How many days after applying car heat insulation and explosion-proof film can you open the windows?

Automotive ignition system works as follows: the engine computer integrates input information from various sensors, selects the appropriate ignition advance angle from the memory, and determines the crankshaft speed, position, and which cylinder is at the compression top dead center based on the crankshaft position sensor. It then controls the conduction and cutoff of the high-power transistor, i.e., the interruption of the primary current in the ignition coil. The basic components of an automotive ignition system are: power source; sensors; ECU; ignition coil; distributor; spark plug. Ignition coils used in engine ignition systems can be divided into two types based on the magnetic circuit: open magnetic circuit type and closed magnetic circuit type. The open magnetic circuit type ignition coil generally has a can-shaped structure. It consists of several laminated silicon steel sheets forming a rod-shaped iron core, with the secondary coil and primary coil wound around the outer side of the iron core. The closed magnetic circuit ignition coil has a sealed iron core. The function of the automotive ignition system is to generate an electric spark when the cylinder piston reaches the end of compression, igniting the air-fuel mixture. The rapid combustion of the mixture produces powerful force to push the piston downward, enabling the engine to perform work.

It is appropriate to charge an electric vehicle when the battery level remains at 40%, as the battery is in the plateau region, which is beneficial for battery lifespan. A scientifically correct charging method is an important factor in ensuring battery condition and usage cycle. When the battery level drops to 20%, there may be inaccuracies in battery level estimation, and the battery might no longer be in the plateau region. Charging at this point can shorten the battery's lifespan, and the vehicle may also experience sudden breakdowns or become undrivable. In practical usage, charging an electric vehicle should follow the principle of shallow charging and discharging, avoiding full discharge. Pure electric vehicles use ternary lithium batteries, which have minimal memory effect. Unlike other batteries, they do not have charging memory, meaning the battery's condition is not affected by the amount of charging. The power battery in electric vehicles is designed for cycle usage, and frequent charging does not negatively impact the power battery.

It typically takes about 20-30 kilowatt-hours of electricity to fully charge an electric vehicle. Electric vehicle batteries are divided into two main categories: storage batteries and fuel cells. There are two charging methods: fast charging and slow charging. Fast charging refers to high-power DC charging, which can charge the battery to 80% capacity in half an hour. Slow charging refers to AC charging, which takes 6 to 8 hours to complete. Precautions for Charging Electric Vehicles: Avoid Overcharging and Over-Discharging: During the charging process, it is important to control the charging time reasonably to avoid overcharging. Overcharging can cause the battery to overheat and potentially explode. While driving, it is necessary to monitor the battery level. If the battery indicator shows the red zone, the driver should stop operating the vehicle and charge it as soon as possible. Driving with insufficient battery power can significantly increase the battery's wear rate. Recommend Daily Charging: It is recommended that owners charge their vehicles daily, as this keeps the battery in a shallow cycle state, which is more conducive to extending its lifespan. Pay Attention to the Charging Cable Plug: During the charging process, if the charging plug is found to have poor contact, it should be addressed promptly to avoid overheating. Prolonged overheating of the plug may lead to a short circuit, which can easily damage both the charger and the battery.

Electric vehicles take 5-10 hours to fully charge. There are two types of charging for electric vehicles: AC charging and DC charging. AC charging is the safest and most conventional method for electric vehicles, typically requiring 6-8 hours to complete. AC charging can be done at home or via charging stations. Home charging usually provides 3 kWh per hour, while AC charging stations may offer either 3 kWh or 6 kWh per hour, depending on the station and the vehicle's onboard charger. DC charging is exclusively done at stations but offers more power options. Charging methods for electric vehicles include: Portable charging cable: This can be plugged directly into a standard 220V/16A household socket to charge the electric vehicle, but the charging speed is relatively slow. Home charging station: If you have a dedicated parking space, you can opt to install a home charging station. However, this requires approval from the property management and must pass an inspection by the power company, making the process somewhat cumbersome. Public charging stations: Most public charging stations are built and operated by power companies such as State Grid and Southern Grid, though some private enterprises have also entered this sector.

Electric car lights flickering can be caused by: deep discharge of the electric vehicle; charger malfunction; poor contact; or wiring faults in the electric vehicle itself. Deep discharge of the electric vehicle: You can charge it continuously for 12 hours. If that doesn't work, use a charger with the same voltage (20AH) to activate it, charging for 5 hours. Charger malfunction: If the electric car lights are flickering, it may be because the battery is not charging and lacks power. It should be sent to after-sales service for inspection and possibly replacing the charger. If the issue is with the battery, a 36V Giant battery may need to be replaced. Poor contact: It is recommended to check whether the internal wiring of the electric vehicle's headlights has poor contact. If confirmed, the internal wires can be replaced or reconnected. Wiring faults in the electric vehicle itself: If the lights start flickering when the power is connected but not yet plugged into the battery, it indicates a fault in the electric vehicle itself and should be sent to after-sales service for inspection.

Which is better between electromagnetic suspension and air suspension depends on the driving environment. In areas with good road conditions, air suspension is preferable as it is less likely to have its air tank scratched by gravel or other debris. In regions with harsh weather conditions, electromagnetic suspension is the better choice. Air suspension consists of an air spring and an adjustable damper, offering the ability to adjust vehicle height and change damping. It is a fully active suspension system. Depending on the road surface, the suspension can be adjusted on-demand to achieve optimal performance, providing excellent adaptability. Its downside is the relatively complex structure and high cost. Electromagnetic suspension is an independent suspension system that operates based on electromagnetic response. The structure of electromagnetic suspension is relatively simple, comprising an onboard control system, wheel displacement sensors, electromagnetic hydraulic rods, and straight-tube shock absorbers. It can be powered directly by the car battery, resulting in low power consumption. Since the suspension effect is achieved through electromagnetic response, there are fewer moving parts, allowing it to operate in temperatures ranging from -50°C to 140°C. Additionally, it produces significantly less noise compared to other suspension systems. Similar to air suspension, it can adjust to various driving modes, offering different driving experiences. Its drawback also lies in the cost issue.