Product Description
MIC NO. | OEM.NO | APPLICATION | YEAR | PHOTO |
TB34OP8701 | 701149 CHINAMFG : 13 0571 0QAD RENAULT : 77571085 |
NISSAN KUBISTAR Box (X76) 1.2 RENAULT 19 I (B/C53_) 1.4 RENAULT 19 II (B/C53_) 1.4 RENAULT 19 II Chamade (L53_) 1.4 RENAULT CLIO I (B/C57_, 5/357_) 1.2 (5/357Y, 5/357K) RENAULT CLIO I (B/C57_, 5/357_) 1.4 RENAULT CLIO II (BB_, CB_) 1.2 (BB0A, BB0F, BB10, BB1K, … RENAULT CLIO II (BB_, CB_) 1.2 LPG RENAULT CLIO II Box (SB0/1/2_) 1.2 (SB0A, SB0F, SB10) RENAULT KANGOO (KC0/1_) 1.2 (KC0A, KC0K, KC0F, KC01) RENAULT KANGOO Express (FC0/1_) 1.2 (FC01, FC0A, FC0F) RENAULT MEGANE I (BA0/1_) 1.4 e (BA0E, BA0V) RENAULT MEGANE I (BA0/1_) 1.6 e (BA0F, BA0S) RENAULT MEGANE I Cabriolet (EA0/1_) 1.6 e (EA0F) RENAULT MEGANE I Classic (LA0/1_) 1.4 (LA0E, LA0V) RENAULT MEGANE I Coach (DA0/1_) 1.6 e (DA0F) RENAULT MEGANE I Grandtour (KA0/1_) 1.6 e (KA0F) RENAULT MEGANE Scenic (JA0/1_) 1.4 i (JA0E) RENAULT RAPID Box (F40_, G40_) 1.4 (F40D) RENAULT TWINGO I (C06_) 1.2 (C066, C068) RENAULT TWINGO II (CN0_) 1.2 (CN0D) |
2003- 1988-1992 1992-1995 1994-1995 1996-1998 1991-1998 1998- 1998-2009 1999-2003 1997- 1997- 1996-2003 1996-1999 1996-1999 1996-2003 1996-1999 1999-2003 1997-1999 1994-1998 1996-2007 2007- |
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After-sales Service: | Online Technical Support |
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Warranty: | One Year |
Car Make: | RENAULT |
Samples: |
US$ 10/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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Can timing pulleys be customized for specific applications?
Yes, timing pulleys can be customized to suit specific applications and requirements. Here’s how timing pulleys can be customized:
1. Size and Dimensions:
Timing pulleys can be customized in terms of their size and dimensions to fit specific shaft diameters, spacing, and clearance requirements. Customization allows engineers to ensure proper alignment and integration of the pulley within the system.
2. Tooth Profile:
The tooth profile of a timing pulley can be customized based on the specific power transmission needs of the application. Different tooth profiles, such as trapezoidal, curvilinear, or modified curvilinear, offer varying levels of engagement, load capacity, and noise characteristics. Customizing the tooth profile allows for optimized performance and efficiency.
3. Material Selection:
Timing pulleys can be customized by selecting the appropriate material based on the application’s requirements. Different materials, such as steel, aluminum, plastic, or composites, offer varying levels of strength, durability, corrosion resistance, and temperature tolerance. Customizing the material ensures compatibility with the operating conditions and environment.
4. Coatings and Surface Treatments:
Custom coatings and surface treatments can be applied to timing pulleys to enhance their performance and longevity. These treatments include but are not limited to hard anodizing, zinc plating, nitriding, or specific coatings for reduced friction, wear resistance, or improved tooth engagement.
5. Flanges and Attachments:
Timing pulleys can be customized with flanges or attachments to facilitate proper belt tracking, prevent belt slippage, or accommodate specific mounting requirements. These additions help ensure reliable and stable power transmission in the application.
6. Keyways and Hubs:
Custom keyways and hubs can be incorporated into timing pulleys to provide precise shaft-to-pulley connection and prevent slippage or misalignment. Keyways and hubs allow for secure and accurate power transmission in applications that require high torque or precise positioning.
7. Prototype and Low-Volume Production:
Timing pulleys can be customized through prototyping and low-volume production processes. This allows for the creation of unique designs, iterations, and testing before full-scale production. Customization at these stages ensures that the final timing pulleys meet the specific requirements of the application.
By offering customization options, timing pulley manufacturers and suppliers can cater to a wide range of industries and applications, including automotive, aerospace, robotics, industrial automation, medical, and more. Customized timing pulleys provide engineers with the flexibility to design systems that meet precise power transmission needs, resulting in optimized performance, reliability, and efficiency.
How do timing pulleys impact the performance of 3D printers?
Timing pulleys play a significant role in determining the performance and accuracy of 3D printers. Here’s an explanation of how timing pulleys impact the performance of 3D printers:
1. Motion Control:
Timing pulleys, in conjunction with belts or chains, are used to control the movement of the print head and build platform in 3D printers. The motor drives the driving pulley, which is connected to the print head or build platform through a timing belt or chain. The driven pulley on the print head or build platform receives the rotational motion from the driving pulley, resulting in precise and synchronized movement. The accuracy and quality of the printed object depend on the precise control and synchronization facilitated by the timing pulleys.
