Descripción del Producto
Descripción del Producto
China Manufacturer Auto Parts Timing Belt Xihu (West Lake) Dis. Pulley Tensioner Pulley OEM 83062 A1 for Peugeot 308 Series
Water Pump for CITROEN
Water Pump for PEUGEOT
All kinds of car water pumps can be produced for you. Welcome to your inquiry.
| MIC NO. | REF&OEM NO | APPLICATION | YEAR | PHOTO |
| TB34BM9501 | 201160 030145299F 030145299C 030145299 | BMW 1 (E87) 130 i BMW 3 (E90) 325 i BMW 3 (E90) 330 i BMW 3 Convertible (E46) 325 Ci BMW 3 Convertible (E93) 325 i BMW 3 Convertible (E93) 330 i BMW 3 Coupe (E46) 325 Ci BMW 3 Touring (E91) 325 i BMW 5 (E39) 520 i BMW 5 (E39) 528 i BMW 5 (E60) 523 i BMW 5 (E60) 525 i BMW 5 (E60) 530 i BMW 5 (E60) 530 i xDrive BMW 5 Touring (E61) 530 i BMW 6 (E63) 630 i BMW 6 Convertible (E64) 630 i BMW 7 (E38) 728 i, iL BMW 7 (E65, E66, E67) 730 i, Li BMW 7 (E65, E66, E67) 735 i, Li BMW 7 (E65, E66, E67) 745 i, Li BMW 7 (E65, E66, E67) 760 i, Li BMW X1 (E84) xDrive 25 i BMW X1 (E84) xDrive 28 i BMW X3 (E83) 2.5 i BMW X3 (E83) 2.5 si BMW X3 (E83) 3.0 i xDrive BMW X3 (E83) 3.0 si BMW X5 (E53) 3.0 i BMW X5 (E70) 3.0 si BMW Z4 Roadster (E85) 2.2 i BMW Z4 Roadster (E85) 2.5 i BMW Z4 Roadster (E85) 2.5 si BMW Z4 Roadster (E85) 3.0 i BMW Z4 Roadster (E85) 3.0 si BMW Z4 Roadster (E89) sDrive 23 i BMW Z4 Roadster (E89) sDrive 30 i OPEL OMEGA B (V94) 2.2 16V (F69, M69, P69) SEAT IBIZA IV (6J5, 6P1) 1.4 TSI SKODA OCTAVIA II Combi (1Z5) 1.8 TSI VW (SVW) POLO Hatchback (9J1) 1.4 VW (SVW) POLO Saloon (9J2) 1.4 | 2004-2011 2004-2011 2000-2006 2006-2571 2007-2013 2000-2006 2004-2008 1996-2003 1995-2000 2004-2009 2003-2005 2001-2009 2008-2009 2004-2571 2004-2571 2004-2571 1995-2001 2003-2008 2001-2005 2001-2005 2003-2008 2571-2011 2009-2011 2004-2006 2006-2008 2003-2006 2006-2008 2000-2006 2006-2008 2003-2005 2002-2005 2006-2008 2002-2005 2006-2008 2009-2011 2009-2011 1999-2003 2009-2015 2007-2013 2002-2006 2003-2006 |
Perfil de la empresa
Our Factory
Exhibition Shows
Preguntas frecuentes
Q1: Are you a trading company or manufacturer?
A1: We are industrial and export combination.
Q2: If there’s any quality problem, what would you do to guarantee our rights?
Q2: We seldom get complains from our customers so far. If it really happens, we’ll be responsible for that.
Q3: How long is your delivery time?
Q3: Around 30-45 days if no stock; Around 7 days when stock available.
Q4: What’s your sample policy?
A4: Samples under $50.0 will be no charge, however the freight charge should be borne on buyer’s account.
Normal delivery time will be 4 days when stock available.
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| After-sales Service: | Online Technical Support |
|---|---|
| Warranty: | 1 Year |
| Car Make: | FOR PEUGEOT |
| Car Model: | FOR PEUGEOT 307 |
| Lead time: | 60-90 days |
| OEM service: | Disponible |
| Muestras: | US$ 15/Piece 1 unidad (pedido mínimo) | |
|---|
| Personalización: | Disponible | Solicitud personalizada |
|---|

How do timing pulleys contribute to efficient power distribution?
