Product Description
MIC NO | OEM.NO | APPLICATION | YEAR | PHOTO |
TB34RE9703 | 55719 DACIA : 775718117 DACIA : DACIA : 82QAB RENAULT : 775718117 RENAULT : RENAULT : |
DACIA DUSTER (HS_) 1.6 16V DACIA LOGAN (LS_) 1.6 16V (LS09, LS18, LS1S, LS1V,… DACIA LOGAN MCV (KS_) 1.6 16V (KS0L, KS0M, KS0P, KS1S) NISSAN KUBISTAR Box (X76) 1.6 16V RENAULT CLIO II (BB_, CB_) 1.4 16V (B/CB0L) RENAULT CLIO II (BB_, CB_) 1.6 16V (BB01,, BB2KL, BB3G… RENAULT CLIO III (BR0/1, CR0/1) 1.4 16V RENAULT CLIO III Grandtour (KR0/1_) 1.4 16V RENAULT KANGOO (KC0/1_) 1.6 16V RENAULT KANGOO / GRAND KANGOO (KW0/1_) 1.6 16V RENAULT KANGOO BE BOP (KW0/1_) 1.6 (KW0D) RENAULT KANGOO Express (FC0/1_) 1.6 16V RENAULT LAGUNA I (B56_, 556_) 1.6 16V (B568, B561) RENAULT LAGUNA I Grandtour (K56_) 1.6 16V (K568) RENAULT LAGUNA II (BG0/1_) 1.6 16V (BG0A, BG0L) RENAULT LAGUNA II Grandtour (KG0/1_) 1.6 16V (KG0A, KG0L) RENAULT LOGAN I (LS_) 1.6 (LS0L, LS09, LS1S, LS1V, LS1Y,… RENAULT LOGAN I Estate (KS_) 1.6 (KS0L, KS0M, KS0P, KS1S) RENAULT MEGANE I (BA0/1_) 1.4 16V (BA0D, BA1H, BA0W, BA10) RENAULT MEGANE I (BA0/1_) 1.6 16V (BA04, BA1K, BA1V,… RENAULT MEGANE I Cabriolet (EA0/1_) 1.4 16V (EA0D, EA1H, EA0W, EA10) RENAULT MEGANE I Cabriolet (EA0/1_) 1.6 16V (EA04, EA0B, EA11, EA1J) RENAULT MEGANE I Classic (LA0/1_) 1.4 16V (LA0D, LA1H, lA0W, LA10) RENAULT MEGANE I Classic (LA0/1_) 1.6 16V (LA00, LA1J, LA1K,… RENAULT MEGANE I Coach (DA0/1_) 1.4 16V (DA0D, DA1H, DA0W, DA10) RENAULT MEGANE I Coach (DA0/1_) 1.6 16V (DA0B, DA04, DA11) RENAULT MEGANE I Grandtour (KA0/1_) 1.4 16V (KA0D, KA1H, KA0W, KA10) RENAULT MEGANE I Grandtour (KA0/1_) 1.6 16V (KA0B, KA04, KA11) RENAULT MEGANE II (BM0/1_, CM0/1_) 1.4 16V RENAULT MEGANE II (BM0/1_, CM0/1_) 1.6 RENAULT MEGANE II Estate (KM0/1_) 1.4 RENAULT MEGANE II Estate (KM0/1_) 1.6 16V Hi-Flex RENAULT MEGANE II Saloon (LM0/1_) 1.4 RENAULT MEGANE II Saloon (LM0/1_) 1.6 RENAULT MEGANE III Coupe (DZ0/1_) 1.6 16V (DZ0H) RENAULT MEGANE III Hatchback (BZ0/1_, B3_) 1.6 16V (BZ0H) RENAULT MEGANE Scenic (JA0/1_) 1.6 16V (JA0B, JA04, JA11) RENAULT MODUS / GRAND MODUS (F/JP0_) 1.4 (JP01, JP0J) RENAULT SCÉNIC I MPV (JA0/1_, FA0_) 1.4 16V (JA0D, JA1H, Ja0W, JA10) RENAULT SCÉNIC I MPV (JA0/1_, FA0_) 1.6 RENAULT SCÉNIC II (JM0/1_) 1.4 (JM0B, JM0H, JM1A) RENAULT THALIA I (LB_) 1.4 16V |
2571-2018 2006- 2007- 2003- 1999-2004 1998- 2005- 2571- 2001- 2008- 2009- 2001- 1997-2001 1997-2001 2001-2005 2001-2007 2007- 2007- 1999-2003 1999-2002 1999-2003 1999-2003 1999-2003 1999-2003 1999-2003 1999-2003 1999-2003 1999-2003 2003-2008 2005-2008 2003-2009 2008-2009 2003- 2005- 2008- 2008- 1998-1999 2004- 1999-2003 2001-2003 2003-2008 2000- |
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Can you provide guidance on selecting and sizing V-belt tensioners for specific V-belt applications?
