What to Pay Attention to When Driving Through Deep Water Areas

Honda 30th model uses CBR400 piston size. Honda 30th model specifications: Engine type: Water-cooled 4-stroke DOHC 16-valve V4; Bore x Stroke: 55X42; Max Power: 59PS/12500RPM; Max Torque: 3.7KGM/11000RPM; Dimensions (LxWxH): 1985X705X1075; Wheelbase: 1345; Curb weight: 167KG; Tires: 120/60-17X150/60-18; Fuel tank: 15L. Engine crankshaft phase: 360 degrees, spark plugs were upgraded to a high-temperature resistant type suitable for high RPMs, front fork diameter increased from original 37mm to 41mm, headlight changed to dual lamps, exhaust pipe located on left side.

A damaged fuel pump in a car cannot be considered a major overhaul. Oil contamination is the direct cause of fuel pump damage. It is essential to strictly adhere to the manufacturer's recommended fuel grade, ensure the vehicle does not run low on fuel, and follow proper refueling procedures to prevent damage to the fuel pump. Driving with low fuel levels for extended periods can prevent the fuel pump from cooling properly. Poor fuel quality and excessive impurities can frequently clog the fuel pump, leading to abnormal driving conditions. Function of the Fuel Pump: The fuel pump's role is to transport oil from the oil pan to various oil passages (for cooling purposes) and the oil filter (to filter the oil) through pressurization. It also lubricates the cylinders, ensuring the engine operates smoothly and normally. Automotive repairs include major overhauls and minor repairs. A major overhaul involves repairing or replacing any component of the car (including foundational parts) to restore the vehicle to its optimal technical condition and fully (or nearly fully) recover its lifespan. On the other hand, a minor repair involves replacing or repairing individual parts to maintain or restore the vehicle's operational capability.

Steering wheel abnormal noises may be caused by insufficient lubrication of the steering column, low power steering fluid, issues with the universal joint, or damage to the plane bearing. Steering wheel principle: Many vehicles now have vacuum assist, which only reduces the driver's control effort but does not change the force on the steering gear itself. Therefore, an effective way to reduce steering wheel wear is to minimize the load on the steering wheel during operation. Safety hazards caused by aging: Car enthusiasts should develop the habit of turning the steering wheel only after the wheels start moving. This reduces the friction resistance between the tires and the ground, lessens the excessive load on the steering gear and the excessive wear of the steering linkage system, which can cause abnormal noises when turning the steering wheel. Long-term stationary steering: This not only places a heavy load on the steering gear but also accelerates the wear on the tire surface, reducing the tire's service life. The method to change this habit is: Quickly turn the steering wheel when the wheels are slightly moving to achieve the purpose of control.

Chery Tiggo 3, the fan starts working at 93 degrees. Working principle of the electric fan: The car's electric fan is controlled by a thermostat. When the water temperature rises to the upper limit, the thermostat connects the power supply, and the fan starts working. When the water temperature drops to the lower limit, the thermostat turns off the power supply, and the fan stops working. Reasons why the electric fan does not work: Poor lubrication of the motor: If the fan does not rotate, it may be due to insufficient lubrication of the motor, causing the motor to be unable to drive the fan blades after installation; Motor overheating: Overheating of the motor can also reduce its load-bearing capacity, decreasing the motor's effective power and making it unable to drive the load; Reduced capacitor capacity: The capacitor's capacity may decrease, leading to a reduction in the motor's starting torque and inability to drive the load; Extended motor usage: Over time, the motor wears out. After the motor's shaft sleeve wears, it is easy to burn out. Prolonged use of the motor increases its internal resistance, reduces its load-bearing capacity, and makes it unable to drive the fan blades to rotate.

Mercedes-Benz GLA is not equipped with a three-cylinder engine, but a 1.3T inline four-cylinder turbocharged engine. Engine performance specifications: The Mercedes-Benz GLA uses two versions of the engine, one is a low-power version 1.3-liter turbocharged engine, and the other is a high-power version 1.3-liter turbocharged engine. The low-power version has a maximum power of 100kW and a maximum torque of 250 Nm, with the maximum power achieved at 5500 rpm and the maximum torque available between 1460 to 4000 rpm. The high-power version delivers a maximum power of 120kW and a maximum torque of 250 Nm, with the maximum power at 5500 rpm and the maximum torque between 1620 to 4000 rpm. This engine features direct fuel injection technology and uses an aluminum alloy cylinder head and block. Introduction to the Mercedes-Benz GLA: The Mercedes-Benz GLA is a five-door, five-seat SUV model. Its dimensions are 4427 mm in length, 1834 mm in width, and 1615 mm in height, with a wheelbase of 2729 mm. The Mercedes-Benz GLA perfectly combines powerful performance and handling.

An automobile is typically composed of four main parts: the engine, chassis, body, and electrical equipment. Below is a more detailed introduction: I. Function of the Engine: The engine's role is to burn the fuel supplied to it and generate power. Most cars use reciprocating piston internal combustion engines, which generally consist of the engine block, crankshaft-connecting rod mechanism, valve train, fuel supply system, cooling system, lubrication system, ignition system (used in gasoline engines), and starting system. II. Composition of the Chassis: The chassis receives power from the engine, enabling the car to move and ensuring it operates normally according to the driver's control. The chassis consists of the following components: 1. Transmission System: Transmits the engine's power to the drive wheels. The transmission system includes the clutch, gearbox, drive shaft, and drive axle. 2. Running Gear: Connects all the assemblies and components of the car into a whole and supports the entire vehicle to ensure normal operation. The running gear includes the frame, front axle, drive axle housing, wheels (steering wheels and drive wheels), and suspension (front suspension and rear suspension). 3. Steering System: Ensures the car can move in the direction chosen by the driver, consisting of a steering wheel-equipped steering gear and steering linkage. 4. Braking Equipment: Slows down or stops the car and ensures it remains reliably parked after the driver leaves. Every car's braking equipment includes several independent braking systems, each composed of an energy supply device, control device, transmission device, and brake. III. Body: The body serves as the workspace for the driver and the area for carrying passengers and cargo. It should provide the driver with convenient operating conditions and offer passengers a comfortable and safe environment or ensure the cargo remains intact. A typical truck body includes the front sheet metal cab, driver's cabin, and cargo compartment. IV. Electrical Equipment: The electrical equipment consists of the power supply group, engine starting and ignition systems, car lighting, and signal devices. Additionally, modern cars are increasingly equipped with various electronic devices such as microprocessors, central computer systems, and various artificial intelligence devices, significantly enhancing the car's performance.