Product Description
| Model | CA6DM2-35E5 | CA6DM2-37E5 | CA6DM2-39E5 | CA6DM2-42E5 | Model | CA6DL2-29E5 | CA6DL2-31E5 | CA6DL2-33E5 | CA6DL2-35E5 | CA6DL2-37E5 | Model | CA6DL1-26E5 | CA6DL1-28E5 | CA6DL1-29E5 | CA6DL1-32E5 | Model | CA6DLD-18E5 | CA6DLD-20E5 | CA6DLD-22E5 | CA6DLD-24E5 | CA6DLD-26E5 |
| Type | 6-cylinder in-line, direct injection, turbocharged&intercooling, common rail | Type | 4-cylinder in-line, direct injection, turbocharged&intercooling, common rail | Type | 6-cylinder in-line, direct injection, turbocharged&intercooling, common rail | Type | 6-cylinder in-line, direct injection, turbocharged&intercooling, common rail | ||||||||||||||
| Bore×Stroke (mm) | 123×155 | Bore×Stroke (mm) | 112×145 | Bore×Stroke (mm) | 110×135 | Bore×Stroke (mm) | 108×120 | ||||||||||||||
| Valves/cylinder | 4 | Valves/cylinder | 4 | Valves/cylinder | 4 | Valves/cylinder | 4 | ||||||||||||||
| Displacement (L) | 11.04 | Displacement (L) | 8.6 | Displacement (L) | 7.7 | Displacement (L) | 6.6 | ||||||||||||||
| Rated power (kW) | 261 | 279 | 290 | 312 | Rated power (kW) | 218 | 231 | 249 | 261 | 279 | Rated power (kW) | 195 | 209 | 216 | 238 | Rated power (kW) | 134 | 149 | 164 | 179 | 194 |
| Net power (kW) | 258 | 276 | 287 | 309 | Net power (kW) | 215 | 228 | 246 | 258 | 276 | Net power (kW) | 192 | 206 | 213 | 235 | Net power (kW) | 132 | 147 | 162 | 177 | 192 |
| Rated speed (r/min) | 1900 | Rated speed (r/min) | 2100 | Rated speed (r/min) | 2300 | Rated speed (r/min) | 2300 | ||||||||||||||
| Maximum torque/speed | 1600 | 1650 | 1750 | 1900 | Maximum torque (Nm) | 1250 | 1250 | 1350 | 1500 | 1550 | Maximum torque (Nm) | 1050 | 1100 | 1150 | 1250 | Maximum torque (Nm) | 680 | 780 | 860 | 940 | 1050 |
| (Nm/r/min) | 1100~1400 | 1100~1400 | 1100~1400 | 1100~1400 | Maximum torque speed (r/min) | 1300~1500 | Maximum torque speed (r/min) | 1300~1700 | Maximum torque speed (r/min) | 1300-1700 | |||||||||||
| Fuel consumption (g/kW·h) | 190 | Fuel consumption (g/kW·h) | 192 | Fuel consumption (g/kW·h) | 192 | Fuel consumption (g/kW·h) | 196 | ||||||||||||||
| Noise dB (A) | ≤ 94.6 | Noise dB (A) | ≤ 94 | Noise dB (A) | ≤ 95.5 | Noise dB (A) | ≤ 96 | ||||||||||||||
| Technical Route | SCR | Technical Route | SCR | Technical Route | SCR | Technical Route | SCR | ||||||||||||||
| Emission Compliant (TAS) | EURO V | Emission Compliant (TAS) | EURO V | Emission Compliant (TAS) | EURO V | Emission Compliant (TAS) | EURO V | ||||||||||||||
| Net Mass (kg) | 1050 | Net Mass (kg) | 870 | Net Mass (kg) | 820 | Net Mass (kg) | 740 | ||||||||||||||
| Length×Width×Height (mm) | 1365×775×1180 | Length×Width×Height (mm) | 1308×778×996 | Length×Width×Height (mm) | 1308×778×976 | Length×Width×Height (mm) | 992×720×955 | ||||||||||||||
| Model | CA4DLD-13E5 | CA4DLD-15E5 | CA4DLD-17E5 | CA4DLDZ-18E5 | Model | CA6SM2-31E4N gas engine for sale | CA6SM2-33E4N gas engine for sale | CA6SM2-35E4N gas engine for sale | CA6SM2-37E4N gas engine for sale | Model | CA6SM2-31E5N gas engine for sale | CA6SM2-33E5N gas engine for sale | CA6SM2-35E5N gas engine for sale | CA6SM2-37E5N gas engine for sale | Model | CA6DM2-35E4 | CA6DM2-37E4 | CA6DM2-39E4 | CA6DM2-42E4 | ||
| Type | 4-cylinder in-line, direct injection, turbocharged&intercooling, common rail | Type | 6 cylinders, in-line, director injection, turbocharged inter-cooling, electric-controlled system(closed loop control) | Type | 6 cylinders, in-line, director injection, turbocharged inter-cooling, electric-controlled system(closed loop control) | Type | 6-cylinder in-line, direct injection, turbocharged&intercooling, common rail | ||||||||||||||
