Reasons for Rubber Friction Sound When Turning at Low Speed?

An electric power steering system in cars consists of a torque sensor, vehicle speed sensor, electronic control unit (ECU), electric motor, and electromagnetic clutch. Below are the working principle and classification of electric power steering systems: Working Principle of Electric Power Steering System: The torque sensor is connected to the steering shaft. When the steering shaft rotates, the torque sensor activates, converting the relative angular displacement between the input and output shafts caused by the torsion bar into an electrical signal sent to the ECU. The ECU determines the rotation direction of the electric motor and the magnitude of the assist current based on signals from the vehicle speed sensor and torque sensor, thereby achieving real-time control of power steering. Classification of Electric Power Steering Systems: There are three types: mechanical hydraulic power steering, electro-hydraulic power steering, and electric power steering.

You can refuel, but it's best to choose reputable small gas stations, meaning those with complete and proper documentation. Potential for clogging the fuel system: Inferior fuel contains excessive impurities. If these clog the system, it can lead to poor fuel delivery. In mild cases, engine performance may decline; in severe cases, the engine may stall or fail to start. Additionally, components such as the fuel pump, fuel filter, pump screen, and gasoline filter are highly susceptible to damage and clogging. Engine carbon buildup: Impurities in gasoline typically exist as gum-like substances. Even if they pass through filtration systems, they can accumulate on intake valves, intake manifolds, and within cylinders, eventually forming hard carbon deposits over time. These deposits adsorb gasoline, leading to improper air-fuel mixtures and affecting engine performance. Damage to the catalytic converter and oxygen sensors: Impure gasoline does not burn completely, directly causing poor exhaust flow, failed emissions tests, unstable engine operation, sluggish acceleration, overall poor fuel economy, and increased fuel consumption.

The method to reset the tire pressure monitoring light on the Magotan is as follows: After addressing the tire pressure issue, first turn on the ignition switch, then press and hold the tire pressure monitoring reset button until you hear a "ding" sound before releasing it. The tire pressure monitoring system will then store the current normal tire pressure data, automatically clear the previous data, and finally, the warning light on the dashboard will turn off, completing the tire pressure reset. Tire pressure monitoring automatically checks the tire pressure in real-time while driving and alerts the driver to any leaks or low pressure to ensure driving safety. There are three common types of tire pressure monitoring systems: Direct Tire Pressure Monitoring: This system uses pressure sensors installed in each tire to directly measure the tire pressure. The pressure information is transmitted wirelessly from inside the tire to a central receiver module, which then displays the data for each tire. The system automatically alerts if the tire pressure is too low or if there is a leak. Indirect Tire Pressure Monitoring: When the pressure in a tire decreases, the vehicle's weight causes the rolling radius of that tire to become smaller, making it rotate faster than the other wheels. By comparing the rotational speed differences between tires, the system monitors the tire pressure. Indirect tire pressure monitoring systems essentially rely on calculating the rolling radius of tires to monitor pressure. Introduction to Tire Pressure Monitoring System (TPMS): This system combines the advantages of both direct and indirect systems. It equips direct sensors in two diagonally opposite tires and includes a 4-wheel indirect system. Compared to using only direct systems, this hybrid approach reduces costs and overcomes the indirect system's inability to detect simultaneous low pressure in multiple tires. However, it still cannot provide real-time pressure data for all four tires as effectively as a direct system.

Spark plugs generally need to be replaced after driving around 30,000 kilometers. The replacement interval varies depending on the material of the spark plugs: yttrium spark plugs should be replaced every 30,000 kilometers, platinum spark plugs every 50,000 kilometers, platinum spark plugs every 80,000 kilometers, and platinum-iridium alloy spark plugs every 100,000 kilometers. Methods to check if the spark plugs are in good condition: 1. Healthy spark plug electrodes should be pale yellow; black electrodes indicate an incorrect air-fuel mixture ratio. 2. If they appear oily, it suggests a misaligned spark plug gap or excessive fuel supply, or a short or open circuit in the high-voltage wire. 3. If the deposits are black, it indicates carbon buildup on the spark plugs and bypassing.

The Lynk & Co 01 uses a transmission from Aisin. Established in 1969, Aisin is a world-renowned professional developer and manufacturer of automotive automatic transmissions. In the field of automotive automatic transmissions, Aisin's products hold the highest market share globally. The two-wheel-drive models of the Lynk & Co 01 are equipped with Aisin's 6AT automatic manual transmission, while the four-wheel-drive models feature a 7DCT dual-clutch transmission. The 7-speed dual-clutch transmission, also known as a 7DCT, utilizes a wet clutch. The wet dual-clutch transmission is characterized by two multi-plate clutches of different sizes, installed coaxially within a sealed oil chamber filled with hydraulic fluid. This design allows for better regulation and higher thermal tolerance, enabling the transmission to handle greater torque. When using the Lynk & Co 01's transmission in daily driving, it is important to observe the following precautions: Do not delay changing the transmission oil for extended periods. Prolonged use without oil changes can damage internal components such as bearings and the transmission housing. Avoid coasting in neutral for long durations. While many experienced drivers may coast in neutral with manual transmissions, doing so with an automatic transmission can cause overheating and create a jolt when shifting back into Drive (D). Never shift into Drive (D) or Reverse (R) before the vehicle has come to a complete stop. Some drivers may attempt to shift into reverse while the vehicle is still moving to demonstrate smooth operation, but this can severely damage the transmission gears, potentially leading to gear grinding and other malfunctions over time. Do not frequently climb steep slopes in Drive (D). Automatic vehicles may overheat under high loads or shift too early, resulting in insufficient power for climbing. In such cases, use manual mode to lock in a lower gear or switch to sport mode to protect the transmission. Avoid long-distance towing. If the automatic vehicle breaks down, use a flatbed tow truck to transport it with the transmission in Neutral (N). Do not use tow ropes or attempt to tow the vehicle directly, as this can cause damage.

A mosquito suspended in the car can keep up with the vehicle's speed due to inertia. The car's speed carries all items inside, making everything in the car move at the same speed as the vehicle. Explanation One: If the mosquito is initially suspended in the air and the car starts accelerating from rest, without air, the mosquito would not move with the car and would collide because nothing affects the mosquito. With air present, the car moves the air along with it, and the air acts on the mosquito, causing it to move. On a high-speed train, the air is relatively stationary to the train, allowing the mosquito to remain suspended in the air. Explanation Two: In this scenario, the car, air, and mosquito are in the same inertial frame. From another perspective, if the car were like a large tube without a front or back, even if the car were moving fast and the air remained still, the mosquito would still not move with the car. The air plays a crucial role.