What brand is the engine of the GAC Trumpchi GS4?

Mini trucks have a mandatory scrapping period of 8 years. A mini truck refers to a commercial vehicle with a length ≤3500mm and a total mass ≤1800kg. Once the service life reaches 8 years, it must be scrapped compulsorily. Light-duty and large commercial trucks have a scrapping period of 10 years. Difference between recommended scrapping and compulsory scrapping: Recommended scrapping suggests disposal, but the vehicle can remain in use if it still meets operational requirements. Compulsory scrapping means the vehicle must be decommissioned without exception. There are four criteria for compulsory scrapping: 1. Reaching the prescribed service life; 2. Failing to meet national safety technical standards for in-use vehicles after repairs and adjustments; 3. Still exceeding national emission or noise standards for in-use vehicles after repairs, adjustments, or control technology implementation; 4. Failing to obtain valid inspection certification for three consecutive inspection cycles after the validity period expires. According to Article 43 of the 'Motor Vehicle Registration Regulations', when applying for new vehicle registration after transferring or deregistering an old vehicle, the original owner may request to retain the old license plate number. The following conditions apply: the application must be submitted within six months after transfer/deregistration, and the owner must have possessed the original vehicle for over three years.

C1 Subject 3 exam has a full score of 100, with 80 being the passing mark. The C1 exam consists of four subjects: traffic regulations and related knowledge, field driving, road driving, and safe and civilized driving common sense. C1 driver's license exam passing standards: Traffic regulations and related knowledge (Subject 1) — written test, full score of 100, passing score is 90 or above. Field driving (Subject 2) — on-site, actual vehicle. Minimum requirement is 80, below 80 is failing. Road driving (Subject 3) — highway or simulated site, actual vehicle. Full score is 100, must achieve 90 or above to pass. Safe and civilized driving common sense — written test, questions mainly in the form of cases, pictures, animations, etc., question types include true/false, single-choice, and multiple-choice, totaling 50 questions, full score of 100, passing score is 90. C1 application age: The minimum age limit for a C1 driver's license is 18 years old, with no upper age limit. However, applicants aged 70 and above must pass tests on memory, judgment ability, and reaction ability.

You should not directly add water to the car coolant, as doing so will lower the boiling point of the new coolant mixture, which may cause the car to overheat. The main component of coolant is ethylene glycol, which has excellent thermal stability—preventing freezing in winter to protect the engine and cooling the engine in summer. This ensures the engine operates at an optimal temperature year-round, an effect that cannot be achieved by using water alone. Coolant serves multiple purposes, including antifreeze, cooling, corrosion prevention, and scale inhibition. Although coolant contains water, it is specifically soft water (distilled water), which has undergone deionization and softening treatment. If the engine coolant level is low, you can add soft water, but be cautious about the quantity—adding too much can alter the coolant's boiling and freezing points. Reasons why you should not add water to car coolant: The primary function of antifreeze is to prevent scale formation. Adding water to antifreeze can lead to scale buildup in the engine, clogging the pipes and affecting performance and lifespan. Mixing water with antifreeze may cause engine scaling, which can block the cooling system, disrupting normal operation and shortening the engine's service life. The water in antifreeze is soft and must be mixed according to specific standards. Therefore, it is not recommended to add water to car antifreeze. Its main role is to circulate within the engine cooling system, carrying away excess heat generated during operation, ensuring the engine runs at the proper working temperature.

The reasons for brake pads making a piercing noise are as follows: 1. The most common reason is excessive wear of the brake pads, which thins them out and causes the warning tab on the brake pad to come into contact with the brake disc. As a result, every time you press the brake, the pads emit a squealing sound. At this point, the brake pads need to be replaced because excessively thin pads can lead to brake failure, posing a safety hazard. 2. Small stones may be lodged in the brake pads. If you frequently drive on rough or damaged roads, it's easy for small stones to get trapped in the brake pads. When you press the brake, a small stone might get caught between the pad and the disc, quickly embedding itself into the pad. 3. Quality issues with the brake pads themselves. Currently, brake pads are categorized into metallic, semi-metallic, and ceramic types. Obviously, metallic and semi-metallic pads are harder than ceramic ones. Excessive hardness not only produces a piercing noise but can also damage the brake disc. Ceramic pads have a much lower noise occurrence rate, so it's recommended to use ceramic pads when replacing brake pads in the future. 4. Quality issues with the brake pads themselves. Currently, brake pads are categorized into metallic, semi-metallic, and ceramic types. Obviously, metallic and semi-metallic pads are harder than ceramic ones. Excessive hardness not only produces a piercing noise but can also damage the brake disc. Ceramic pads have a much lower noise occurrence rate, so it's recommended to use ceramic pads when replacing brake pads in the future.

