Where is the Power Steering Fluid Located?

Hydraulic oil cannot be added to the steering gear. Because the viscosity of hydraulic oil is different from that of power steering fluid, mixing different types of hydraulic oil will affect the normal operation of the steering gear. Different machines have specific requirements for the viscosity of hydraulic oil. Different types of oil operate in different environments, with varying additive formulations and base oil requirements, so they should not be mixed. More details are as follows: 1. The liquid used in the hydraulic braking system is called brake fluid, which does not undergo chemical reactions, is unaffected by high temperatures, and does not corrode, soften, or expand metals and rubber. Power steering fluid, on the other hand, is a transmission fluid, and a key indicator is its low-temperature fluidity. Even at temperatures as low as several tens of degrees below zero, it does not thicken, ensuring smooth control of the steering gear. 2. Power steering fluid is a special liquid used in the car's power steering pump. Through hydraulic action, it makes the steering wheel very easy to turn, similar to automatic transmission fluid, brake fluid, and shock absorber fluid. 3. If hydraulic oil is not replenished in time when it is low, minor issues may include loss of power steering assistance and loud power steering noise, while severe cases may result in the power steering pump burning out, affecting normal use.

The exclamation mark light on the dashboard can appear in the following three situations: 1. A triangle with an exclamation mark in the middle, which is a general fault indicator light. It may illuminate under the following circumstances: (1) Overheating of the dry dual-clutch transmission clutch. (2) Fuel cut-off system intervention or malfunction. (3) Parking sensor failure. (4) External light malfunction. (5) Engine oil pressure sensor failure. (6) Traction control system warning or malfunction. 2. A circle with parentheses and an exclamation mark in the middle, which is the brake system warning light. It may illuminate under the following circumstances: (1) In some vehicles, it lights up for a few seconds after turning on the ignition switch and turns off after starting the engine. (2) It lights up when the handbrake is engaged and turns off when released. (3) Low brake fluid level, illuminating while driving. (4) Brake system malfunction. 3. A horizontal line with parentheses and an exclamation mark in the middle: This is the tire pressure monitoring warning light, which illuminates when the pressure in one of the vehicle's tires is too low.

The triangular small glass in a sedan is the most expensive. Below is relevant information about the production and design of this triangular small glass: 1. Design principle of the triangular small glass: This small triangular piece of glass is uniquely designed. The purpose of this design in the car body is to achieve a visually harmonious and aesthetically pleasing effect for the overall appearance of the vehicle. The side rear of the car incorporates a triangular window design, with chrome trim decorating the upper part of the overall window, and the contour features a new style. The triangular window next to the rearview mirror also serves to reinforce the connection between the window and the window lift guide rails, ensuring smoother and more stable operation during the window's up and down movement. This design prevents any jamming or stuttering when the window is being raised or lowered. 2. Reasons for the high cost of the triangular glass: Firstly, this small piece of glass is relatively difficult to manufacture, with significant challenges in sealing design during the production process. Even the slightest data during production requires precise calculation. Most importantly, this glass is more prone to aging compared to other car windows. Therefore, during the manufacturing process, in addition to considering sealing, attention must also be paid to issues such as noise and environmental factors causing glass aging. This makes the use of this glass highly particular, which is why its price is higher than that of larger glass pieces.

Making an immediate U-turn after driving in the wrong direction on a highway will result in a deduction of 12 points and a fine. Prohibited U-turn situations are as follows: U-turns are prohibited where there are "No U-turn" or "No Left Turn" signs: If there is a sign prohibiting U-turns, then U-turns are not allowed at that intersection. A U-turn is an extension of a left turn, so if there is a sign prohibiting left turns at an intersection, U-turns are also prohibited there. U-turns are prohibited at crosswalks: U-turns are not allowed at crosswalks. If U-turns are permitted at an intersection, you must cross the crosswalk before making the U-turn; you cannot make a U-turn on the crosswalk. U-turns are prohibited when there is no left-turn lane: Even if you are in the leftmost lane, U-turns are not allowed if there is no sign permitting left turns. U-turns are prohibited from the second left-turn lane: When a vehicle is in the second left-turn lane, it cannot make a U-turn. In the absence of any signs, U-turns are only allowed from the innermost left-turn lane. U-turns are prohibited at solid yellow lines: U-turns are not allowed at solid yellow lines. Even if there is a sign permitting U-turns, you must wait for the green light and cross the stop line to make the U-turn. U-turns are prohibited on highways: Crossing the central divider to make a U-turn on a highway is illegal and will result in a fine and a deduction of 12 points. If you miss an exit on the highway, continue driving to the next exit to leave the highway; never attempt an illegal U-turn.

