Is it normal for an ordinary car to consume 30 liters of fuel per 100 kilometers?

Water may enter if it reaches just below the door edge. Theoretically, as long as the water does not submerge the air intake, it will not affect the engine. However, there are too many unpredictable factors, such as water splashing into the air intake when vehicles pass by. Additionally, you must drive slowly and be aware of the underwater environment, as the surface may appear calm but the underwater conditions are unknown. If the engine stalls while wading through water, do not attempt to restart it. You can use the following three height references to help assess the situation: 1. Exhaust pipe height: Safe wading height. During actual driving, as long as the engine does not stall, the exhaust pipe continuously emits exhaust gases, which prevent water from entering the pipe. Therefore, the main concern during wading is not the exhaust pipe but the air intake. 2. Half-wheel height or above: May cause water to enter the vehicle. Modern cars are equipped with various electronic components and sensors, and if the water level exceeds half the wheel height, water may seep in. 3. Air intake height: Maximum wading height. The air intake height is the most critical indicator for vehicle wading depth because once water enters the air intake, it can cause the engine to stall. In severe cases, water can be sucked into the engine, leading to permanent damage. Therefore, if the water reaches this level, you must not continue driving.

The BAIC Senova X35 is equipped with an engine independently developed and produced by the BAIC Group, making it a domestically manufactured engine. The engine model of the BAIC Senova X35 is G4LD, with a maximum power of 103 kW, maximum torque of 242 Nm, maximum horsepower of 118 Ps, maximum power speed of 6000 rpm, and maximum torque speed of 1500-3200 rpm. For the daily maintenance of the BAIC Senova X35's engine, the following methods can be used: Use lubricating oil of the appropriate quality grade. For gasoline engines, SD--SF grade gasoline engine oil should be selected based on the additional devices of the intake and exhaust systems and usage conditions; for diesel engines, CB--CD grade diesel engine oil should be selected according to mechanical load, with the selection standard not lower than the manufacturer's specified requirements. Regularly change the engine oil and filter. The quality of any grade of lubricating oil will change during use. After a certain mileage, its performance deteriorates, causing various problems for the engine. To avoid failures, change the oil regularly according to usage conditions and keep the oil level moderate. When oil passes through the fine holes of the filter, solid particles and viscous substances in the oil accumulate in the filter. If the filter is clogged and the oil cannot pass through the filter element, it may burst the filter element or open the safety valve, bypassing through the bypass valve and bringing contaminants back to the lubrication area, accelerating engine wear and increasing internal contamination. Regularly clean the crankcase. During engine operation, high-pressure unburned gases, acids, moisture, sulfur, and nitrogen oxides from the combustion chamber enter the crankcase through the gap between the piston rings and cylinder walls, mixing with metal powder from part wear to form sludge. In small amounts, it suspends in the oil; in large amounts, it precipitates, clogging the filter and oil holes, making engine lubrication difficult and causing wear. Regularly use a radiator cleaner to clean the radiator. Removing rust and scale not only ensures the normal operation of the engine but also extends the overall lifespan of the radiator and engine.

Whether to press the brake or clutch first when decelerating can be determined based on different situations. The scenario where you press the brake first and then the clutch is: when the speed is high and you need to decelerate, you should press the brake first. Once the speed drops to an appropriate level, press the clutch, shift to a lower gear, and use the engine to decelerate. The scenario where you press the clutch first and then the brake is: when the speed is low and you need to decelerate, press the clutch first and then the brake. The purpose of this is that at low speeds, pressing the brake first can easily cause the engine to stall, and pressing the clutch first can avoid this situation. The functions of the clutch include: 1. Gradually increasing the driving force of the car for a smooth start; 2. Temporarily separating the engine and transmission for gear shifting; 3. Preventing overload in the transmission system; 4. Reducing torsional vibration impact from the engine and extending the life of the transmission gears.

