What are the penalty standards for making a U-turn in Subject 3?

The principle of burning urea: Urea is injected into the automobile exhaust pipe through the urea tank injection system, where it undergoes a chemical reaction with the exhaust gas of diesel vehicles, converting the waste gas produced by the vehicle into water and nitrogen, thereby achieving the goal of energy saving and emission reduction. The use of urea is intended to reduce CO and NO in the exhaust gas, converting these two gases into harmless CO2 and NO2. After urea injection, it forms a mist and undergoes a redox reaction with the high-temperature exhaust gas, with the oxidized portion being completely oxidized substances. More details are as follows: 1. Modern diesel vehicles emit polluting nitrogen oxide gases during operation, which are harmful to the atmosphere and human health. Long-term exposure to these gases can lead to respiratory diseases. To reduce the emission of these gases and minimize their harm to human health, the government has mandated the use of urea in diesel vehicles. 2. For some vehicles, if urea is not used, the power of the vehicle may weaken, and the amount of exhaust gas produced during driving may increase. For example, a National V emission standard diesel vehicle, when fully loaded, consumes about 10kg of urea per 1,000 kilometers traveled.

The Yanmar 85G combine harvester has a fault code table, which is recorded in the manual. Below is an introduction to common harvester faults and their causes: 1. No response or weak starting: No starting response is mainly caused by loose battery terminals or poor grounding of the cable. In this case, tighten the terminals and ensure the grounding wire is securely connected to the body. Also, check the connectors and ensure they are properly connected or replace the electrical components. Weak starting is primarily due to poor terminal contact or insufficient battery power, so tighten the terminals or charge the battery. 2. No power to lights and instruments after starting: Check all fuses, the main power relay, ignition switch, bulbs, wire connectors, etc. Replace fuses, bulbs, relays, or the ignition switch as needed. If the wire or harness plug has poor contact, reconnect the wire plug. 3. No charging: This may be due to the generator fan belt slipping or disconnected wires. Adjust the belt tension or ensure all generator wires are correctly and securely connected. If the ammeter is damaged or the polarity is reversed, replace the meter head or swap the positive and negative terminals. For internal generator faults, repair or replace the generator. Replace the regulator promptly if it is damaged.

The driving range displayed on the dashboard is calculated by the vehicle's onboard computer based on the remaining fuel, indicating how many more kilometers the car can travel. The driving range is determined by the amount of fuel, which in turn is measured by the fuel level sensor. Therefore, it can be concluded that the driving range depends on the fuel level sensor. The fuel level sensor, commonly referred to as the fuel float, is installed inside the fuel tank and detects the amount of fuel based on the fuel level. Here are some common issues related to the fuel gauge: 1. If the fuel tank is half full but the fuel gauge suddenly drops to zero after driving for a while: This is likely a fault with the fuel float. The fuel float operates similarly to a potentiometer or a sliding rheostat. If the "sliding rheostat" shorts at a certain position, this issue may occur. The solution is to remove, clean, or replace the fuel float. 2. If the fuel gauge remains stuck at a certain position and does not decrease even after driving a significant distance: Check if the fuel float is stuck in a particular position. Remove the fuel float and test the flexibility of the float arm by moving it up and down. If it is not flexible enough, clean or replace the fuel float.

The Corolla is a Japanese car. This vehicle stands out in terms of both exterior design and performance. Exterior of the Corolla: It adopts a family-oriented design language. The iconic large-mouth front grille is retained, delivering strong visual impact. The headlight design remains sharp and connects with the central trim strip, creating a somewhat aggressive aura. The C-shaped fog light areas on both sides of the grille enhance the overall design sense. The rear end has a more substantial feel, with rich curve designs adding a strong sense of layering. The polygonal taillights on both sides feature multi-color combinations inside, improving recognition while forming a good echo with the front face. Performance of the Corolla: It offers two engine options: a 1.5L three-cylinder and a 1.2T four-cylinder. The new 1.5L three-cylinder engine boasts a high compression ratio of 13:1, with a maximum power output of 121 horsepower and peak torque of 148 Nm, achieving a thermal efficiency of up to 40%. The 1.2T four-cylinder engine delivers a maximum power of 116 horsepower and peak torque of 185 Nm. For the transmission system, it is paired with either a 6-speed manual or a CVT continuously variable transmission (simulating 10 gears).

Whether Volkswagen Bora should use semi-synthetic or fully synthetic engine oil depends on the oil change interval. Fully Synthetic Engine Oil: Fully synthetic engine oil is a high-grade lubricant. It utilizes superior components from crude oil, undergoes chemical reactions, and achieves the desired molecular structure under controlled conditions. The molecular arrangement of fully synthetic oil is orderly, giving it strong resistance to external changes. For driving in most cities across China, fully synthetic oil can be changed every 10,000-12,000 kilometers or approximately once a year. Semi-Synthetic Engine Oil: Semi-synthetic engine oil is formulated using semi-synthetic base oil, specifically Group III base oil internationally. It is a refined product derived from mineral oil through hydro-cracking technology, consisting of a 4:6 ratio of mineral oil to fully synthetic oil. The purity of semi-synthetic oil is very close to that of fully synthetic oil, but its cost is slightly higher than mineral oil. It serves as an ideal transitional product from mineral oil to synthetic oil. For driving in most cities across China, semi-synthetic oil can be changed every 5,000-8,000 kilometers or approximately every six months.

All Lynk & Co 01 models are equipped with a four-cylinder engine, with a displacement of 2.0 liters and a turbocharged type. Below is a detailed introduction to the Lynk & Co 01: 1. The Lynk & Co 01 is the first model produced by Lynk & Co, belonging to the compact SUV category. In terms of body dimensions, the Lynk & Co 01 measures 4512*1857*1689mm in length, width, and height. 2. In terms of power, the Lynk & Co 01 is powered by a 2.0-liter four-cylinder turbocharged engine across all variants, delivering a maximum horsepower of 190 hp, a maximum power of 140 kW, and a maximum torque of 300 N·m. 3. Regarding fuel consumption, the official combined fuel consumption as per the Ministry of Industry and Information Technology is 6.5L/100km. However, based on real-world test data, the actual fuel consumption is typically around 9L/100km. 4. In terms of transmission, the Lynk & Co 01 is equipped with a 6-speed automatic transmission across all models. 5. For the suspension system, the front suspension of the Lynk & Co 01 is a MacPherson strut independent suspension, while the rear suspension is a multi-link independent suspension. 6. In terms of tire specifications, both the front and rear tires of the Lynk & Co 01 are 235/60R17.