When selecting and sizing V-belt tensioners for specific V-belt applications, several factors need to be considered to ensure optimal performance and compatibility. Here’s a detailed guidance on selecting and sizing V-belt tensioners:
- Understand the Application Requirements:
- Determine the Tensioner Type:
- Calculate the Tensioning Force:
- Consider Belt Length and Width:
- Check Mounting Configurations:
- Consider Environmental Factors:
- Consult Manufacturer Guidelines and Specifications:
Begin by understanding the specific requirements of the V-belt application. Consider factors such as the power transmission requirements, operating conditions (including speed and temperature), space limitations, and any unique environmental considerations. This understanding will help determine the appropriate tensioner design and features needed for the application.
Based on the application requirements, choose the appropriate type of tensioner. Common types include spring-loaded tensioners, hydraulic tensioners, or automatic tensioners with adaptive tension control. Each type has its advantages and is suitable for different applications. Consider factors such as the desired tensioning force, adjustability, and the level of automation required.
Calculate the required tensioning force for the V-belt system. This depends on factors such as the power transmitted, the number of belts, the wrap angle around the pulleys, and the coefficient of friction between the belt and pulleys. Use the appropriate equations or online calculators to determine the tensioning force needed to prevent belt slippage and ensure proper power transmission.
Take into account the length and width of the V-belt when selecting a tensioner. Ensure that the tensioner is compatible with the belt’s dimensions. Consider the range of adjustability provided by the tensioner to accommodate variations in belt length due to wear or elongation over time. Also, verify that the tensioner can handle the width of the V-belt without any interference or misalignment issues.
Check the available mounting configurations in your application. Assess the space constraints, the position of the tensioner relative to the pulleys, and the method of tensioner attachment (e.g., bolt-on, weld-on, or stud-mounted). Ensure that the selected tensioner can be properly mounted and aligned in the available space without interfering with other system components.
Consider any environmental factors that may affect the performance and durability of the tensioner. For example, if the application is exposed to high temperatures, corrosive substances, or harsh operating conditions, choose a tensioner with appropriate materials, coatings, or seals to withstand these conditions and ensure long-term reliability.
Refer to the manufacturer’s guidelines, specifications, and technical documentation for the tensioner. Manufacturers often provide detailed information about the tensioner’s capabilities, compatibility, installation procedures, and maintenance requirements. Follow their recommendations to ensure proper selection, sizing, and installation of the tensioner for the specific V-belt application.
By considering these factors and following the guidance above, you can select and size the appropriate V-belt tensioner for your specific V-belt application. Proper selection and sizing will ensure optimal performance, longevity, and reliability of the V-belt system.
What is the impact of proper tensioning on the lifespan and reliability of V-belts?
Proper tensioning is crucial for the lifespan and reliability of V-belts. The correct tension ensures optimal power transmission, minimizes belt wear, and reduces the risk of belt failure. Here’s a detailed explanation of the impact of proper tensioning on V-belts:
- Prevents Slippage:
- Reduces Wear:
- Optimizes Power Transmission:
- Minimizes Belt Stretch:
- Enhances Belt Lifespan:
- Improves System Reliability:
Proper tensioning prevents belt slippage, which can occur when the tension is too loose. Slippage leads to inefficient power transmission, reduced belt lifespan, and poor performance of the driven components. By maintaining the appropriate tension, V-belt tensioners prevent slippage and ensure efficient power transfer.
When V-belts are under-tensioned or over-tensioned, excessive wear occurs. Under-tensioning can cause belt slapping, increased flexing, and accelerated wear on the belt’s sidewalls. Over-tensioning can lead to excessive stress on the belt, resulting in premature wear, cracking, and potential belt failure. Proper tensioning helps distribute the load evenly across the belt, reducing wear and extending its lifespan.
Proper tensioning ensures optimal power transmission between the driving and driven components. When V-belts are correctly tensioned, the belts effectively grip the pulleys, enabling efficient transfer of rotational force. This maximizes power transfer efficiency, minimizes energy losses, and improves the overall performance of the system.
V-belts naturally undergo some stretch during operation due to the forces and tension they experience. However, excessive belt stretch can lead to reduced tension and compromised power transmission. Proper tensioning helps minimize belt stretch, maintaining the desired tension level and preventing loss of power and belt misalignment.