The anti-skid light illuminates due to sensor malfunction. Sensor failure, or potential navigation interference causing tire slippage, may lead the vehicle to determine possible loss of control. Use a computer to inspect the ABS sensor and clear the fault; resolving the ABS light will turn off the anti-skid light. Below are two possibilities regarding system faults: 1. Only the ABS warning light is on: If only the ABS warning light illuminates while driving, it indicates a fault in the ABS system, but the car can still rely on the conventional braking system. Professional inspection should be sought as soon as possible. 2. Both the ABS warning light and the brake system warning light are on: If both the ABS warning light and the brake system warning light illuminate simultaneously while driving, it indicates faults in both the ABS and brake systems, leading to altered braking characteristics. In the latter case, you must stop driving immediately, check the brake fluid level. If the fluid level is at the "min" mark, do not continue driving and seek professional inspection. If the fluid level is normal, it may indicate an ABS system fault, meaning the ABS regulation function has failed, leaving only the ordinary braking system operational. This can cause the rear wheels to lock up more quickly during braking, leading to skidding. Drive cautiously in this situation and seek repairs as soon as possible.

The Hongqi H5 currently has 6 models on sale. Among them, the Hongqi H5-2022 1.8T Automatic Zhilian Qichang and Qiling versions, as well as the facelifted 1.8T Automatic Zhilian Qiyun and Qixiang versions (4 models in total) equipped with a 197 horsepower engine, have an NEDC fuel consumption of 6.4L per 100km. The Hongqi H5-2022 1.5T-DCT Qiyue and Qiyun versions (2 models) equipped with a 169 horsepower engine have an NEDC fuel consumption of 6.2L per 100km. The fuel tank capacity is the same across different Hongqi H5 models. The driving range on a full tank is as follows: For models with the 197 horsepower engine, the fuel tank capacity is 55L, giving a driving range of 55/6.4*100=859km on a full tank. For models with the 169 horsepower engine, the fuel tank capacity is 55L, giving a driving range of 55/6.2*100=887km on a full tank. Vehicle fuel consumption is directly influenced by five major factors: driving habits, the vehicle itself, road conditions, natural wind, and ambient temperature. Specific factors that increase fuel consumption include: Driving habits: Aggressive driving behaviors such as rapid acceleration, frequent overtaking, and not easing off the throttle before traffic lights can increase fuel consumption. The vehicle itself: Vehicles with larger engine displacements generally consume more fuel than those with smaller displacements because larger displacements typically mean greater power output, requiring more gasoline for combustion. Heavier vehicles also tend to have higher fuel consumption due to the greater driving torque needed. Road conditions: Driving on dirt roads, muddy roads, soft surfaces, or mountainous terrain increases resistance and fuel consumption. Natural wind: Driving against the wind or on windy days increases vehicle resistance and fuel consumption. Low ambient temperatures: When the engine block is cold during startup, injected gasoline is less likely to atomize, requiring more fuel for combustion and thus increasing consumption. Additionally, the engine control unit may command higher idle speeds to warm up the engine in cold weather, further increasing fuel consumption.

Single wishbone vehicles generally have a longer body compared to double wishbone vehicles. Double wishbone vehicles feature upper and lower crossbeams in the large arm, welded into a frame structure, while single wishbone vehicles have a single crossbeam structure in the middle. Due to the sufficient strength of the crossbeam, the structural strength and rigidity of the single wishbone are also excellent. The single wishbone is superior to the double wishbone. Because the single wishbone has only one force-bearing point, its force distribution is more uniform and stronger. Fewer components also result in a lower failure rate. Below are some differences between double wishbone and single wishbone: Structure: Double wishbone vehicles have upper and lower crossbeams in the large arm, welded into a frame structure, while single wishbone vehicles have a single crossbeam structure in the middle. Advantages: The biggest advantage of double wishbone vehicles is their flexibility, making them more suitable for narrow spaces. Single wishbone structures are simpler to manufacture, easier to correct for deformation after welding, and provide better visibility for the driver. Application Market: China's first-generation loaders used double wishbone structures, while current production vehicles mostly use single wishbone structures. High-end loaders also adopt single wishbone designs.