In winter, a car's fuel consumption is slightly higher than in summer, typically by around 1-2 liters. During the winter months, due to the influence of moving air, the engine increases fuel injection and adjusts the ignition timing to maintain temperature. Additionally, the thermal efficiency of gasoline is significantly lower in cold weather compared to warmer temperatures. Using the car's heater places extra load on the engine. Operating the heater in winter consumes more fuel than using the air conditioning in summer. Theoretically, the heater does not activate the air conditioning compressor; it simply transfers heat from the engine's coolant system into the cabin to warm the interior. On the surface, many people assume that this heat is generated anyway and doesn't involve additional energy consumption or fuel usage. However, while the engine's coolant heat does warm the cabin, if the heat output is insufficient to reach the desired temperature, the engine must work harder to produce more thermal energy to meet the cabin's heating demands, leading to additional fuel consumption. Gasoline's thermal efficiency is lower in winter. One of the main reasons for higher fuel consumption in winter is the reduced thermal efficiency of gasoline due to lower temperatures. Generally, an engine operates optimally within a temperature range of 80°C to 90°C. If the temperature rises too high, the engine's cooling system increases the coolant circulation rate to dissipate excess heat. Conversely, in colder conditions, it reduces the coolant flow to maintain the necessary temperature. This is the fundamental principle of engine cooling—in winter, the engine prioritizes heat retention over dissipation. Due to the effects of moving air, it becomes harder for the engine to maintain a stable temperature around 80°C. To compensate, the engine increases fuel injection and adjusts the ignition timing to sustain the required temperature. Furthermore, gasoline's thermal efficiency is considerably worse in cold weather than in summer. These factors collectively contribute to higher fuel consumption in winter compared to other seasons.

Models equipped with horizontally opposed engines include Subaru's Forester, Subaru XV, Impreza WRX, Legacy, and Outback, as well as the Porsche 718 and Porsche 911. Advantages of horizontally opposed engines: The primary advantage of a horizontally opposed engine is its low center of gravity. With its cylinders arranged "flat," it not only lowers the vehicle's center of gravity but also allows for a flatter and lower front-end design, enhancing driving stability. Additionally, the horizontally opposed cylinder layout is a symmetrical and stable structure, resulting in smoother operation compared to V-type engines and minimal power loss during operation. Naturally, the lower center of gravity and balanced weight distribution also contribute to improved handling. Porsche 718: Equipped with a 2.0T horizontally opposed 4-cylinder turbocharged engine, paired with a 7-speed dual-clutch transmission, delivering a maximum power of 184 kW, 250 PS, and a peak torque of 310 N·m. The Porsche 718 features a mid-engine, rear-wheel-drive layout. Porsche 911: Powered by a 4.0L horizontally opposed 6-cylinder naturally aspirated engine, mated to a 7-speed dual-clutch transmission, producing a maximum power of 383 kW, 521 PS, and a peak torque of 470 N·m. The Porsche 911 is a rear-engine, rear-wheel-drive vehicle. Subaru Outback: Fitted with a 2.5L horizontally opposed naturally aspirated engine, generating 169 horsepower and 252 N·m of torque, paired with a CVT transmission and equipped with the Symmetrical AWD four-wheel-drive system. Subaru Legacy: Features a 2.5L horizontally opposed naturally aspirated engine, producing 171 horsepower and 235 N·m of torque, matched with a CVT transmission. Subaru Forester: Comes with a 2.0L horizontally opposed 4-cylinder naturally aspirated engine, paired with a CVT transmission, delivering 156 horsepower, 115 kW of power, and a peak torque of 196 N·m. Subaru XV: Standard across the lineup with a 2.0L horizontally opposed engine, offering a peak power of 113 kW and a peak torque of 196 N·m. Subaru WRX: Equipped with a 2.4T turbocharged horizontally opposed 4-cylinder engine, capable of producing up to 260 horsepower and 376 N·m of torque.