| Bore×Stroke(mm) | 108×120 | Bore×Stroke(mm) | 123×155 | Bore×Stroke(mm) | 123×155 | Bore×Stroke (mm) | 123×155 | ||||||||||||||
| Valves/cylinder | 4 | Valves/cylinder | 4 | Valves/cylinder | 4 | Valves/cylinder | 4 | ||||||||||||||
| Displacement (L) | 4.4 | Displacement (L) | 11.04 | Displacement (L) | 11.04 | Displacement (L) | 11.04 | ||||||||||||||
| Rated power/rated speed (kW/r/min) | 98/2500 | 105/2500 | 112/2500 | 127/2500 | Rated power(kW) | 231 | 245 | 261 | 278 | Rated power(kW) | 231 | 246 | 261 | 278 | Rated power (kW) | 261 | 279 | 290 | 312 | ||
| Net power/speed (kW/r/min) | 96/2500 | 103/2500 | 110/2500 | 125/2500 | Net power(kW) | 228 | 242 | 258 | 275 | Net power(kW) | 228 | 243 | 258 | 275 | Net power (kW) | 258 | 276 | 287 | 309 | ||
| Maximum torque (Nm) | 450 | 450 | 530 | 600 | Rated speed (r/min) | 1900 | Rated speed (r/min) | 1900 | Rated speed (r/min) | 1900 | |||||||||||
| Maximum torque speed(r/min) | 1300~1700 | Maximum torque (Nm) | 1450 | 1500 | 1550 | 1650 | Maximum torque (Nm) | 1450 | 1500 | 1550 | 1650/1300 | Maximum torque (Nm) | 1600 | 1650 | 1750 | 1900 | |||||
| Fuel consumption(g/kW·h) | 200 | Maximum torque speed (r/min) | 1100~1500 | 1100~1400 | Maximum torque speed (r/min) | 1100~1500 | 1100~1400 | Maximum torque speed (r/min) | 1100~1400 | 1100~1400 | 1100~1400 | 1100~1400 | |||||||||
| Noise dB(A) | ≤94 | Min. gas consumption at full load (g/kW.h) | 195 | Min. gas consumption at full load (g/kW. h ) | 195 | Fuel consumption (g/kW·h) | 190 | ||||||||||||||
| Technical Route | SCR/ EGR+VNT/FGT+POC | Noise dB(A) | ≤96 | Noise dB(A) | ≤96 | Noise dB (A) | ≤ 94.6 | ||||||||||||||
| Emission Compliant (TAS) | EURO V | Emission Compliant(TAS) | EURO IV | Emission Compliant(TAS) | EURO V | Technical Route | SCR | ||||||||||||||
| Net Mass(kg) | 560 | Net Mass (kg) | 1050 | Net Mass (kg) | 1050 | Emission Compliant (TAS) | EURO | ||||||||||||||
| Length×Width×Height(mm) | 992×780×960 | Length×Width×Height(mm) | 1365×775×1180 | Length×Width×Height(mm) | 1365×775×1180 | Net Mass (kg) | 1050 | ||||||||||||||
| Length×Width×Height (mm) | 1365×775×1180 | ||||||||||||||||||||
FAQ:
Q1. What is your terms of packing?
A: Generally, we pack our goods in Carton boxes and then in wooden case.
Q2. What is your terms of payment?
A: T/T 30% as deposit, and 70% before delivery. We’ll show you the photos of the products and packages
before you pay the balance.
Q3. What is your terms of delivery?
A: EXW, FOB, CPT, CIF.
Q4. How about your delivery time?
A: Generally, it will take 7 to 30 days after receiving your advance payment. The specific delivery time depends
on the items and the quantity of your order.
Q5. Can you produce according to the samples?
A: Yes, we can produce by your samples or technical drawings. We can build the molds and fixtures.
Q6. What is your sample policy?
A: We can supply the sample if we have ready parts in stock, but the customers have to pay the sample cost and
the courier cost.
Q7. Do you test all your goods before delivery?
A: Yes, we have 100% test before delivery
Q8: How do you make our business long-term and good relationship?
A:1. We keep good quality and competitive price to ensure our customers benefit ;
2. We respect every customer as our friend and we sincerely do business and make friends with them, no matter where they come from.
