A control device for remotely accessing a battery management

By using a battery control device with a mechanical structure, the safety hazards caused by the instability of electronic devices are solved, enabling safe battery management and rapid response, and improving overall safety and stability.

CN114825524BActive Publication Date: 2026-07-03萧县鑫辉源电池有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
萧县鑫辉源电池有限公司
Filing Date
2022-04-19
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing remote access battery management control devices suffer from a high error rate due to the instability of electronic equipment, which makes it impossible to perform automatic control in a timely manner in dangerous situations, thus affecting overall safety.

Method used

The control equipment, which employs a mechanical structure, includes a battery box, control box, battery body, control mechanism, main control, and auxiliary mechanisms. It achieves safe battery management through mechanical switching of circuits and gas transmission.

Benefits of technology

It improves the safety and stability of battery control devices, enabling rapid response in dangerous situations, reducing errors, and ensuring safe battery use.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention discloses a control device for remote access and management of batteries, relating to the field of battery auxiliary control technology. Addressing existing devices with certain safety hazards, the following solution is proposed: It includes a battery box with multiple safety plates fixedly connected to its back; a control box slidably mounted on the outside of the battery box, with an installation door on one side; multiple battery bodies snapped onto the safety plates, each battery body having cables connected to both ends; and multiple control mechanisms fixedly connected inside the control box, each control mechanism electrically connected to two cables on its corresponding battery body, the two cables being connected by a wire. This invention has a simple structure, is easy to use, and can realize circuit switching and safe operation. It achieves mechanical switching, improving overall safety and stability. It can automatically switch on and off, further ensuring the safety of overall control, reducing potential errors, and achieving safe use.
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Description

Technical Field

[0001] This invention relates to the field of battery auxiliary control technology, and in particular to a control device for remote access and management of batteries. Background Technology

[0002] A battery is a cup, tank, or other container or composite container containing an electrolyte solution and metal electrodes to generate an electric current. It is a device that converts chemical energy into electrical energy. Some batteries can be recharged using external energy sources for repeated use. In order to better understand the battery during its use, certain control devices are required.

[0003] Existing control equipment generally uses fully electronic devices, which can effectively perform remote control and access, and connect to the battery status. However, due to the higher instability of electronic devices compared to mechanical devices, existing control equipment still has a certain error rate. When errors or dangers occur, it cannot perform automatic control in a timely manner, affecting overall safety. Summary of the Invention

[0004] The present invention proposes a control device for remote access and management of batteries, which solves certain safety hazards.

[0005] To achieve the above objectives, the present invention adopts the following technical solution:

[0006] A control device for remotely accessing and managing batteries, comprising:

[0007] The battery box has multiple safety plates fixedly connected to its back.

[0008] The control box is slidably mounted on the outside of the battery box, and has an installation door on one side.

[0009] The battery body is provided in multiple forms and is snapped onto the safety plate. Both ends of the battery body are connected to cables.

[0010] The control mechanism is fixedly connected inside the control box. There are multiple control mechanisms, and each control mechanism is electrically connected to two cables on the corresponding battery body. The two cables are connected by wires.

[0011] The main control unit is fixedly connected to one side of the control box and is connected to the control mechanism via wires.

[0012] An auxiliary mechanism is installed inside the control box, and one end of the mechanism is fitted with a flexible hose, the other end of which is connected to a conductive mechanism.

[0013] Preferably, the control mechanism includes:

[0014] The mounting box is fixedly connected to the control box via rods;

[0015] A current stabilizer, which is fixedly connected inside the mounting box, with one end connected to the cable;

[0016] An electromagnet, one end of which is connected to a current stabilizer via a wire, is fixed on a mounting box, and the output end of the electromagnet is connected to a trigger unit connected to the mounting box.

[0017] The comparison unit is connected in the middle of the mounting box and is connected to the trigger unit;

[0018] A circuit breaker is fixedly connected inside a mounting box, and its control terminal is connected to a damping rod fixedly connected to the mounting box. The control terminal of the circuit breaker is connected to a comparison unit.

[0019] The monitoring unit is fixedly connected inside the installation box. It is connected to the circuit breaker via wires, and its output is connected to the main control unit.

[0020] Preferably, the comparison unit includes:

[0021] The air guide ring is fixedly connected to the mounting box, and a limiter is connected to one side of the air guide ring. A control ring fixedly connected to the mounting box is connected to one side of the limiter. The two control rings are symmetrically arranged.

[0022] The conductive rod rotates in the middle of the mounting box, and its two ends are rotatably connected to the control box;

[0023] The device has two micro motors, one of which is connected to one of the control coils via a wire, and the other micro motor is connected to an adjacent cable via a wire.

[0024] The first pull rope is provided in two parts. One end of each first pull rope is wound around the output end of two micro motors, and the other end of each first pull rope is fixedly connected to both ends of the conductive rod.

[0025] There are two second pull ropes. One end of each second pull rope is fixedly connected to both ends of the conductive rod, and the other end of each second pull rope is fixedly connected to the control end of the circuit breaker.

[0026] The connecting pipe has one end connected to the air guide ring and the other end connected to the auxiliary mechanism;

[0027] Preferably, the control ring includes insulating arcs on both sides, one end of the insulating arc is fixedly connected to the mounting box, and the other end is fixedly connected to a high-resistance arc. A conductive arc is fixedly connected between the two high-resistance arcs. The limiter is connected to the high-resistance arc, and the triggering unit is connected to the conductive arc through a wire.

