What is the fuel consumption of the Haval H6 National Trend Edition 1.5T?

When a vehicle has no power despite the battery having charge, the reasons may include: loose battery group connectors, broken internal battery connection wires, short circuits in the wiring, blown fuses, or the vehicle's power-off switch not being turned on. Below are more relevant details: 1. Battery: The red terminal is the positive pole, and the black terminal is the negative pole. Generally, the left side is positive and the right side is negative. Be cautious to avoid short circuits when connecting the battery. Short-term exposure to water will not affect the battery's performance, as water is a weak electrolyte with poor conductivity. However, it is essential to dry it immediately to prevent oxidation of the terminals, which could lead to terminal detachment and battery damage. 2. Battery Has Charge but Vehicle Won't Start: This symptom is often caused by a blown fuse responsible for the starter motor. It's important to note that if the vehicle fails to start, avoid repeatedly attempting to start it, as this can drain the battery completely, leaving it powerless. 3. Replacing a Fuse: If a car fuse is blown, it must be replaced. You can visit a repair shop to have it replaced. 4. Fuse Location: The location of the fuse varies depending on the vehicle model. Generally, the fuse box is near the battery. The fuse box is usually secured with clips, and some high-end models may have bolts. Carefully remove the box to access the fuses.

The differences between internal and external air circulation: 1. Different principles: Internal circulation keeps the air inside the car flowing in a closed environment; External circulation brings outside air into the vehicle. 2. Different air intake locations: Internal circulation draws air from inside the cabin, preventing outside air from entering; External circulation's air intake is located below the front windshield wiper, pulling outside air into the car. 3. Different effects: Prolonged use of internal circulation can make the air stale, reduce oxygen levels, cause discomfort like heat and fatigue, and affect driving safety; External circulation maintains air flow between inside and outside the car, preventing excessive carbon dioxide concentration.

A 1.3L displacement car consumes 6-6.5 liters of fuel per 100 kilometers. Below are some related introductions about fuel consumption: 1. Tires: Fuel consumption is closely related to tires. Generally, the larger the contact area between the tires and the ground, the stronger the grip. However, the frictional resistance also increases. 2. Oxygen sensor: The main function of the oxygen sensor is to monitor the oxygen concentration in the exhaust. The car's computer adjusts the fuel injection amount in real-time based on the data it provides. It is usually installed near the three-way catalytic converter and is divided into the front oxygen sensor and the rear oxygen sensor. 3. Poor driving habits and road conditions: Poor driving habits are also a reason for increased fuel consumption. Examples include sudden acceleration, sudden braking, sudden stops, prolonged idling, speeding, frequent lane changes, and for manual transmission cars, delayed gear shifting and driving at high speeds in low gears.

Generally not. Because the seat position is calculated and designed to be exactly at the force-bearing point. Unauthorized changes to the force-bearing point may affect the car's balance and seat safety. The so-called car seat refers to the seat used when riding in a car. By position, it can be roughly divided into: 1. Front seats: headrest, backrest, seat cushion, (armrest); 2. Rear seats: (headrest), backrest, seat cushion, side wings, (armrest). More related information is as follows: 1. Seat functions: Common seat functions include seat memory, seat heating, seat ventilation, and seat massage. Seat memory can store seat positions. When the vehicle has multiple regular drivers, such as couples, bosses and drivers, etc., the seat memory can restore the seat position with one click when changing drivers, eliminating the need for repeated adjustments. 2. Seat heating: Seat heating refers to the electric heating device inside the seat. It generally appears in vehicles with leather seats. Since the surface material of leather seats is colder in winter, with seat heating, when sitting down in the cold winter, you won't be greeted by a cold leather seat. Most electric heating devices have a temperature adjustment function.

Motorcycle spontaneous combustion mainly occurs due to electrical connectors or wires spontaneously grounding and sparking, generating high temperatures that ignite flammable paint, leaked gasoline, or other combustible materials. Therefore, electrical leakage or grounding sparks are critical factors, and reducing fuel leakage is particularly important. The specific causes of spontaneous combustion are as follows: 1. High-voltage ignition leakage sparks: When the engine is running, the ignition coil reaches high temperatures, causing the insulation of high-voltage ignition wires to soften, age, crack, or deteriorate. This allows high-voltage ignition electricity to easily penetrate the insulation (at cracked areas) and spark between the wire and the motorcycle's body parts (grounding). If the spark comes into contact with the paint on the frame or fuel tank, or with gasoline leaking from the carburetor, it can lead to ignition and combustion. 2. Electrical devices, switches, or wires breaking and sparking: Although most electrical devices, switches, and wires operate at low voltage, any breakage, poor contact, or insulation damage can result in grounding and sparking. 3. Electrical failure and short circuits: A common example is the rear brake light failing due to contact point welding. Prolonged grounding can cause high current to pass through the wire, melting the insulation and leading to widespread electrical leakage. The resulting high temperatures can ignite flammable materials such as paint or leaked fuel.

Auxiliary road vehicles refer to the lanes on both sides of the main road, which are designed to assist the main road in traffic flow. The main road is exclusively for motor vehicles, while the auxiliary road accommodates mixed traffic of motor vehicles, non-motor vehicles, and pedestrians. Main road vehicles travel on the regular traffic lanes. The speed limits differ: auxiliary road vehicles are not allowed to exceed 60 km/h, whereas main road vehicles can reach speeds of 80 km/h or more. Classification based on usage, function, and traffic volume: 1. Expressway: A multi-lane highway exclusively for motor vehicles with controlled access and divided lanes for directional traffic. 2. Class I Highway: A multi-lane highway for motor vehicles with divided lanes and optional access control. It connects expressways or serves as a main road in urban-rural fringe areas, economic zones of development areas, and sparsely populated regions. 3. Class II Highway: A two-lane highway for motor vehicles, typically serving as a main road in medium-sized or larger cities or connecting to large industrial zones and ports. 4. Class III Highway: A two-lane highway primarily for motor vehicles, functioning as a distributor road connecting counties and towns. 5. Class IV Highway: A two-lane or single-lane highway mainly for motor vehicles, serving as a local road connecting villages and rural areas.