China wholesaler High Accuracy C5 Level Stainless Steel Ball Screw Lead

Product Description

 

Product Description

HIGH QUALITY ROLLED BALL SCREW :

Sketchs and dimensions

ROLLED BALL SCREW FSY SERIES SPECIFICATION 

Model no. d I Da Specification Ca(kgf) Coa(kgf) kgf/
μm
D A E B L W H X Q n
  FSY01616-3.6 16   16 2.778 32 53 10.1   10 45   42 34 4.5 M6 1.8×2 1073 2551 31
  FSY57120-3.6 20   20 3.175 39 62 13   10 52    50 41 5.5 M6 1.8×2 1387 3515 37
 FSY57125-3.6 25   25 3.969 47 74 15   12 64   60 49 6.6 M6 1.8×2 2074 5494 45
  FSY03232-3.6 32   32 4.762 58 92 17   12 78   74 60 9 M6 1.8×2 3571 8690 58
  FSY04040-3.6 40   40 6.35 73 114 19.5   15 99   93 75 11 M6 1.8×2 4831 14062 70
FSY05050-3.6  50   50 7.938 90 135 21.5   20 117 112 92 14 M6 1.8×2 7220 21974 86
Model no. d I Da Specification Ca(kgf) Coa(kgf) kgf/
μm
D A E B L W H X Q n
  FSY01632-1.6 16   32 2.778 32 53 10.1   10 42.5   42 34 4.5 M6 0.8×2 493 1116 11
  FSY57140-1.6 20   40 3.175 39 62 13   10 48    50 41 5.5 M6 0.8×2 653 1597 15
  FSY57150-1.6 25   50 3.969 47 74 15   12 58   60 49 6.6 M6 0.8×2 976 2495 19
  FSY03264-1.6 32   64 4.762 58 92 17   12 71   74 60 9 M6 0.8×2 1374 3571 22
  FSY04080-1.6 40   80 6.35 73 114 19.5   15 90   93 75 11 M6 0.8×2 2273 6387 29
FSY 0571 10-1.6  50 100 7.938 90 135 21.5   20 111 112 92 14 M6 0.8×2 3398 9980 35

 

Detailed Photos

Part no. definition

Other series

FSU Series

Model no. Specification
d I Da D A B L W H X Q n Ca(kgf) Coa(kgf) kgf/
μm
FSU01605-4 ☆ 16 5 3.175 28 48 10 45 38 40 5.5 M6 1×4 1380 3052 32
FSU01610-3 10 3.175 28 48 10 57 38 40 5.5 M6 1×3 1103 2401 26
FSU57105-4 ☆ 20 5 3.175 36 58 10 51 47 44 6.6 M6 1×4 1551 3875 39
FSU57105-4 ☆ 25 5 3.175 40 62 10 51 51 48 6.6 M6 1×4 1724 4904 45
FSU57110-4 10 4.762 40 62 12 80 51 48 6.6 M6 1×4 2954 7295 50
FSU03205-4 ☆ 32 5 3.175 50 80 12 52 65 62 9 M6 1×4 1922 6343 54
FSU03210-4 ☆ 10 6.35 50 80 12 85 65 62 9 M6 1×4 4805 12208 61
FSU04005-4 ☆ 40 5 3.175 63 93 14 55 78 70 9 M8 1×4 2110 7988 63
FSU5711-4 ☆ 10 6.35 63 93 14 88 78 70 9 M8 1×4 5399 15500 73
FSU 0571 1-4 ☆ 50 10 6.35 75 110 16 88 93 85 11 M8 1×4 6004 19614 85
FSU 0571 0-4  63 10 6.35 90 125 18 93 108 95 11 M8 1×4 6719 25358 99
FSU 0571 1-4  80 10 6.35 105 145 20 93 125 110 13.5 M8 1×4 7346 31953 109
FSU01204-4 12 4 2.5 24 40 10 40 32 30 4.5   1×4 902 1884 26
FSU01604-4 16 4 2.381 28 48 10 40 38 40 5.5 M6 1×4 973 2406 32
FSU57104-4 20 4 2.381 36 58 10 42 47 44 6.6 M6 1×4 1066 2987 38
FSU57104-4 25 4 2.381 40 62 10 42 51 48 6.6 M6 1×4 1180 3795 43
FSU57106-4 6 3.969 40 62 10 54 51 48 6.6 M6 1×4 2318 6057 47
FSU57108-4 8 4.762 40 62 10 63 51 48 6.6 M6 1×4 2963 7313 49
FSU03204-4 32 4 2.381 50 80 12 44 65 62 9 M6 1×4 1296 4838 51
FSU03206-4 6 3.969 50 80 12 57 65 62 9 M6 1×4 2632 7979 57
FSU03208-4 8 4.762 50 80 12 65 65 62 9 M6 1×4 3387 9622 60
FSU04006-4 40 6 3.969 63 93 14 60 78 70 9 M6 1×4 2873 9913 66
FSU04008-4 8 4.762 63 93 14 67 78 70 9 M6 1×4 3712 11947 70
FSU 0571 0-4  63 20 9.525 95 135 20 149 115 100 13.5 M8 1×4 11444 36653 112
FSU 0571 1-4  80 20 9.525 125 165 25 154 145 130 13.5 M8 1×4 12911 47747 138
FSU1571-4  100 20 9.525 150 202 30 180 170 155 17.5 M8 1×4 14303 60698 162

