What is the capacity of the Great Wall Pao DEF tank?

Here are the reasons for a strong gasoline smell in the car: 1. Under conditions of very low external temperatures, when the water temperature and exhaust pipe temperature are low, combined with the cold start of the engine during winter driving, the mixture tends to be richer. As a result, some of the mixture cannot fully combust and is directly expelled through the exhaust pipe, leading to a noticeable gasoline smell. This is a normal phenomenon. 2. It may be due to issues with the carbon canister or the carbon canister solenoid valve, causing an overly rich mixture during startup. 3. If the local temperature is low and there is excessive carbon buildup inside the engine, the mixture may not atomize properly, also leading to this phenomenon. 4. If the solenoid valve remains closed, gasoline vapor in the carbon canister will accumulate and eventually fill the entire canister. The excess vapor will then escape into the atmosphere, resulting in a gasoline smell. 5. A leaking fuel injector can cause an overly rich mixture, and the unburned mixture will be expelled through the exhaust pipe, leading to a strong gasoline smell.

No need to charge. The "electricity" in hybrid technology does not come from external charging facilities. Hybrid vehicles simply do not have charging devices. Relevant details are as follows: 1. The hybrid system means that when the vehicle does not require high power from the engine, part of the engine's power is used to generate electricity and stored in the battery. Additionally, the kinetic energy reduced during vehicle deceleration and braking is converted into electrical energy and stored in the battery, a process known as "regenerative braking." This is the source of the "electricity" in hybrid dual-power technology. 2. The electrical energy stored in the battery is fully utilized as driving force during vehicle operation, reducing fuel consumption while enhancing power. The "electricity" circulates within the hybrid dual-power system, enabling hybrid vehicles to have "electricity" available without the need for charging.

Performance-oriented CVT transmissions worldwide tend to adopt the chain solution. The structural differences between chains and steel belts are as follows: 1. A CVT steel belt is based on two embedded steel belts as foundational support, with hundreds of steel plates clamped onto the metal belt. This push-plate structure can only transmit power by "pushing," utilizing the hardness of the material between the push plates to form thrust. Under external force, the push plates compress, and during power transmission, the driving pulley tightly presses against the entire side of the steel belt to create static friction, thereby pushing the driven pulley to rotate via the steel belt. 2. The CVT chain differs significantly in structure from the steel belt. The chain does not directly contact the pulley but transmits torque by compressing the intermediate rocker pins. Structurally, the chain consists of two bundles of annular steel plates and tension plates, with each bundle composed of 12 layers of high-tensile thin steel plates stacked together. Patented T702 high-strength steel is inserted between each group of steel plates to form rocker pins for connection, achieving a tensile strength of up to 2000 MPa. This chain structure can only transmit power by "pulling." The driving pulley compresses the chain's "rocker pins" to generate static friction, driving the chain to transmit torque.

Reasons for excessive vehicle exhaust emissions: 1. Abnormal engine operation: The engine may experience issues such as misfiring, spark plug oil leakage, or oil mixing. When accelerating, the engine runs unevenly and lacks power. 2. Dirty vehicle systems: This usually occurs in relatively new vehicles, but the test results show excessive emissions, or the excess is minor (only a few percent or fractions of a percent). This indicates that the vehicle's exhaust treatment system (including the catalytic converter and oxygen sensor) is not significantly faulty. The cause of excessive emissions may be due to the three major systems (intake system, exhaust system, and fuel system) being too dirty. 3. Catalytic converter failure: A faulty catalytic converter is the primary reason for excessive vehicle exhaust emissions. The catalytic converter is the most important external purification device installed in the vehicle's exhaust system. It converts harmful gases such as CO, HC, and NOx from vehicle exhaust into harmless carbon dioxide, water, and nitrogen through oxidation and reduction. 4. Oxygen sensor damage: In engines using catalytic converters to reduce exhaust pollution, the oxygen sensor is an essential component. It detects the oxygen concentration in the exhaust and sends feedback signals to the ECU, which controls the fuel injector to adjust the fuel injection volume. This keeps the air-fuel ratio of the mixture near the theoretical value, ensuring more complete fuel combustion. 5. Vehicle aging: If the vehicle has traveled over 450,000 kilometers or is more than 15 years old, various components may show significant aging, poor contact, inadequate sealing, or insufficient pressure.

When shifting gears in a car, the accelerator needs to be released. Detailed instructions on releasing the accelerator when shifting gears are as follows: 1. When upshifting, release the accelerator, depress the clutch, shift up, release the clutch, and press the accelerator. When downshifting, release the accelerator, depress the clutch, lightly apply the brakes, shift down, and release the clutch. Apply throttle as needed. Generally, the accelerator should be released when shifting gears. Operating a manual transmission car without releasing the accelerator during gear shifts is challenging. 2. When downshifting, release the accelerator and lightly apply the brakes to control the speed within the range suitable for the target gear, depress the clutch, engage the corresponding gear, and then slowly release the clutch. Downshifting is a deceleration process, but it doesn't mean completely ignoring the accelerator pedal. After completing the shift and fully releasing the clutch pedal, the accelerator pedal should be pressed immediately to achieve smooth power transition. 3. It is possible to shift gears while pressing the accelerator pedal, but this will lead to excessive wear of the clutch plates.

Replacing shock absorbers does not necessarily require replacing the springs. If the car shakes severely, it is usually not related to the springs, as springs primarily serve a cushioning function. A faulty shock absorber can affect the car's balance, but replacing them in pairs (left and right) will not cause issues. Unusual noises are typically due to aging or wear of the shock absorber buffer rubber. Below is more information about shock absorbers: 1. Shock absorbers are not designed to support the vehicle's weight but to dampen the oscillations after the springs absorb shocks and to absorb energy from road impacts. In a car with faulty shock absorbers, the vehicle will continue to bounce after passing over bumps or uneven surfaces, and the shock absorbers are meant to control this bouncing. 2. Without shock absorbers, the rebound of the springs cannot be controlled, leading to severe bouncing when driving on rough roads. During turns, the up-and-down motion of the springs can also cause loss of tire grip and traction. The ideal scenario is to use shock absorbers to limit the spring's rebound to a single cycle.