What are the body dimensions of the Fengguang e1?

Kia KX3's motor has a maximum power of 81.6kW and a maximum torque of 285Nm. Here is some information about the Kia KX3: 1. The Kia KX3 EV is a pure electric vehicle, and this model is a single-motor variant. 2. The Kia KX3 has a range of approximately 300 kilometers, which is the data provided by the Ministry of Industry and Information Technology. The actual range may be slightly lower, as the ministry tests the range under relatively ideal conditions. 3. The motor of a pure electric vehicle does not produce excessive vibration or noise during operation, so the interior of a pure electric vehicle is very quiet when driving.

Buick Excelle hood closing method is as follows: 1. Lower the front hood support stand, use the other hand to hold the hood, slowly move it downward. When it's about 50mm-60mm from closing, release it to allow free fall movement. A clicking sound indicates the hood is closed. Without this free fall distance, the hood might not seal properly. 2. After locking, check whether the engine hood is tightly closed. Here are some details about Buick Excelle hood: 1. Price: A genuine Buick Excelle hood costs about 1,200 RMB, with painting fees around 400 RMB. 2. The engine hood serves two key functions in car collisions: energy absorption and pedestrian protection.

Car torque is the rotational force output from the crankshaft of an engine. Here are more details about car torque: 1. With a fixed power output, car torque is inversely proportional to engine speed. The faster the speed, the smaller the torque, and vice versa, reflecting the vehicle's load capacity within a certain range. 2. The greater the torque output, the higher the vehicle's carrying capacity. It also means better acceleration performance and stronger climbing ability. This results in fewer gear shifts and relatively less wear on the transmission. During startup, the advantages of higher torque become even more apparent.

There are several main differences between regular car batteries and start-stop batteries: 1. Start-stop batteries can be used more times and have a longer lifespan than regular batteries. Their plates are harder than regular plates, and the active material is less prone to falling off, making them suitable for vehicles with start-stop mode. 2. Start-stop batteries are manufactured using stamping processes due to higher technical requirements, but they have larger capacities and can charge and discharge quickly. Ordinary lead-acid batteries cannot discharge large currents multiple times in a short period, as their separators do not allow ions to pass through quickly. 3. The conditions for start-stop engine shutdown are very strict: low battery charge, low air temperature, low water temperature, fog lights on, distance from last activation to current parking less than 300 meters, or engine speed not reaching above 1800 rpm from last activation to current parking. If these conditions are not met, the engine will not shut down.

Abnormal noise fault phenomena in the drive axle: 1. Abnormal noise occurs in the drive axle while driving, which weakens or disappears when coasting in neutral. 2. Abnormal noise occurs in the drive axle both while driving and coasting in neutral. 3. No abnormal noise occurs when the car is driving straight, but abnormal noise appears in the drive axle when turning. 4. Abnormal noise occurs in the rear drive when going uphill or downhill, or in the drive axle during both uphill and downhill driving. 5. There is operational noise or heavy abnormal noise from the wheels. Fault causes: 1. Excessive meshing clearance of the conical and cylindrical main and driven gears, planetary gears, or half-shaft gears; loose fit between the half-shaft gear spline groove and the half-shaft; poor meshing of the main and driven conical gears; uneven meshing clearance of the conical and cylindrical main and driven gears; gear tooth surface damage or broken teeth. 2. Loose main conical gear bearing; loose main cylindrical gear bearing; loose differential conical roller bearing; excessive preload in a rear axle bearing leading to insufficient clearance; improper adjustment of main and driven conical gears, resulting in insufficient clearance. 3. Mismatch between differential planetary gears and half-shaft gears, causing poor meshing; worn or broken planetary gears or half-shaft gears; worn differential cross shaft journal; thinned planetary gear support washer; planetary gears sticking to the differential cross shaft or improper assembly (e.g., excessively thick planetary gear support washer), making planetary gear rotation difficult; loose fastening rivets between the reducer driven gear and the differential housing. 4. Insufficient gear meshing clearance in a certain part of the drive axle, causing noise when going uphill; excessive gear meshing clearance in a certain part of the rear axle, causing noise when going downhill; improper gear meshing marks or loose gear shaft support bearings in a certain part of the rear axle, causing noise during both uphill and downhill driving. 5. Damaged wheel hub bearing or loose bearing outer ring; foreign objects inside the brake drum; broken wheel hub; excessively worn wheel hub bolt holes, leading to insecure wheel rim fixation.

Mazda 3 Axela's engine is a compression ignition engine, with the following details: 1. The Mazda 3 Axela is equipped with the SKYACTIV-X 2.0L gasoline compression ignition engine. This engine features Mazda's unique SPCCI (Spark Plug Controlled Compression Ignition) technology, enabling seamless switching between spark ignition and compression ignition to enhance power output and fuel efficiency. 2. Compared to Mazda's previous SKYACTIV-G 2.0L engine without this technology, which had a maximum power of only 158 horsepower and a peak torque of 202 Nm, the SKYACTIV-X 2.0L engine with this technology achieves a maximum power of 180 horsepower and a peak torque of 224 Nm under the same displacement. In addition to a 10% to 30% increase in torque output, fuel economy has also improved by 20% to 30%, with the new car's reported combined fuel consumption being 5.2L per 100 kilometers.