Timing pulleys play a crucial role in ensuring efficient power distribution in various mechanical systems. Here’s how timing pulleys contribute to efficient power distribution:
1. Precise Timing and Synchronization:
Timing pulleys, in conjunction with timing belts or chains, synchronize the rotation of different components within a system. By maintaining precise timing between the input and output shafts, timing pulleys ensure that power is distributed accurately and efficiently. This synchronization prevents power loss due to misalignment or timing discrepancies.
2. Positive Drive System:
Timing pulleys create a positive drive system when paired with timing belts or chains. The teeth on the pulleys interlock with the teeth on the belt or chain, creating a firm grip that eliminates slippage. This positive drive ensures that power is efficiently transmitted from the driving pulley to the driven pulley without any energy loss.
3. Load Distribution:
Timing pulleys help distribute the load evenly across the system by transmitting power from the driving pulley to the driven pulley. The pulley’s design and tooth profile enable the load to be distributed over a larger contact area, reducing stress concentration on individual components. This even load distribution enhances the overall efficiency of power transmission.
4. Reduced Friction and Wear:
Timing pulleys, particularly those made of materials with low friction coefficients, minimize friction and wear during power transmission. The smooth engagement between the pulley teeth and the belt or chain reduces energy losses caused by friction. Additionally, materials with excellent wear resistance properties extend the lifespan of the pulleys, ensuring long-term efficiency.
5. Control de tensión:
Timing pulleys, in combination with tensioner and idler pulleys, help maintain the appropriate tension in the timing belt or chain. Proper tension control ensures that the belt or chain remains securely engaged with the pulleys, preventing power loss due to slippage. By maintaining optimal tension, timing pulleys contribute to efficient power distribution throughout the system.
6. System Optimization:
Timing pulleys allow for system optimization by providing flexibility in gear ratios and power transmission configurations. By selecting pulleys with different diameters or tooth profiles, engineers can adjust the speed and torque distribution within the system. This optimization ensures that power is distributed efficiently, matching the requirements of the specific application.
Overall, timing pulleys ensure efficient power distribution by providing precise timing, creating a positive drive system, evenly distributing loads, reducing friction and wear, controlling tension, and enabling system optimization. These factors contribute to the overall efficiency, reliability, and performance of mechanical systems where timing pulleys are utilized.

Can timing pulleys be part of conveyor systems for material handling?
Yes, timing pulleys can indeed be part of conveyor systems for material handling. Here’s an explanation of how timing pulleys are utilized in conveyor systems:
Conveyor systems are commonly used in industries such as manufacturing, logistics, and packaging to transport materials or products from one location to another. Timing pulleys play a crucial role in these systems by facilitating the movement and control of the conveyor belts.
1. Transmisión de potencia:
Timing pulleys are used in conveyor systems to transmit power from the motor to the conveyor belt. The motor drives the driving pulley, which is connected to the motor shaft, while the driven pulley is connected to the conveyor belt. The rotational motion of the motor is transferred to the driven pulley through a timing belt or chain, causing the conveyor belt to move. Timing pulleys ensure efficient power transmission, allowing the conveyor system to handle different loads and operate reliably.
2. Speed Control:
Timing pulleys allow for speed control in conveyor systems. By varying the diameter or the number of teeth on the driving and driven pulleys, different gear ratios can be achieved. This enables operators to adjust the speed of the conveyor belt according to the specific requirements of the material handling process. Speed control is important for optimizing production flow, ensuring proper material handling, and preventing damage or spillage of the transported items.
3. Synchronization:
Timing pulleys ensure precise and synchronized movement of the conveyor belt. The teeth on the timing belt or chain mesh with the teeth on the pulleys, creating positive engagement. This ensures that the conveyor belt moves in a coordinated manner and prevents slippage or misalignment. Synchronization is crucial for maintaining the integrity of the material handling process, especially when dealing with delicate or fragile items that require gentle handling.
4. Tensioning and Tracking:
Timing pulleys are used in conveyor systems to apply tension to the timing belt or chain and maintain proper tracking of the conveyor belt. Tensioning devices, such as idler pulleys or tensioners, are employed to adjust the tension and ensure the correct alignment of the timing belt or chain on the pulleys. Proper tensioning and tracking prevent belt or chain slippage, reduce wear and tear, and promote smooth and reliable operation of the conveyor system.