2. Positioning Accuracy:
Timing pulleys contribute to the positioning accuracy of 3D printers. The teeth on the timing belt or chain mesh with the teeth on the pulleys, creating positive engagement. This ensures that the print head or build platform moves precisely according to the instructions from the control system. The accuracy of the timing pulley system directly affects the dimensional accuracy and surface finish of the printed object.
3. Speed and Acceleration:
Timing pulleys allow for control of the speed and acceleration of the print head and build platform in 3D printers. By varying the diameter or the number of teeth on the pulleys, different gear ratios can be achieved. This enables printers to control the speed and acceleration of the print head or build platform, affecting printing time, print quality, and the ability to handle intricate details and complex geometries.
4. Print Resolution:
The resolution of a 3D printer refers to the smallest feature size that can be accurately reproduced. Timing pulleys play a role in determining the achievable print resolution. The finer the pitch and the more teeth per unit length on the timing belt or chain, the higher the resolution that can be achieved. Timing pulleys with smaller teeth allow for finer positioning and more precise movement, enabling the printer to produce objects with intricate details and smooth surfaces.
5. Noise and Vibration:
Properly designed and maintained timing pulley systems contribute to reducing noise and vibration in 3D printers. Well-aligned and tensioned timing belts or chains, along with accurately machined pulleys, minimize backlash and ensure smooth and quiet operation. This is particularly important during rapid movements and changes in direction, as excessive noise and vibration can affect print quality and overall printer performance.
6. Maintenance and Durability:
The durability and maintenance requirements of the timing pulley system impact the overall performance of 3D printers. High-quality timing pulleys and belts or chains are essential to ensure longevity and reliable operation. Regular inspection, tensioning, and replacement of worn or damaged components are necessary to maintain optimal performance and prevent print quality issues caused by a degraded timing pulley system.
7. Extruder and Filament Control:
In addition to controlling the movement of the print head and build platform, timing pulleys may also be used in the extruder assembly of 3D printers. Timing pulleys help drive the filament feeding mechanism, ensuring consistent and controlled extrusion of the filament during the printing process. The accurate and synchronized movement facilitated by the timing pulleys contributes to maintaining filament tension and preventing issues such as under-extrusion or filament jams.
By understanding the impact of timing pulleys on 3D printer performance, manufacturers and users can optimize the design, calibration, and maintenance of the timing pulley systems to achieve accurate, reliable, and high-quality 3D prints.
In which industries are timing pulleys commonly employed?
Timing pulleys find application in various industries where precise motion control, accurate timing, and reliable power transmission are crucial. Here are some industries where timing pulleys are commonly employed:
1. Manufacturing and Automation:
Timing pulleys are extensively used in manufacturing and automation industries. They play a vital role in conveyor systems, robotic arms, pick-and-place machines, packaging equipment, and assembly lines. Timing pulleys ensure precise movement, synchronization, and positioning of components, facilitating efficient and automated production processes.
2. Automotive and Transportation:
The automotive and transportation industries rely on timing pulleys for engine timing and power transmission. Timing pulleys are used in internal combustion engines to synchronize the rotation of the camshaft and crankshaft, ensuring proper valve timing. They are also employed in various vehicle systems such as steering, air conditioning, and powertrain components.
3. Aerospace and Aviation:
In the aerospace and aviation industries, timing pulleys are utilized in applications that require precise motion control and synchronization. They are used in aircraft engines, flight control systems, landing gear mechanisms, and wing flap systems. Timing pulleys contribute to the safety, efficiency, and reliability of aircraft operations.
4. Medical and Healthcare:
In the medical and healthcare fields, timing pulleys are utilized in medical devices, diagnostic equipment, surgical robots, and imaging systems. They enable precise movement and positioning in equipment such as infusion pumps, robotic surgery systems, and CT scanners. Timing pulleys contribute to accurate procedures, patient safety, and improved healthcare outcomes.
5. Printing and Paper Handling:
Printing presses and paper handling equipment utilize timing pulleys to ensure precise paper feeding, registration, and tension control. Timing pulleys enable accurate and synchronized movement of paper rolls, sheets, or labels, ensuring high-quality printing and efficient paper handling processes.
6. Textile and Garment Industry:
In the textile and garment industry, timing pulleys are employed in textile machinery, knitting machines, and sewing equipment. They assist in controlling the movement of fabric, yarn, and threads, ensuring precise and synchronized operations. Timing pulleys contribute to the efficiency and quality of textile and garment production processes.
7. Industrial Automation and Robotics:
Timing pulleys have widespread usage in industrial automation and robotics applications. They are employed in robotic arms, CNC machines, automated guided vehicles (AGVs), and material handling systems. Timing pulleys enable precise and synchronized movement, enhancing productivity, accuracy, and efficiency in industrial automation processes.
8. Semiconductor and Electronics:
The semiconductor and electronics industries utilize timing pulleys in equipment such as wafer handling systems, pick-and-place machines, and semiconductor manufacturing equipment. Timing pulleys ensure precise positioning, alignment, and synchronization of delicate components, contributing to the manufacturing of high-quality electronic devices.
These are just a few examples of industries where timing pulleys are commonly employed. Their versatile nature and ability to provide precise motion control make them valuable components in various applications across different sectors.
editor by CX
2024-04-25