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| After-sales Service: | 3 Months Warranty |
|---|---|
| Condition: | New |
| Color: | Black |
| Material: | Alloy |
| Transport Package: | Carton Packaging or Wooden Box Packaging |
| Specification: | Conform to the STD size of the original factory |
| Samples: |
US$ 56.69/Piece
1 Piece(Min.Order) | |
|---|
| Customization: |
Available
| Customized Request |
|---|
How do axle shafts enhance the overall performance and drivability of vehicles?
Axle shafts play a crucial role in enhancing the overall performance and drivability of vehicles. These components are integral to the drivetrain system and are responsible for transferring power from the differential to the wheels. Here’s a detailed explanation of how axle shafts contribute to improved performance and drivability:
- Power Transmission: Axle shafts are responsible for transmitting power from the differential to the drive wheels. By efficiently transferring torque, axle shafts allow the wheels to rotate and generate forward motion. The proper functioning of axle shafts ensures that power is effectively delivered to the wheels, enabling acceleration, towing capability, and overall propulsion.
- Traction and Stability: Axle shafts, particularly in vehicles equipped with differential systems, play a crucial role in optimizing traction and stability. Differential systems allow for power distribution between the wheels, adjusting torque delivery based on wheel slip conditions. This helps to improve traction on various surfaces, such as slippery roads or uneven terrains. By ensuring better grip and stability, axle shafts contribute to safer and more confident driving experiences.
- Handling and Cornering: Axle shafts influence the handling and cornering characteristics of a vehicle. By transmitting power to the drive wheels, axle shafts enable precise control and responsiveness during steering inputs. Well-designed axle shafts with appropriate strength and flexibility properties contribute to predictable and stable handling, allowing drivers to navigate corners smoothly and maintain control over the vehicle.
- Load-Bearing Capacity: Axle shafts are subjected to significant loads, especially in vehicles that carry heavy loads or tow trailers. Robust axle shafts with adequate load-bearing capacity ensure that the vehicle can handle the weight without experiencing excessive deflection or failure. By providing sufficient strength and durability, axle shafts contribute to the safe and efficient transport of passengers and cargo.
- Efficiency and Fuel Economy: The weight and design of axle shafts can impact the overall efficiency and fuel economy of a vehicle. Lighter axle shafts, such as those made from advanced materials like aluminum or composites, can reduce the unsprung weight of the vehicle. This helps improve suspension response, reduce energy losses, and enhance fuel efficiency. Additionally, optimized designs and reduced friction in axle shafts contribute to more efficient power transmission, maximizing the energy utilization of the drivetrain system.
- Durability and Reliability: Axle shafts are subjected to various stresses and operating conditions, including high torque, vibrations, and impacts. High-quality axle shafts constructed from durable materials, engineered with appropriate geometries, and manufactured using advanced techniques offer enhanced durability and reliability. Reliable axle shafts minimize the risk of failures or breakdowns, contributing to the overall dependability of the vehicle.
In summary, axle shafts enhance the overall performance and drivability of vehicles through efficient power transmission, improved traction and stability, enhanced handling and cornering, adequate load-bearing capacity, increased efficiency and fuel economy, and enhanced durability and reliability. These components play a critical role in ensuring optimal power delivery, control, and safety, ultimately enhancing the driving experience and satisfaction of vehicle owners.
How do axle shafts contribute to a vehicle’s stability and handling?
Axle shafts play a crucial role in contributing to a vehicle’s stability and handling characteristics. They are integral components of the suspension and drivetrain systems, affecting how the vehicle distributes power, maintains traction, and responds to steering inputs. Here’s a detailed explanation of how axle shafts contribute to a vehicle’s stability and handling:
- Power Distribution: Axle shafts transmit power from the drivetrain to the wheels, allowing the vehicle to move forward or backward. The distribution of power between the wheels is essential for maintaining stability and preventing wheel slippage. By transferring torque evenly to the wheels, axle shafts help optimize traction and prevent excessive power loss, ensuring that the vehicle stays stable and controlled during acceleration or deceleration.
- Traction Control: Axle shafts, particularly those equipped with differential mechanisms, help maintain traction by allowing the wheels to rotate at different speeds when necessary. This feature is especially important during turns or when driving on uneven surfaces. The differential compensates for differences in wheel rotation, enabling the vehicle to maintain stability and grip by preventing wheel spin or loss of control.
- Suspension Geometry: Axle shafts are integrated into the suspension system, connecting the wheels to the differential or transaxle. The positioning and design of axle shafts influence the suspension geometry, including factors like camber, caster, and toe. Proper suspension geometry is crucial for stability, predictable handling, and optimal tire contact with the road surface. Well-engineered axle shafts ensure that the suspension components work harmoniously to maintain stability and enhance handling characteristics.
