Where is the Jiaojiang Subject 2 Test Site?

There are three types of batteries commonly used in car keys: 1. CR2016 button-type battery. This model of button battery is highly prevalent in modern car key remotes and is one of the most universal car remote batteries. These batteries have a voltage of 3V, and since car key remotes typically require 9V, all three batteries need to be replaced at the same time. 2. CR2025 button-type battery. This model is far less commonly used than the CR2016. It is thicker than the CR2016 but has a higher energy storage capacity. The specifications of the CR2025 are: battery diameter of 20mm and thickness of 2.5mm. This model is often used in audio remote controls. 3. Alkaline 12V battery. The 12V alkaline battery was commonly used in early car key remotes and electric rolling doors in shops. Older models of car key remotes, such as those from Honda and Toyota, often used this type of battery.

There are several main reasons why the steering wheel fails to automatically return to center: 1. Uneven tire inflation pressure between left and right wheels. Inconsistent tire pressure is one of the primary causes of weak return force. To diagnose this issue, a tire pressure gauge must be used. Kicking the tread with your foot can only provide a rough estimate of tire pressure. The reason uneven tire pressure causes failure to return to center is that the side with lower pressure has increased ground contact area, naturally encountering greater road resistance, thus causing the vehicle to pull toward the side with lower pressure. In this case, the left and right tire pressures should be readjusted to maintain consistent inflation pressure on both sides. 2. Uneven tire wear between left and right wheels with significant differences. If there is substantial disparity in tire wear between the left and right wheels, it can pull the steering wheel to one side. This issue can usually be addressed through tire rotation. To resolve steering wheel pull and extend tire service life, vehicles should undergo tire rotation every 10,000 kilometers of driving.

According to official data, the A4L 190 has a 2.0T displacement and takes 9.7 seconds to accelerate from 0 to 100 km/h. Factors affecting the vehicle's 0-100 km/h acceleration time are as follows: Torque: Torque generally represents the strength of the force; the greater the torque, the stronger the force pushing the vehicle, and naturally, the faster the acceleration. The BMW 320i has a maximum torque of 205 Nm and takes 9 seconds to accelerate from 0 to 100 km/h. The A4L 190 has a torque of 270 Nm and takes 9.7 seconds to accelerate from 0 to 100 km/h. Transmission efficiency: The transmission is the medium for power delivery and inevitably involves power loss. The higher the transmission efficiency, the better the acceleration performance. Generally, the ranking of transmission efficiency is as follows: manual transmission > dry dual-clutch transmission > wet dual-clutch transmission > AT transmission > CVT transmission. The A4L 190 is equipped with a wet dual-clutch transmission. Power-to-weight ratio: The relationship between horsepower and vehicle weight is called the power-to-weight ratio (unit is Hp/T). The higher the power-to-weight ratio, the faster the acceleration. The BMW 320i has a power-to-weight ratio of 106 Hp/T and takes 9 seconds to accelerate from 0 to 100 km/h. The A4L 190 has a power-to-weight ratio of 93 Hp/T and takes 9.7 seconds to accelerate from 0 to 100 km/h.

Here are the methods to check the license plates under a person's name: 1. Use the 12123 app to query vehicle information under your name by filling in personal details and following the app's instructions. 2. Visit the local vehicle management office for inquiries: Regardless of any changes to your personal information, registration details are always kept at the vehicle management office. Therefore, you can bring relevant documents to check the license plate information registered under your name. 3. Inquire at the insurance company: After purchasing a vehicle, you typically insure it, so the insurance company will also have registration records.

The distinction between forged and cast wheels mainly lies in the manufacturing process, cost, and weight. Here are the detailed specifics: 1. Different Processes: In terms of mold selection, cast wheels use sand molds, while forged wheels utilize steel molds. Cast wheels undergo natural cooling before mechanical processing, including deburring, surface finishing, and polishing. Forged wheels, on the other hand, are shaped through stamping before mechanical processing. The casting technology determines performance. From a performance perspective, forged wheels offer higher strength and lighter weight, whereas cast wheels exhibit better filling properties, fewer shrinkage cavities, and higher density. 2. Different Costs: The casting process is simpler and relatively cheaper, while forging involves more complex procedures, resulting in higher manufacturing costs. In terms of pricing, forged wheels of the same model are typically much more expensive than low-pressure cast wheels. 3. Different Weights: Forged wheels require continuous stamping to form, which results in a very dense molecular structure after shaping, enabling them to withstand higher pressure. Therefore, forged wheels are lighter in weight compared to cast wheels of the same size and strength. In summary, the production process of forged wheels is more precise, making cast wheels somewhat inferior in comparison. As a result, high-end vehicles more commonly opt for forged wheels.

When the vehicle deviates during braking on wet roads, the correct approach is to first firmly grip the steering wheel and avoid slamming on the brakes. In this situation, immediately pressing the brake pedal can easily cause the vehicle to roll over. If the rear wheels remain locked without releasing the pedal, the car may experience a fishtailing effect. Similarly, if the front wheels remain locked without releasing the pedal, the vehicle's direction may become uncontrollable. Below are some precautions for safe driving on slippery roads: 1. While driving: On wet roads, follow the tire tracks of the vehicle ahead to avoid sliding off the road. Maintain a steady speed in third gear and avoid sudden braking to prevent the vehicle from skidding into roadside ditches. 2. Rear-wheel skidding: If the rear wheels skid during braking, immediately release the brake and use a gentle pumping (i.e., cadence braking) technique while lightly steering in the same direction as the skid to regain control. For front-wheel skidding, steer lightly in the opposite direction of the skid. 3. Starting the vehicle: Apply the throttle smoothly and avoid high-rev starts with excessive throttle. Due to the low tire traction on wet roads, high-rev starts can easily cause wheel spin and make it difficult to get moving.