FSI Series

Model no. d I Da Specification Ca(kgf) Coa(kgf) kgf/
μm
D A B L W H X Y Z Q n
FSI01605-4 ☆ 16 5 3.175 30 49 10 45 39 34 4.5 8 4.5 M6 1×4 1380 3052 33
FSI01610-3 10 3.175 34 58 10 57 45 34 5.5 9.5 5.5 M6 1×3 1103 2401 27
FSI57105-4 ☆ 20 5 3.175 34 57 11 51 45 40 5.5 9.5 5.5 M6 1×4 1551 3875 39
FSI57105-4 ☆ 25 5 3.175 40 63 11 51 51 46 5.5 9.5 5.5 M8 1×4 1724 4904 45
FSI57110-4 10 4.762 46 72 12 80 58 52 6.5 11 6.5 M6 1×4 2954 7295 51
FSI03205-4 ☆ 32 5 3.175 46 72 12 52 58 52 6.5 11 6.5 M8 1×4 1922 6343 52
FSI03210-4 ☆ 10 6.35 54 88 15 85 70 62 9 14 8.5 M8 1×4 4805 12208 62
FSI04005-4 ☆ 40 5 3.175 56 90 15 55 72 64 9 14 8.5 M8 1×4 2110 7988 59
FSI5711-4 ☆ 10 6.35 62 104 18 88 82 70 11 17.5 11 M8 1×4 5399 15500 72
FSI 0571 1-4 ☆ 50 10 6.35 72 114 18 88 92 82 11 17.5 11 M8 1×4 6004 19614 83
FSI 0571 0-4  63 10 6.35 85 131 22 93 107 95 14 20 13 M8 1×4 6719 25358 95
FSI 0571 1-4  80 10 6.35 105 150 22 93 127 115 14 20 13 M8 1×4 7346 31953 109
FSI01604-4 16 4 2.381 30 49 10 45 39 34 4.5 8 4.5 M6 1×4 973 2406 32
FSI57104-4 20 4 2.381 34 57 11 46 45 40 5.5 9.5 5.5 M6 1×4 1066 2987 37
FSI5715T-4 5.08 3.175 34 57 11 51 45 40 5.5 9.5 5.5 M6 1×4 1550 3875 39
FSI57104-4 25 4 2.381 40 63 11 46 51 46 5.5 9.5 5.5 M6 1×4 1180 3795 43
FSI5715T-4 5.08 3.175 40 63 11 51 51 46 5.5 9.5 5.5 M8 1×4 1724 4903 45
FSI03204-4 32 4 2.381 46 72 12 47 58 52 6.5 11 6.5 M6 1×4 1296 4838 49

 

Company Profile

ZheJiang CHINAMFG Precision Technology Co.,Ltd. 
is a professional manufacturer of linear guide, linear module and ball screw etc.she is located in HangZhou city,ZheJiang ,China.The production base covers 33333 square CHINAMFG and holds a building area of 16000 square CHINAMFG at present. with over 10 years’ effort of our whole team. and also trust and support from our respected customers. We are so lucky to become 1 famous brand in China, who make international standard products.we aim to serve customers world-widely.

