Product Description
MIC NO | OEM.NO | APPLICATION | YEAR | PHOTO |
TB34PG9301 | 957726 082990 9642929880 |
CITROEN BERLINGO / BERLINGO FIRST Box (M_) 1.1 i (MAHDZ, MBHDZ, MBHFX) CITROEN BERLINGO / BERLINGO FIRST Box (M_) 1.4 bivalent CITROEN BERLINGO / BERLINGO FIRST Box (M_) 1.4 i (MBKFX, MBKFW) CITROEN BERLINGO / BERLINGO FIRST Box (M_) 1.4 i bivalent (MBKFW) CITROEN BERLINGO / BERLINGO FIRST MPV (MF_, GJK_, GFK_) 1.1 i (MFHDZ, MFHFX) CITROEN BERLINGO / BERLINGO FIRST MPV (MF_, GJK_, GFK_) 1.4 bivalent CITROEN BERLINGO / BERLINGO FIRST MPV (MF_, GJK_, GFK_) 1.4 i (MFKFX, MFKFW, GJKFWB, GJKFWC, GFKFWC) CITROEN BERLINGO / BERLINGO FIRST MPV (MF_, GJK_, GFK_) 1.4 i bivalent (MFKFW) CITROEN C2 (JM_) 1.1 CITROEN C2 (JM_) 1.4 CITROEN C3 I (FC_, FN_) 1.1 i CITROEN C3 I (FC_, FN_) 1.4 i CITROEN C3 I (FC_, FN_) 1.4 i Bivalent CITROEN C3 II (SC_) 1.1 i CITROEN C3 II (SC_) 1.4 CITROEN C3 Pluriel (HB_) 1.4 CITROEN NEMO Box (AA_) 1.4 CITROEN NEMO Estate 1.4 CITROEN SAXO (S0, S1) 1.1 X,SX CITROEN XSARA (N1) 1.4 i CITROEN XSARA Break (N2) 1.4 i CITROEN XSARA Coupe (N0) 1.4 i FIAT FIORINO Box Body/Estate (225_) 1.4 (225BXA1A, 225BXF1A) FIAT QUBO (225_) 1.4 (225AXA1A) PEUGEOT 1007 (KM_) 1.4 PEUGEOT 106 II (1A_, 1C_) 1.1 i PEUGEOT 206 Hatchback (2A/C) 1.1 PEUGEOT 206 Hatchback (2A/C) 1.1 i PEUGEOT 206 Hatchback (2A/C) 1.4 i PEUGEOT 206 Hatchback (2A/C) 1.4 LPG PEUGEOT 206 Saloon 1.4 PEUGEOT 206 SW (2E/K) 1.1 PEUGEOT 206 SW (2E/K) 1.4 PEUGEOT 206+ (2L_, 2M_) 1.1 PEUGEOT 206+ (2L_, 2M_) 1.4 i PEUGEOT 207 (WA_, WC_) 1.4 PEUGEOT 207 SW (WK_) 1.4 PEUGEOT 306 (7B, N3, N5) 1.1 PEUGEOT 306 (7B, N3, N5) 1.4 SL PEUGEOT 306 Break (7E, N3, N5) 1.4 PEUGEOT 306 Hatchback (7A, 7C, N3, N5) 1.1 PEUGEOT 307 (3A/C) 1.4 PEUGEOT BIPPER (AA_) 1.4 PEUGEOT BIPPER Tepee 1.4 PEUGEOT PARTNER Box (5_, G_) 1.1 PEUGEOT PARTNER Box (5_, G_) 1.4 PEUGEOT PARTNER Box (5_, G_) 1.4 BiFuel PEUGEOT PARTNER Combispace (5_, G_) 1.1 PEUGEOT PARTNER Combispace (5_, G_) 1.4 |
1996-2008 2002-2011 1996-2011 2003-2005 1996-2008 2002-2011 1996-2011 2003-2008 2003-2012 2003-2009 2002- 2002-2571 2002- 2009-2013 2009-2016 2003- 2008- 2009- 1996-2003 1997-2005 1997-2005 1998-2005 2007- 2008- 2005- 1996-2004 1998-2000 1998-2007 1998-2012 2006-2007 2007- 2002- 2002-2007 2009-2013 2009-2013 2006-2013 2007-2012 1994-2001 1994-2001 1997-2002 1993-2001 2000-2003 2008- 2008- 1996-2005 1996-2015 2003-2006 1996-2002 1996-2015 |
After-sales Service: | Online Technical Support |
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Warranty: | One year |
Car Make: | CITROEN |
Car Model: | XSARA Break (N2) 1.4 i |
Sample: | Available |
Application: | XSARA Break (N2) 1.4 i |
Samples: |
US$ 15/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
| Customized Request |
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What are the common problems and maintenance requirements for pulleys?
