alloys that may also contain chromium, nickel, molybdenum, copper, or other alloying materials.
A splined shaft can be used to transmit torque and provide anti-rotation when operating as a linear guide. These shafts have square profiles that match up with grooves in a mating piece and transmit torque and rotation. They can also be easily changed in length, and are commonly used in aerospace. Its reliability and fatigue life make it an excellent choice for many applications.
The main difference between a parallel key splined shaft and a keyed shaft is that the former offers more flexibility. They lack slots, which reduce torque-transmitting capacity. Splines offer equal load distribution along the gear teeth, which translates into a longer fatigue life for the shaft. In agricultural applications, shaft life is essential. Agricultural equipment, for example, requires the ability to function at high speeds for extended periods of time.
Involute helical splines
Involute splines are a common design for splined shafts. They are the most commonly used type of splined shaft and feature equal spacing among their teeth. The teeth of this design are also shorter than those of the parallel spline shaft, reducing stress concentration. These splines can be used to transmit power to floating or permanently fixed gears, and reduce stress concentrations in the stationary joint. Involute splines are the most common type of splined shaft, and are widely used for a variety of applications in automotive, machine tools, and more.
Involute helical spline shafts are ideal for applications involving axial motion and rotation. They allow for face coupling engagement and disengagement. This design also allows for a larger diameter than a parallel spline shaft. The result is a highly efficient gearbox. Besides being durable, splines can also be used for other applications involving torque and energy transfer.
A new statistical model can be used to determine the number of teeth that engage for a given load. These splines are characterized by a tight fit at the major diameters, thereby transferring concentricity from the shaft to the female spline. A male spline has chamfered tips for clearance with the transition area. ANSI and DIN design manuals specify the different classes of fit.
The design of involute helical splines is similar to that of gears, and their ridges or teeth are matched with the corresponding grooves in a mating piece. It enables torque and rotation to be transferred to a mate piece while maintaining alignment of the 2 components. Different types of splines are used in different applications. Different splines can have different levels of tooth height.
Involute ball splines
When splines are used, they allow the shaft and hub to engage evenly over the shaft’s entire circumference. Because the teeth are evenly spaced, the load that they can transfer is uniform and their position is always the same regardless of shaft length. Whether the shaft is used to transmit torque or to transmit power, splines are a great choice. They provide maximum strength and allow for linear or rotary motion.
There are 3 basic types of splines: helical, crown, and ball. Crown splines feature equally spaced grooves. Crown splines feature involute sides and parallel sides. Helical splines use involute teeth and are often used in small diameter shafts. Ball splines contain a ball bearing inside the splined shaft to facilitate rotary motion and minimize stress concentration in stationary joints.
The 2 types of splines are classified under the ANSI classes of fit. Fillet root splines have teeth that mesh along the longitudinal axis of rotation. Flat root splines have similar teeth, but are intended to optimize strength for short-term use. Both types of splines are important for ensuring the shaft aligns properly and is not misaligned.
The friction coefficient of the hub is a complex process. When the hub is off-center, the center moves in predictable but irregular motion. Moreover, when the shaft is centered, the center may oscillate between being centered and being off-center. To compensate for this, the torque must be adequate to keep the shaft in its axis during all rotation angles. While straight-sided splines provide similar centering, they have lower misalignment load factors.
Keyed shafts
Essentially, splined shafts have teeth or ridges that fit together to transfer torque. Because splines are not as tall as involute gears, they offer uniform torque transfer. Additionally, they provide the opportunity for torque and rotational changes and improve wear resistance. In addition to their durability, splined shafts are popular in the aerospace industry and provide increased reliability and fatigue life.
Keyed shafts are available in different materials, lengths, and diameters. When used in high-power drive applications, they offer higher torque and rotational speeds. The higher torque they produce helps them deliver power to the gearbox. However, they are not as durable as splined shafts, which is why the latter is usually preferred in these applications. And while they’re more expensive, they’re equally effective when it comes to torque delivery.
Parallel keyed shafts have separate profiles and ridges and are used in applications requiring accuracy and precision. Keyed shafts with rolled splines are 35% stronger than cut splines and are used where precision is essential. These splines also have a smooth finish, which can make them a good choice for precision applications. They also work well with gears and other mechanical systems that require accurate torque transfer.
Carbon steel is another material used for splined shafts. Carbon steel is known for its malleability, and its shallow carbon content helps create reliable motion. However, if you’re looking for something more durable, consider ferrous steel. This type contains metals such as nickel, chromium, and molybdenum. And it’s important to remember that carbon steel is not the only material to consider.