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Precision: C5 / C7
Screw Diameter: 1-10mm
Flange: With Flange
Nut Number: Single
Rows Number: 4-Row
Nut Type: Circulator
Samples:
US$ 20/Piece
1 Piece(Min.Order)

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Customization:
Available

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lead screw

What maintenance practices are recommended for lead screws to ensure optimal functionality?

Maintaining lead screws is crucial for ensuring their optimal functionality and longevity. Regular maintenance practices can help prevent issues such as wear, backlash, and premature failure. Here are some recommended maintenance practices for lead screws:

  1. Cleaning: Regularly clean the lead screw and nut to remove dirt, debris, and contaminants that can cause friction and wear. Use a soft brush or cloth to gently wipe away any buildup. Avoid using abrasive materials or harsh chemicals that can damage the surfaces.
  2. Lubrication: Proper lubrication is essential for reducing friction and ensuring smooth operation of the lead screw. Follow the manufacturer’s recommendations for lubrication intervals and use the appropriate lubricant for the specific application. Apply the lubricant evenly along the entire length of the screw, ensuring that it reaches the threads and engages with the nut. Be careful not to over-lubricate, as excess lubricant can attract more dirt and debris.
  3. Inspection: Regularly inspect the lead screw for any signs of wear, damage, or misalignment. Look for excessive backlash, unusual noise during operation, or visible signs of wear on the threads. Check the nut for any signs of wear, such as uneven or flattened threads. If any issues are detected, take appropriate measures to address them, such as replacing worn components or realigning the system.
  4. Tension Adjustment: If the lead screw system utilizes tensioning mechanisms, such as adjustable tension nuts or spring-loaded devices, periodically check and adjust the tension as needed. Proper tension ensures proper engagement between the screw and nut, minimizing backlash and maintaining accurate positioning.
  5. Protection: Protect the lead screw from environmental factors that can contribute to corrosion or damage. If the lead screw is exposed to moisture, chemicals, or extreme temperatures, consider implementing protective measures such as using covers, seals, or coatings to shield the screw and nut. This is particularly important for lead screws operating in outdoor or harsh industrial environments.
  6. Training and Operator Practices: Provide proper training to operators who work with lead screw systems. Ensure they understand the correct operating procedures, including any specific maintenance requirements. Encourage operators to report any abnormalities or issues promptly to prevent further damage or downtime.

By following these maintenance practices, lead screw systems can operate optimally and have a longer service life. Regular cleaning, appropriate lubrication, thorough inspection, tension adjustment, protection from external factors, and proper operator practices are all essential for ensuring the optimal functionality and reliability of lead screws.

lead screw

Are there innovations or advancements in lead screw technology that have emerged in recent years?

In recent years, there have been notable innovations and advancements in lead screw technology aimed at improving performance, efficiency, precision, and durability. These advancements have been driven by the demand for more sophisticated machinery and automation systems. Here are some key innovations in lead screw technology that have emerged in recent years:

  1. Anti-Backlash Designs: Backlash, which refers to the play or clearance between the screw and nut, has been a longstanding challenge in lead screw systems. To address this issue, innovative anti-backlash designs have been developed. These designs incorporate mechanisms such as preloading systems, split nuts, or adjustable axial play to minimize or eliminate backlash, resulting in improved precision and repeatability.
  2. High-Efficiency Thread Profiles: Traditional lead screws often feature trapezoidal or ACME thread profiles, which can result in higher friction and lower mechanical efficiency. Recent advancements have introduced new thread profiles, such as the “triangular” or “wedge” profiles, which optimize the contact area between the screw and nut, reducing friction and improving mechanical efficiency. These high-efficiency thread profiles offer smoother operation, increased load-carrying capacity, and improved energy efficiency.
  3. Lead Screw Coatings and Surface Treatments: Coatings and surface treatments have been developed to enhance the durability, wear resistance, and lubrication properties of lead screws. For example, advanced coatings like Teflon, ceramic, or DLC (Diamond-Like Carbon) coatings provide low friction, reduce wear, and improve the lifespan of the lead screw. These coatings also help prevent contaminants from adhering to the surfaces, minimizing the risk of damage or performance degradation.
  4. Integrated Lubrication Systems: Lubrication is crucial for smooth operation and longevity of lead screws. Recent advancements have introduced integrated lubrication systems that automatically deliver a controlled amount of lubricant to the screw and nut. These systems ensure consistent and optimal lubrication, reducing friction, wear, and the need for manual lubrication maintenance. Integrated lubrication systems can be particularly beneficial in applications where access to the lead screw is limited or in environments where contamination risks are high.
  5. Smart and Connected Lead Screw Systems: The rise of Industry 4.0 and the Internet of Things (IoT) has led to the development of smart and connected lead screw systems. These systems feature embedded sensors, communication capabilities, and data analytics algorithms. They enable real-time monitoring of operating parameters, condition monitoring, predictive maintenance, and performance optimization. Smart lead screw systems provide valuable insights, enhance operational efficiency, and reduce downtime by enabling proactive maintenance and troubleshooting.
  6. Hybrid Lead Screw Technologies: Hybrid lead screw technologies combine the advantages of different types of screws, such as combining a traditional lead screw with a ball screw or roller screw elements. This fusion results in enhanced performance characteristics, such as increased load capacity, improved efficiency, reduced friction, and higher precision. Hybrid lead screws offer a cost-effective alternative to high-precision ball screws while providing superior performance compared to traditional lead screws.

These recent innovations and advancements in lead screw technology have significantly improved the performance, efficiency, precision, and durability of lead screw systems. Anti-backlash designs, high-efficiency thread profiles, advanced coatings, integrated lubrication systems, smart and connected features, and hybrid technologies have expanded the capabilities and application range of lead screws in various industries, including aerospace, automotive, robotics, and industrial automation.

lead screw

Can you explain the role of a lead screw in converting rotary motion to linear motion?

A lead screw plays a crucial role in converting rotary motion into linear motion in mechanical systems. It achieves this by utilizing the helical threads on the screw and the corresponding threads on the nut. Here’s a detailed explanation of how a lead screw accomplishes the conversion:

  1. Helical Thread Design: A lead screw is designed with a helical thread that wraps around its cylindrical shaft. The thread is typically a continuous spiral groove with a specific pitch, which is the distance between adjacent threads. The pitch determines the linear distance the nut will travel when the lead screw makes one complete revolution.
  2. Matching Threaded Nut: The lead screw is paired with a nut that has threads matching those on the screw. The nut is typically fixed in place while the lead screw rotates. The nut contains internal threads that engage with the external threads of the lead screw.
  3. Rotary Motion: When the lead screw is rotated, either manually or by a motor-driven mechanism, the helical threads on the screw cause the nut to move linearly along the length of the screw. The direction and magnitude of the linear motion depend on the direction and speed of the screw’s rotation.
  4. Linear Motion: As the lead screw rotates, the engaged threads between the screw and the nut create a force that translates the rotational motion into linear motion. The helical threads on the screw push against the matching threads in the nut, causing the nut to move along the length of the screw. This results in linear displacement of the nut and any attached components.
  5. Precision and Control: The pitch of the lead screw determines the linear distance traveled by the nut for each revolution of the screw. By controlling the rotational motion of the lead screw, precise and controlled linear movement can be achieved. This makes lead screws suitable for applications that require accurate positioning or adjustment of components.
  6. Load Capacity: Lead screws can handle both axial loads (tension or compression forces) and torque. The helical threads distribute the load over a larger surface area, allowing the lead screw to support and transfer significant loads. By incorporating thrust bearings or other supporting elements, the lead screw can handle high loads while maintaining smooth and controlled linear motion.

Overall, the lead screw’s role in converting rotary motion to linear motion relies on the interaction between the helical threads of the lead screw and the matching threads of the nut. This mechanism provides a reliable and precise means to translate rotational motion into linear displacement, making lead screws a valuable component in various mechanical systems and applications.

China wholesaler High Accuracy C5 Level Stainless Steel Ball Screw Lead  China wholesaler High Accuracy C5 Level Stainless Steel Ball Screw Lead
editor by CX 2024-03-27

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