Pulleys, like any mechanical component, can experience common problems and require regular maintenance to ensure their proper functioning and longevity. Here are some of the common problems and maintenance requirements for pulleys:
1. Wear and Tear: Over time, pulleys can experience wear and tear due to friction, load stress, and environmental factors. This can result in issues such as worn grooves, cracked or deformed pulley bodies, or damaged bearings. Regular inspection is necessary to identify signs of wear and address them promptly.
2. Misalignment: Pulleys can become misaligned, causing the belt or rope to run off its intended path. This can lead to inefficient power transmission, increased wear on the belt, and reduced overall system performance. Regular alignment checks and adjustments are necessary to ensure proper alignment of pulleys and belts.
3. Belt Tension: Proper belt tension is crucial for optimal pulley performance. Over time, belts can stretch or become loose, resulting in inadequate tension. Insufficient tension can cause slippage, reduced power transfer, and premature wear. Regular checks and adjustments of belt tension are necessary to maintain optimal performance.
4. Contamination: Pulleys can accumulate dirt, dust, debris, or other contaminants, particularly in industrial or outdoor environments. Contamination can lead to increased friction, reduced efficiency, and accelerated wear. Regular cleaning of pulleys is necessary to prevent buildup and maintain smooth operation.
5. Lubrication: Pulleys with bearings require proper lubrication to minimize friction and ensure smooth rotation. Insufficient lubrication can lead to increased friction, heat generation, and premature bearing failure. Regular lubrication according to manufacturer recommendations is essential for optimal pulley performance and longevity.
6. Bearing Maintenance: Pulleys with bearings should undergo regular bearing maintenance. This includes inspecting bearings for signs of wear or damage, cleaning them, and replacing worn-out or faulty bearings. Proper bearing maintenance helps prevent bearing failure, which can lead to pulley malfunction or system downtime.
7. Environmental Factors: Pulleys used in outdoor or harsh environments may be exposed to adverse conditions such as extreme temperatures, moisture, chemicals, or corrosive substances. Extra care should be taken to protect pulleys from these environmental factors. This may involve using appropriate seals, covers, or coatings and implementing preventive measures to mitigate the effects of the environment.
8. Regular Inspections: Regular inspections are crucial for identifying potential problems early on. Inspect pulleys for signs of wear, damage, misalignment, or other issues. Address any identified problems promptly to prevent further damage or system failure.
9. Replacement of Worn-out Parts: If any components of the pulley, such as the belt, bearings, or fasteners, are worn out or damaged beyond repair, they should be replaced promptly. Using worn-out parts can compromise the performance and safety of the pulley system.
10. Manufacturer Guidelines: Follow the manufacturer’s guidelines and recommendations for maintenance and servicing of pulleys. Manufacturers often provide specific instructions on maintenance intervals, lubrication requirements, and other important considerations.
By proactively addressing these common problems and adhering to regular maintenance requirements, pulley performance and service life can be optimized, ensuring smooth and reliable operation in various applications.
Can pulleys be used for both horizontal and vertical lifting?