Tesla dash cam footage can typically be saved on the memory card for one to two years under normal conditions. The duration before the footage is overwritten depends on the maximum supported capacity of the dash cam and the size of the memory card. Below is additional information about dash cam memory cards: 1. Common memory card sizes for dash cams on the market: Most dash cams support 32G, while some support 64G. The Mingju M2 panoramic dash cam, an industry-first national patent-subsidized product, features 4 lenses, dual 1440P resolution, dual WiFi, and dual memory, supporting up to 256G—currently the largest supported capacity for dash cams. Due to technological and cost limitations, dash cams usually have capacity restrictions. For example, a dash cam that supports up to 32G can only recognize the first 32G of a 64G card, rendering the remaining capacity unusable. Therefore, using a 64G memory card in a 32G-limited dash cam is wasteful, as it can only utilize 32G of the 64G or may not recognize the excess capacity at all. 2. How to evaluate the quality of a dash cam: Assess based on the memory usage over time. For a 32G memory card at the mainstream 1080p resolution (which is not ideal), approximately 120MB of storage is needed per minute of recording, equating to about 7G per hour. For 720p resolution (an outdated standard), around 80MB per minute or 4.7G per hour is required. Many 720p or 1080p dash cams are misleadingly marketed as "high-definition," falsely claiming to match 1296p or 1440p (currently the highest resolution). With a 32G memory card, a 1080p dash cam can record continuously for about 4.5 hours. For dual-lens setups (sharing one memory card), with the front camera at 1080p and the rear at 720p (the highest resolution supported for rear cameras in China), recording time drops to approximately 3 hours. Notably, the Mingju M2 is the first domestic dash cam to support 1080p for both side and rear views.

The starting capacitor in a starter is used to create a rotating magnetic field in a single-phase motor, enabling the machinery to rotate. This is necessary because the single-phase current flowing through a single-phase motor cannot generate a rotating magnetic field on its own. A capacitor is employed to split the phase, aiming to produce a phase difference of approximately 90 degrees between the currents in the two windings, thereby generating the rotating magnetic field. More details are as follows: 1. A capacitor-start induction motor has two windings: the starting winding and the running winding. These windings are spatially separated by 90 degrees. A large capacitor is connected in series with the starting winding. When the running winding and the starting winding are energized with single-phase alternating current, the capacitor causes the current in the starting winding to lead the current in the running winding by 90 degrees in time, reaching its peak value first. 2. This creates two identical pulse magnetic fields in both time and space, generating a rotating magnetic field in the air gap between the stator and the rotor. Under the influence of this rotating magnetic field, an induced current is produced in the motor rotor. The interaction between this current and the rotating magnetic field generates an electromagnetic torque, causing the motor to rotate. 3. To enable a single-phase motor to start rotating automatically, a starting winding can be added to the stator. This starting winding is spatially separated from the main winding by 90 degrees and is connected in series with an appropriate capacitor. This ensures that the current in the starting winding is approximately 90 degrees out of phase with the current in the main winding, following the principle of phase splitting. 4. When these two currents, which are 90 degrees apart in time, flow through two windings that are 90 degrees apart in space, a (two-phase) rotating magnetic field is generated in space. Under the influence of this rotating magnetic field, the rotor can start automatically. Once the speed reaches a certain level, a centrifugal switch or other automatic control device installed on the rotor disconnects the starting winding, leaving only the main winding operational during normal operation. 5. Therefore, the starting winding can be designed for short-term operation. However, in many cases, the starting winding is not disconnected. Such motors are called capacitor-run single-phase motors. To reverse the direction of rotation of such a motor, the position of the capacitor in series can be changed.