Which is more fuel-efficient, the Changan Eado or the Geely Emgrand?

The methods to deflate high tire pressure in a car are: 1. Press the deflation valve directly while observing the gauge to maintain normal tire pressure; 2. Use a valve core wrench or a fine-pointed object like a pen to press against the valve core for deflation. The hazards of high tire pressure are: 1. Reduced friction and adhesion of the tire, affecting braking performance and tire lifespan; 2. Decreased puncture resistance of the tire, increasing the risk of a blowout. The causes of excessively high tire pressure are: 1. Over-inflation of the tire leading to high pressure readings; 2. Excessive imbalance or deflection in tire dynamics, causing increased wear and temperature, leading to higher pressure; 3. Inaccurate wheel alignment in one of the vehicle's wheels. The dangers of high tire pressure include: 1. Reduced tire friction and adhesion, affecting braking effectiveness; 2. Increased steering wheel vibration and deviation, reducing driving comfort.

Car exhaust pipes drip water in winter because gasoline, after safe combustion, produces carbon dioxide and water vapor. The water vapor condenses into liquid water, which is then expelled through the exhaust pipe once it accumulates to a certain amount. Methods for maintaining a car's exhaust pipe include: 1. Preventing water from entering the interior of the exhaust pipe; 2. Applying anti-rust oil inside the exhaust pipe; 3. Regularly inspecting the condition of the exhaust pipe. Symptoms of a clogged car exhaust pipe include: 1. Difficulty accelerating, with the engine RPM and vehicle speed struggling to increase; 2. Automatic transmission vehicles frequently forced to downshift; 3. Reduced engine power and excessive exhaust emissions; 4. Engine shaking, illuminated fault light, and frequent stalling; 5. Continuous heating of the exhaust pipe, reaching the ignition point of nearby components and potentially causing spontaneous combustion.

The reasons for the Wuling Hongguang S's warm air not heating the feet are: 1. The cable controlling the air duct outlet's baffle is damaged; 2. The pull-out wire is separated from the fixed frame. The working principle of car heating is: 1. The compressor sucks in the low-temperature and low-pressure refrigerant gas at the evaporator outlet; 2. It compresses it into high-temperature and high-pressure gas and discharges it from the compressor, reducing pressure and temperature; 3. The refrigerant gas condenses into a liquid, releasing a large amount of heat. The method to turn on the car heating is: 1. Locate the vehicle's air conditioning control button at the display position in the cockpit; 2. Click the off button on the air conditioning control button to turn on the vehicle's air conditioning; 3. Click the air conditioning button on the car's air conditioning to turn off the car's cooling function; 4. Rotate the air conditioning temperature setting knob to set the temperature to the desired level, and the warm air will be turned on.

The reasons for the fan running during a cold start are: 1. The engine coolant temperature sensor is damaged; 2. There is a fault in the fan control system. The reasons for engine shaking during a cold start are: 1. Carbon buildup in the car; 2. Poor combustion in the cylinders; 3. Fuel quality issues; 4. Ignition system failure; 5. Issues with the exhaust gas recirculation valve. The steps to start an automatic transmission car are: 1. Turn the ignition key to the power position; 2. Press the foot brake and shift the gear from P to N; 3. Release the foot brake and start the engine; 4. Warm up the car while stationary; 5. Press the foot brake, shift the gear from N to D, and release the handbrake; 6. Slowly release the foot brake and gently press the accelerator to start smoothly. The steps to start a manual transmission car are: 1. Fully depress the clutch pedal; 2. Push the gear lever to engage the first gear; 3. Lightly press the turn signal lever downward to activate the left turn signal, alerting vehicles in front and behind; 4. Press the horn button to alert pedestrians in front of the vehicle that you are preparing to start; 5. Release the vehicle's handbrake; 6. Lift the left foot gradually until the clutch reaches the half-clutch position, and the vehicle begins to vibrate slightly; 7. The vehicle starts to move; release the clutch and gently press the accelerator.

The fuel tank capacity of the 2018 Sagitar is 53 liters, which is the officially announced data. Owners who have purchased the 2018 Sagitar can also check this information on the vehicle's configuration sheet. The 2018 Sagitar Automatic Comfort, Automatic Fashion, Manual Comfort, and Manual Fashion models use 92-octane fuel, with a fuel consumption of 6.5-6.8L per 100 kilometers. A full tank can cover a distance of 779-815km. Other versions use 95-octane fuel, with a fuel consumption of 5.5-8L per 100 kilometers, and a full tank can cover a distance of 663-964km. During daily driving, it is necessary to pay attention to the remaining fuel level in the tank at all times. This is usually observed through the fuel gauge inside the vehicle. If there are no other issues, the fuel level will be accurately reflected on the gauge. The fuel gauge on the dashboard typically has 5 to 6 segments. It is advisable to refuel when there are only 2 segments left to avoid running out of fuel midway. During actual refueling, the amount of fuel may exceed the calibrated capacity. This is because the fuel tank capacity marked by the car manufacturer is from the bottom of the tank to the safety limit, and there is still some space from the safety limit to the tank opening. This space is reserved to ensure that the fuel in the tank can expand when the temperature rises without overflowing the tank's safety space. If the fuel is filled up to the tank opening during refueling, the actual amount of fuel added may exceed the calibrated tank capacity.

The twelfth generation Crown was launched in 2005. The initial price and configuration list in January 2005 featured only a 3.0L variant, with the 2.5L Royal version added in October. The Toyota Crown, first introduced in 1955 as Toyota's longest-running model, has undergone fourteen generations and remains a flagship mid-to-large-sized vehicle under the Toyota Group. Domestically produced Crown engines came in 2.5L, 3.0L, and 4.3L variants. The first two were V6 24-valve designs, while the 4.3L was a V8. All featured the Dual VVT-i intelligent variable valve timing system. Historical Timeline: 1955 First-generation Crown: Employed double-wishbone front suspension and a 1.5L engine, utilizing dedicated passenger car chassis technology to establish true sedan standards. 1962 Second-generation Crown: Introduced quad-headlight design and wide-low styling, pioneering 2-speed full-automatic AT transmission. 1967 Third-generation Crown: Curved glass design expanded cabin space, while disc brake implementation enhanced safety. 1971 Fourth-generation Crown: Developed distinctive spindle shape focusing on aerodynamics, first adopting EFI system. 1974 Fifth-generation Crown: Featured 4-speed AT and advanced equipment including speed-sensitive power steering and rear electric seats matching luxury sedan standards. 1979 Sixth-generation Crown: Equipped with 2.8L inline-6 SOHC turbocharged engine balancing power and efficiency. 1983 Seventh-generation introduced four-wheel independent suspension, standard ABS, and first mechanical supercharger. 1983 Seventh-generation Crown expanded engine options to nine variants across 2.0L, 2.4L, 2.8L and new 3.0L (190hp/260Nm), retaining 3AT/4AT/5MT transmissions. 1987 Eighth-generation Crown: Incorporated electronically controlled air suspension, traction control, and integrated information display systems.