By maintaining the proper tension, V-belt tensioners contribute to extending the lifespan of V-belts. Proper tensioning reduces wear, prevents slippage, and minimizes stress on the belts, thereby reducing the risk of belt failure. V-belts that are correctly tensioned are more likely to operate reliably over a longer period, reducing the need for frequent replacements and associated downtime.
Proper tensioning of V-belts improves the overall reliability of the system in which they are used. Reliable power transmission ensures consistent performance of the driven components, reducing the likelihood of unexpected breakdowns or malfunctions. This is particularly crucial in applications where system downtime can have significant financial or operational consequences.
In summary, proper tensioning plays a vital role in the lifespan and reliability of V-belts. It prevents slippage, reduces wear, optimizes power transmission, minimizes belt stretch, enhances belt lifespan, and improves system reliability. By ensuring the correct tension, V-belt tensioners contribute to efficient and reliable operation, reducing maintenance requirements and maximizing the longevity of V-belts in various applications.
Can you explain the significance of proper tensioning in V-belt-driven machinery and equipment?
Proper tensioning plays a crucial role in V-belt-driven machinery and equipment. It is essential for ensuring optimal performance, efficient power transmission, and extended component life. Here’s a detailed explanation of the significance of proper tensioning in V-belt-driven systems:
- Effective Power Transmission:
- Prevention of Slippage:
- Extended Component Life:
- Reduced Maintenance Requirements:
- Optimized System Performance:
- Enhanced Safety:
Proper tensioning is vital for effective power transmission in V-belt-driven machinery and equipment. The tension applied to the V-belt ensures that it remains tightly engaged with the pulleys, creating frictional forces necessary for transferring power. Insufficient tension can result in slippage between the belt and the pulleys, leading to power loss, reduced efficiency, and compromised performance. By maintaining the correct tension, V-belt-driven systems can achieve efficient power transmission, ensuring that the machinery operates at its intended power output.
One of the primary functions of proper tensioning is to prevent slippage between the V-belt and the pulleys. Slippage occurs when the belt loses traction with the pulleys, leading to inefficient power transmission and reduced performance. Proper tensioning ensures that the V-belt remains securely engaged with the pulleys, minimizing the risk of slippage even under varying loads or during sudden changes in speed or torque. By preventing slippage, proper tensioning helps maintain reliable power delivery, consistent operation, and accurate timing in timing belt applications.
Proper tensioning significantly contributes to the extended life of V-belts and other components in V-belt-driven machinery. When the tension is too loose, the V-belt can experience excessive flexing, leading to premature wear, fatigue, and ultimately, failure. On the other hand, excessive tension can cause increased stress on the V-belt and the pulleys, leading to accelerated wear and potential damage. By maintaining the correct tension, V-belts experience optimal operating conditions, reduced wear, and prolonged lifespan. Proper tensioning also helps minimize stress on other components, such as bearings, shafts, and pulleys, further extending their service life.
Proper tensioning in V-belt-driven machinery can help reduce maintenance requirements. Inadequate tension or slippage can lead to various issues that require frequent maintenance, adjustments, or component replacements. These issues may include belt misalignment, premature wear, increased heat generation, or even system failures. By maintaining the correct tension, V-belt systems operate within their designed parameters, minimizing the occurrence of these problems. Reduced maintenance needs not only save time and effort but also contribute to lower maintenance costs and increased productivity.
Proper tensioning is essential for achieving optimized system performance in V-belt-driven machinery and equipment. When the V-belt is appropriately tensioned, it operates efficiently, minimizing energy losses and maximizing power transmission. This, in turn, leads to improved overall system performance, higher productivity, and reduced operating costs. Proper tensioning ensures that the machinery operates at its intended power levels, maintains accurate timing, and delivers consistent performance, resulting in reliable and efficient operation.
Proper tensioning also contributes to enhanced safety in V-belt-driven machinery and equipment. Slippage or inadequate tension can lead to sudden belt failures, unexpected power losses, or even accidents. By maintaining the correct tension, the risk of such incidents is significantly reduced. Properly tensioned V-belts ensure reliable power transmission, minimizing the potential for unexpected equipment malfunctions or sudden stops. This enhances operator safety and helps prevent damage to the machinery or surrounding equipment.
In summary, proper tensioning is of utmost importance in V-belt-driven machinery and equipment. It ensures effective power transmission, prevents slippage, extends component life, reduces maintenance requirements, optimizes system performance, and enhances safety. By maintaining the correct tension, V-belt-driven systems operate efficiently, reliably, and safely, contributing to increased productivity, reduced downtime, and improved overall operational performance.
editor by CX 2024-05-14