- Steering Response: In vehicles with front-wheel drive or all-wheel drive configurations, axle shafts are responsible for transmitting power to the front wheels while also allowing for steering inputs. This design affects the vehicle’s steering response and handling. High-quality axle shafts with minimal play or backlash contribute to precise steering control, allowing the driver to make accurate and predictable maneuvers. Axle shafts that provide a direct and responsive connection between the drivetrain and front wheels enhance the overall handling and stability of the vehicle.
- Weight Distribution: The weight distribution of a vehicle affects its stability and handling characteristics. Axle shafts, particularly those in rear-wheel drive vehicles, support the weight of the vehicle’s rear end. By properly distributing the weight across the axles, axle shafts help maintain a balanced and stable platform. This balanced weight distribution enhances the vehicle’s overall stability and allows for better handling during cornering, reducing the risk of oversteer or understeer.
- Impact on Suspension Tuning: Axle shafts can have an impact on the tuning and performance of the suspension system. Upgrading to high-performance axle shafts, such as those made from stronger materials or featuring improved designs, can enhance the overall rigidity and responsiveness of the suspension. This, in turn, improves the vehicle’s stability and handling, allowing for more precise control during aggressive driving or challenging road conditions.
It’s important to note that while axle shafts contribute significantly to a vehicle’s stability and handling, they work in conjunction with other components such as suspension, tires, steering system, and chassis design. The overall performance and characteristics of a vehicle’s stability and handling are the result of a complex interaction between these components.
In summary, axle shafts contribute to a vehicle’s stability and handling by ensuring proper power distribution, maintaining traction control, influencing suspension geometry, providing responsive steering, contributing to balanced weight distribution, and impacting suspension tuning. High-quality axle shafts that are properly engineered and integrated into the vehicle’s systems enhance stability, improve handling characteristics, and allow for a more controlled and enjoyable driving experience.
Are there different axle shaft designs for rear-wheel drive and front-wheel drive vehicles?
Yes, rear-wheel drive (RWD) and front-wheel drive (FWD) vehicles typically employ different axle shaft designs to accommodate their respective drivetrain configurations. The axle shafts in RWD and FWD vehicles differ in their construction, orientation, and connection to the wheels. Here’s a detailed explanation of the axle shaft designs used in RWD and FWD vehicles:
Rear-Wheel Drive (RWD) Vehicles:
In RWD vehicles, the engine’s power is transmitted to the rear wheels through the drivetrain components. The axle shaft design in RWD vehicles is commonly referred to as a solid axle or full-floating axle. Here are the key characteristics of RWD axle shafts:
- Rigid Shaft: RWD axle shafts are typically solid and rigid, connecting the differential directly to each rear wheel. They are designed to handle high torque loads and provide robustness, making them suitable for heavy-duty applications.
- Single Connection: Each rear wheel has its own dedicated axle shaft, which connects directly to the wheel hub. The axle shaft transfers power to the wheel, enabling it to rotate.
- Support and Power Transfer: RWD axle shafts support the weight of the vehicle and transmit torque from the differential to the wheels. They facilitate smooth power delivery and enable the rear wheels to propel the vehicle forward or backward.
- Less Articulation: Since RWD vehicles typically have a solid rear axle, the axle shafts have limited articulation compared to FWD vehicles. This design simplifies the construction but may result in reduced suspension flexibility and a harsher ride quality.
Front-Wheel Drive (FWD) Vehicles:
In FWD vehicles, the engine’s power is transmitted to the front wheels through the drivetrain components. FWD axle shafts are commonly known as half shafts or CV axles (constant velocity axles). Here are the main characteristics of FWD axle shafts:
- Compact and Lightweight: FWD axle shafts are typically lighter and more compact than RWD axle shafts. They are designed to accommodate the space limitations in the front-wheel-drive layout.
- Constant Velocity (CV) Joints: FWD axle shafts incorporate constant velocity (CV) joints, which allow for flexibility and rotation at various angles. CV joints compensate for the changing length and angle of the axle shafts during suspension movement and steering.
- Transverse Orientation: FWD axle shafts are positioned transversely across the vehicle, connecting the differential or transaxle to the front wheels. This orientation allows for efficient power transfer and space utilization in FWD vehicles.
- Support and Power Transfer: FWD axle shafts support the weight of the vehicle and transmit torque from the differential or transaxle to the front wheels. They enable the front wheels to rotate and provide the driving force for vehicle movement.
- Increased Articulation: FWD axle shafts have greater articulation capabilities due to the need to accommodate suspension movement and steering angles. The CV joints allow the axle shafts to flex and rotate, ensuring smooth power delivery even when the wheels are turned or the suspension is compressed.
These axle shaft designs in RWD and FWD vehicles are tailored to the specific requirements and configurations of each drivetrain layout. They optimize power transmission, support the wheels, and ensure efficient operation based on the unique characteristics of rear-wheel drive and front-wheel drive systems.
editor by CX 2024-02-06