How to reset the tire pressure warning on the Emgrand GL?

The differences between BYD DMp and DMi are as follows: 1. Displacement: Both are equipped with turbocharged engines, but the DMp comes with a 2.0T engine with a maximum power of 192 horsepower (141KW) and maximum torque of 320Nm, while the DMi features a smaller 1.5T engine with a maximum power of 139 horsepower (102KW) and maximum torque of 231Nm. 2. Technology: The 2.0T engine in the DMp, though more powerful, uses more conventional technology; the DMi system's latest 1.5T Xiaoyun engine employs the Miller cycle, making it more advanced, with higher thermal efficiency and lower fuel consumption. 3. Transmission: The DMp is equipped with a traditional 6-speed wet dual-clutch transmission, whereas the DMi uses an E-CVT continuously variable transmission. 4. Motor: Both use permanent magnet synchronous motors, but the DMi models all feature a front-mounted single motor, available in two versions: 145kw and 160kw. The DMp, in addition to a rear-mounted single motor version with 180kw, also offers two dual-motor models with front + rear (250kw + 180kw) configurations. 5. Drive: All DMp models are four-wheel drive, while the DMi models are all two-wheel drive.

Whether cruise control is more fuel-efficient or manual driving is more fuel-efficient depends on the actual road conditions: 1. The cruise control function, during long-distance driving on highways, reduces fatigue and minimizes unnecessary speed variations. Since the computer can automatically control fuel injection and the vehicle operates at a constant speed and under consistent load, it is undoubtedly more fuel-efficient under such road conditions. 2. However, on uphill or downhill roads, to maintain the set speed requirement, the cruise control system may frequently apply brakes or accelerate, leading to higher fuel consumption compared to manual driving.

Tesla's motors are three-phase induction motors produced by Taiwan's Fukuta Electric. An induction motor is a device where the rotor is placed in a rotating magnetic field, and under the influence of this field, it obtains a rotational torque, causing the rotor to turn. The electrical braking methods of Tesla's three-phase induction motor are as follows: 1. Dynamic Braking: During dynamic braking, the three-phase AC power supply to the motor is cut off, and DC power is supplied to the stator windings. At the moment the AC power is cut off, due to inertia, the motor continues to rotate in the original direction. This method is characterized by smooth braking but requires a DC power source and high-power motors, making the DC equipment costly, and the braking force is small at low speeds. 2. Plug Braking: Plug braking is further divided into load plug braking and power plug braking. (1) Load plug braking is also known as load reverse plug braking. This torque allows heavy objects to descend slowly at a stable speed. The characteristics of this braking method are: the power supply does not need to be reversed, no special braking equipment is required, and the braking speed can be adjusted. However, it is only suitable for wound-rotor motors, whose rotor circuit needs to be connected in series with a large resistor to make the slip ratio greater than 1. (2) Power plug braking: When the motor needs to be braked, simply swap any two-phase power lines to reverse the rotating magnetic field for quick braking. When the motor speed reaches zero, the power supply is immediately cut off. The characteristics of this braking method are: fast stopping, strong braking force, and no need for braking equipment. However, during braking, due to the high current, the impact force is also large, which can easily cause the motor to overheat or damage parts of the transmission system. 3. Regenerative Braking: Also known as feedback braking, under the influence of heavy objects, the motor's speed exceeds the synchronous speed of the rotating magnetic field. At this time, the rotor conductors generate an induced current, which produces a torque in the opposite direction of rotation under the influence of the rotating magnetic field. However, since the motor speed is high, a speed reduction device is needed to slow it down.

A car with push-button start cannot be locked without turning off the engine. For push-button start models, the vehicle must be turned off in P (Park) gear to completely cut off the power. If the engine is turned off without being in P gear, although the engine stops running, the vehicle cannot be powered off, and the doors cannot be locked. Therefore, if the engine is not turned off in P gear, you need to press the start button again before getting out of the car to completely cut off the power, allowing the doors and steering wheel to be locked. Using the push-button start when the car is in P or N (Neutral) gear does not harm the engine. However, turning off the engine while the car is in gear can cause some damage to the vehicle. Additionally, for safety reasons, it is best to press the brake pedal before using the push-button start to turn off the engine. The steps to turn off a push-button start car are as follows: Press the brake pedal, bring the vehicle to a smooth stop, shift the gear from D (Drive) to N (Neutral), engage the parking brake, release the foot brake, press the brake pedal again, shift the gear from N to P (Park), release the foot brake, and then press the push-button start key to turn off the power and complete the engine shutdown.

Cleaning carbon deposits in a car depends on the situation. For cars driven in urban areas, it is recommended to clean every 20,000 to 30,000 kilometers, while for those driven on highways, every 30,000 to 40,000 kilometers is advisable. Below are the methods for cleaning carbon deposits: 1. Engine Drip Method: Utilize a small tool resembling an IV drip, where the cleaning agent is introduced into the engine through a tube. 2. Additive Method: Directly add a cleaning additive to the fuel tank. The drawback is that long-term use is required for noticeable effects. 3. Direct Engine Disassembly and Cleaning: This involves disassembling the engine for cleaning, which requires significant time and effort and demands a high level of expertise.

Strictly speaking, driving even one day after expiration constitutes unlicensed driving. However, there are two scenarios regarding an expired driver's license: one is when the validity period expires, within which the license can be renewed through inspection within one year and continue to be used. If it exceeds one year, the driver must retake the exams to obtain a new license. The other scenario is when only the inspection period has passed, which requires different handling procedures. When replacing a motor vehicle driver's license, the driver must undergo inspection by the traffic management department of the public security authority: 1. Drivers holding licenses for large buses, tractors, city buses, medium-sized buses, or large trucks must undergo inspection at the traffic management department within thirty days after the end of each scoring cycle. However, if there are no demerit points recorded during a scoring cycle, the inspection for that cycle is exempted. 2. Drivers holding licenses for vehicle types not specified in the third clause of this article, who are involved in a traffic accident resulting in death and bear equal or greater responsibility without having their license revoked, must undergo inspection at the traffic management department within thirty days after the end of the scoring cycle. 3. Motor vehicle drivers engaged in commercial transportation in a location other than their registered residence can directly undergo inspection at the transportation location after registering with the local vehicle management office for one year.