Yes, pulleys can be used for both horizontal and vertical lifting. The versatility of pulley systems allows them to be utilized in various lifting applications, regardless of the direction of the load. Here’s how pulleys can be used for horizontal and vertical lifting:
1. Horizontal Lifting: In horizontal lifting scenarios, pulleys can be employed to change the direction of the force applied to the load. By using a combination of fixed and movable pulleys, the force can be redirected to pull the load horizontally. This is commonly seen in applications such as manual hoists or block and tackle systems used in construction, where heavy objects need to be moved horizontally across distances.
2. Vertical Lifting: Pulleys are widely used in vertical lifting applications, such as cranes, elevators, and lifting systems. In these setups, the pulleys are typically arranged in such a way that the load can be lifted vertically. By using multiple pulleys and ropes or cables, mechanical advantage can be achieved, making lifting heavier loads easier. The pulleys distribute the load’s weight across multiple lines, reducing the effort required to lift the load.
It’s worth noting that the number and arrangement of pulleys can vary depending on the specific lifting requirements. For example, a single fixed pulley can change the direction of the force but does not provide any mechanical advantage. On the other hand, systems with multiple pulleys, such as compound pulley systems or block and tackle setups, can provide significant mechanical advantage, making lifting heavier loads more manageable.
Whether it is horizontal or vertical lifting, the principles of pulley mechanics remain the same. Pulleys allow for force redirection, mechanical advantage, and load distribution, making lifting tasks more efficient and manageable. The specific configuration and setup of the pulley system will depend on the lifting requirements and the desired level of mechanical advantage.
What are the advantages of using pulleys for mechanical advantage?
Using pulleys for mechanical advantage offers several advantages in various applications. Here are the key advantages:
1. Increased Lifting Capacity: One of the primary advantages of using pulleys for mechanical advantage is that they allow for the lifting of heavier loads with less effort. By distributing the load over multiple segments of rope or belt, pulleys reduce the amount of force required to lift the load. This is especially beneficial in scenarios where manual lifting or limited power is involved.
2. Easier Load Manipulation: Pulleys make it easier to manipulate and control heavy loads. The mechanical advantage provided by pulleys reduces the force needed to move or lift the load, allowing operators to exert less effort. This makes tasks such as lifting, lowering, and positioning heavy objects more manageable and less physically demanding.
3. Safety and Injury Prevention: By reducing the amount of force required to lift heavy loads, pulleys contribute to improved safety and injury prevention. When operators have to exert less physical effort, the risk of strains, sprains, and other lifting-related injuries is significantly reduced. Pulleys enable controlled and smoother load movement, minimizing the risk of sudden shifts or drops that could cause accidents.
4. Precise Load Positioning: Pulley systems provide precise control over load positioning. By using multiple pulleys and adjusting the tension in the rope or belt, operators can achieve precise vertical and horizontal movements of the load. This level of control is particularly valuable in applications that require accurate placement of heavy objects, such as construction, manufacturing, and material handling.
5. Versatility and Adaptability: Pulleys offer versatility and adaptability in various applications. They can be configured in different arrangements and combinations to achieve specific mechanical advantages based on the requirements of the task or load. Pulleys can be easily integrated into existing systems or incorporated into custom-designed setups, making them highly adaptable to different situations.
6. Efficient Power Transmission: Pulleys provide efficient power transmission in mechanical systems. They enable the transfer of rotational motion and force from one component to another with minimal energy loss. The use of pulleys allows for the optimization of power transmission, ensuring effective utilization of available power sources.
7. Cost-Effectiveness: Using pulleys for mechanical advantage can be cost-effective compared to alternative methods. Pulleys are relatively simple and economical devices that can be readily obtained. They require minimal maintenance and have a long operational lifespan. Additionally, pulley systems can often be designed and implemented without the need for complex and expensive equipment.
In conclusion, using pulleys for mechanical advantage offers advantages such as increased lifting capacity, easier load manipulation, safety and injury prevention, precise load positioning, versatility, efficient power transmission, and cost-effectiveness. These advantages make pulleys a valuable tool in a wide range of industries and applications.
editor by CX
2023-09-26