5. Diverse Conveyor Configurations:
Timing pulleys offer flexibility in designing conveyor systems for various material handling applications. They can be used in straight conveyor configurations, where the driving and driven pulleys are aligned on the same plane. Additionally, timing pulleys can be employed in curved conveyor systems, where the pulleys are designed to facilitate smooth and controlled changes in the conveyor belt’s direction. This allows for efficient material flow and adaptability to different layouts and spatial constraints.
By incorporating timing pulleys into conveyor systems, material handling processes can be optimized for efficiency, accuracy, and reliability. The precise movement, speed control, synchronization, and tensioning provided by timing pulleys contribute to smooth operation, reduced downtime, and improved productivity in industrial material handling applications.

¿Qué es una polea de distribución y cómo se utiliza en los sistemas mecánicos?
Una polea de distribución, también conocida como polea síncrona, es un tipo de polea diseñada específicamente para funcionar con correas dentadas o correas de distribución. Presenta ranuras o dientes en su superficie circunferencial que engranan con los dientes correspondientes de la correa. Las poleas de distribución se utilizan en sistemas mecánicos que requieren una transmisión de potencia precisa y sincronizada, donde la sincronización y el posicionamiento exactos son cruciales. A continuación, se explica la función y el uso de las poleas de distribución en los sistemas mecánicos:
1. Transmisión de potencia:
La función principal de una polea de distribución es transmitir el movimiento rotacional y la potencia entre dos o más ejes en un sistema mecánico. Los dientes de la polea engranan con los de la correa de distribución, creando un sistema de transmisión positiva. Este engranaje positivo garantiza que la polea y la correa se muevan juntas sin deslizarse, proporcionando una sincronización precisa y una transmisión de potencia óptima.
2. Sincronización:
Las poleas de distribución se utilizan para sincronizar la rotación de diferentes componentes en un sistema mecánico. Mediante el uso de correas y poleas de distribución compatibles, el movimiento de rotación de la polea motriz se transmite con precisión a las poleas conducidas. Esta sincronización es fundamental en aplicaciones que requieren una sincronización precisa, como en motores, impresoras, máquinas CNC y robótica.
3. Control de velocidad y par motor:
Las poleas de sincronización permiten controlar la velocidad y el par en sistemas mecánicos. Al variar el diámetro o el número de dientes de las poleas, se pueden lograr diferentes relaciones de velocidad entre los ejes motriz y conducido. Esta característica permite ajustar la velocidad de rotación y el par según los requisitos específicos de la aplicación.
4. Posicionamiento e indexación:
Las poleas de distribución se utilizan frecuentemente para el posicionamiento y la indexación precisos de componentes en sistemas mecánicos. Los dientes de la polea y la correa de distribución garantizan un movimiento y posicionamiento exactos de las piezas, lo que permite un movimiento repetible y controlado. Esto hace que las poleas de distribución sean idóneas para aplicaciones como líneas de montaje automatizadas, impresoras 3D y sistemas de control de movimiento de precisión.
5. Bajo mantenimiento:
Las poleas y correas de distribución requieren un mantenimiento mínimo gracias a su diseño. El perfil dentado evita el deslizamiento y elimina la necesidad de ajustes constantes de tensión. Además, funcionan con un mínimo de ruido y vibración, lo que reduce el desgaste del sistema y aumenta su fiabilidad general.
6. Variaciones y configuraciones:
Las poleas de distribución están disponibles en diversos tamaños, materiales y configuraciones para adaptarse a diferentes aplicaciones. Pueden fabricarse con materiales como aluminio, acero o plástico, según los requisitos del sistema. Además, pueden tener diferentes perfiles de dientes, pasos y número de dientes, lo que permite personalizarlas según las necesidades específicas de transmisión de potencia.
En resumen, las poleas de sincronización son poleas especializadas que se utilizan en sistemas mecánicos para proporcionar una transmisión de potencia precisa y sincronizada, una sincronización y posicionamiento exactos, control de velocidad y par, y un funcionamiento que requiere poco mantenimiento. Su uso es frecuente en aplicaciones que requieren un movimiento fiable y controlado, como motores, robótica, máquinas CNC y sistemas automatizados.


Editor por CX
2024-03-06