(1) For 7.2~12kV voltage class oil-less circuit breakers with brackets, the supporting insulators should be perpendicular and fixed to the brackets during installation. The connection of the upper and lower connecting leads should not be subjected to excessive stress, conductive rods and static touches. The head should be on a vertical line. If the insulator is found to be damaged, it should be replaced in time and the cause should be checked. (2) The connection and fastening of various porcelain parts should be symmetrical and evenly applied to prevent the porcelain parts from being damaged by excessive force. (3) During the inspection, the connecting arm, the connecting plate, the shaft and the pin of the switchgear should be inspected. If it is found to be bent, deformed or broken, the cause should be found, the parts should be replaced and preventive measures should be taken. (4) When adjusting the switchgear, apply slow and slow check to check if there is any jam. All springs and buffers should be adjusted and used within the allowable stretching or compression limits, and regularly check for deformation or damage. (5) The oil dampers of various circuit breakers should be properly adjusted. During commissioning, special attention should be paid to checking the buffer stroke of the oil damper and the bounce and opening bounce of the closing contact to verify that the damper performance is good and to prevent damage to the arm and transmission due to damper failure. It is forbidden to perform quick operation without oil in the buffer. Oil buffers used in low temperature areas should be buffer oil suitable for low temperature environmental conditions. (6) To prevent the circuit breaker insulated rod rupturis running, in addition to the buffer should be checked periodically open and close, to prevent the poor insulation properties of the buffer rod in the transmission process by the impact, but also to strengthen whether the change in relative position of the monitoring sub-closing indicator of the insulating rod connected to the moving member, and Circuit breaker regular tests, in order to detect the problem. Insulation rods for "spiral" connection structures shall be modified. (7) When the pressure equalizing capacitor is installed, it will prevent oil leakage caused by “not strong†and find that the oil leakage should be treated or replaced. (8) the switching device base should not collapse, the displacement. The bracket design should be firm and reliable, and the cantilever beam structure should not be used. (9) In order to prevent the mechanical fixed connection part from loosening, it is recommended to use anaerobic rubber to prevent loosening.
Motive batteries are specialized energy storage devices engineered to deliver high power output, endurance, and reliability for the propulsion of various types of electric vehicles. Unlike conventional batteries used in stationary applications or for small electronics, motive batteries are built to withstand the rigorous demands of continuous movement, vibrations, and temperature variations.
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What is a motive battery?
A motive battery stands out as a unique type of battery, tailored specifically for propelling electric vehicles. These batteries are distinct from those used in stationary settings or smaller electronics. They are designed to withstand the challenges of continuous operation, including constant movement, varying temperatures, and vibrations. They represent a critical component in the shift towards eco-friendly transportation and renewable energy.
Types of Traction Batteries
Sealed Lead Acid Batteries (VRLA/AGM):
These are Valve-Regulated Lead-Acid (VRLA) batteries, often using Absorbent Glass Mat (AGM) technology.
Known for their robustness and cost-effectiveness, they are used in a range of electric vehicles, though their weight and lower energy density compared to newer technologies are notable.
LithiumIon Batteries:
Dominating the modern EV market, lithium-ion batteries are prized for their high energy density and efficiency.
They offer longer life spans and faster charging times compared to lead-acid batteries, making them ideal for electric cars and high-performance vehicles.
Nickel-Metal Hydride (NiMH) Batteries:
These batteries are often found in hybrid vehicles.
They provide a balance between cost, energy density, and environmental friendliness, though they are gradually being overshadowed by lithium-ion technology.
Lithium Iron Phosphate Batteries:
Known for their safety and stability, these batteries are gaining popularity in applications where safety is a major concern, such as in e-bikes and electric scooters.
They offer a good balance between life span, energy density, and safety, making them a preferred choice in specific segments of the EV market.
Each type of motive battery brings its unique strengths and is chosen based on the specific requirements of the vehicle and its intended use. Together, they play a pivotal role in the advancement of eco-friendly transportation and the broader adoption of renewable energy technologies.
Features of Electric Vehicle Battery
High Energy Density: Motive batteries are designed to store a large amount of energy in a relatively small space, enabling electric vehicles to travel significant distances on a single charge.
Durability and Longevity: These batteries are engineered to endure numerous charge-discharge cycles over their lifespan, making them a reliable source of power for electric vehicles.
Fast Charging Capabilities: Modern motive batteries often feature advanced technologies that allow for rapid charging, reducing downtime and enhancing the usability of electric vehicles.
Environmental Friendliness: By employing rechargeable systems and often utilizing less toxic materials, motive batteries contribute to reducing pollution and dependency on fossil fuels.
Safety Features: Safety is a critical aspect, and these batteries are equipped with various mechanisms to prevent overheating, overcharging, and other potential hazards.
Motive Power Battery Usage Scenario
Electric Vehicles (EVs): They are predominantly used in passenger cars, offering a cleaner alternative to internal combustion engines.
Electric Trains: Motive batteries are an integral part of modern electric train systems, providing efficient and eco-friendly mass transit solutions.
Electric Bicycles and Scooters: These batteries enable the widespread use of electric bikes and scooters, particularly useful in urban areas for short-distance travel.
Golf Carts and Utility Vehicles: In recreational and utility vehicles like golf carts, motive batteries offer a silent and pollution-free mode of transport.
Through these enhanced features and varied uses, motive batteries are leading the charge in the electric mobility revolution. Their ongoing development and improvement are vital for achieving long-term, sustainable transport solutions globally.