[0028] Preferably, the limiter includes a limiting ring fixedly connected to the air guide ring, a first spring fixedly connected inside the limiting ring, and a sliding rod slidably sleeved with the air guide ring at the other end of the first spring. The sliding rod is slidably sleeved with a high-resistance arc, and one end of the sliding rod extends to the inner side of the control ring. A connecting pipe communicating with the air guide ring is connected to one side of the limiting ring.

[0029] Preferably, the triggering unit includes:

[0030] The trigger box is fixedly connected to the top of the mounting box, and a second spring is fixedly connected inside it;

[0031] Two contact plates are symmetrically arranged, and a sliding plate that is fixedly connected to the bottom end of the second spring is slidably connected between the two contact plates.

[0032] The trigger is fixedly connected to the top of the trigger box and is located directly above the electromagnet.

[0033] Preferably, the monitoring agency includes:

[0034] The multimeter is fixedly connected to one side of the mounting box, and its pointer end is fixedly connected to a conductive needle that rotates relative to the multimeter.

[0035] The segmented arc is fixedly connected to the multimeter. The middle part is made of conductive material and the two ends are made of insulating material. The segmented arc is in contact with the conductive needle and is connected to the circuit breaker through wires.

[0036] The fuse is installed in the mounting box, with one end connected to a conductive pin via a wire and the other end connected to the main control.

[0037] Preferably, the auxiliary mechanism includes:

[0038] The pump body is fixedly connected inside the control box. Its output end is connected to a high-pressure pipe. Multiple connecting pipes are connected to the high-pressure pipe. Solenoid valves are connected to the connecting pipes.

[0039] A storage box is located at the top of the control box and is connected to a high-pressure pipe, which is equipped with a one-way valve.

[0040] The connecting strip is fixedly connected to the storage box, and one end of it is connected to the flexible hose.

[0041] Preferably, the guiding mechanism includes a vent plate connected to a hose, a plurality of vent pipes are fixedly connected to one side of the vent plate, and the other end of the vent pipes extends into the battery box. A pressure control valve and a solenoid valve are connected to the vent pipes.

[0042] Preferably, the bottom of the control box is provided with a T-shaped strip, the outer wall of the battery box is provided with a T-shaped groove to accommodate the T-shaped strip, and a sensor is connected inside the safety plate, the sensor being connected to the main control via a wire.

[0043] The beneficial effects of this invention are:

[0044] 1. It can control the circuit breaker, pump body, and micro motor to perform necessary operations according to external control, realize circuit switching and safe operation, realize mechanical switching, improve overall safety and stability, and through the mechanical work of each position, it can automatically switch on and off, further ensuring the safety of overall control, reducing possible errors, and realizing safe use.

[0045] 2: By working in conjunction with other devices, the pump can cool the battery during use, and can also provide rapid cooling or fire suppression in case of short circuit or other dangers, ensuring battery safety. Attached Figure Description

[0046] Figure 1 This is a front sectional view of a control device for remote access and management of batteries proposed in this invention;

[0047] Figure 2 This is a left sectional view of a control device for remote access and management of batteries proposed in this invention.

[0048] Figure 3 This is a front sectional view of the control box of a control device for remote access and management of batteries proposed in this invention;

[0049] Figure 4 This is a front sectional view of the control mechanism of a control device for remote access and management of batteries proposed in this invention;

[0050] Figure 5 This is a front sectional view of a trigger unit for a control device for remote access and management of batteries, as proposed in this invention.

[0051] Figure 6 This is an enlarged schematic diagram of point A of a control device for remote access and management of batteries proposed in this invention;

[0052] Figure 7 This is an enlarged schematic diagram of point B of a control device for remote access and management of batteries proposed in this invention;

[0053] Figure 8 This is a schematic diagram of the control flow of a control device for remote access and management of batteries proposed in this invention.

[0054] Labels in the diagram: 1. Battery box; 2. Safety panel; 3. Control box; 4. Connecting strip; 5. Storage box; 6. Control mechanism; 7. Main control; 8. Battery body; 9. Vent pipe; 10. Flexible hose; 11. Vent plate; 12. T 13. High-pressure pipe; 14. Pump body; 15. Mounting box; 16. Trigger unit; 17. Control coil; 18. Conductive rod; 19. Second pull rope; 20. Segmented arc; 21. Multimeter; 22. Fuse; 23. Conductive needle; 24. Damping rod; 25. Circuit breaker; 26. Connecting pipe; 27. First pull rope; 28. Micro motor; 29. ​​Air guide ring; 30. Electromagnet; 31. Current stabilizer; 32. Trigger box; 33. Contact plate; 34. Second spring; 35. Trigger; 36. Sliding plate; 37. Cable; 38. Sensor; 39. Conducting pipe; 40. First spring; 41. Limiting ring; 42. Insulating arc; 43. High-resistance arc; 44. Sliding rod; 45. Conductive arc. Detailed Implementation

[0055] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments.

[0056] Reference Figure 1-8 A control device for remotely accessing and managing batteries, comprising:

[0057] The battery box 1 has multiple safety plates 2 fixedly connected to its back. The battery box 1 provides necessary protection, and the safety plates 2 physically separate the multiple batteries to reduce mutual interference.

[0058] The control box 3 is slidably mounted on the outside of the battery box 1, and has an installation door on one side. The control box 3 is an external device that can be disassembled and installed to ensure the needs of operation.

[0059] The battery body 8, which is provided in multiple parts, is snapped onto the safety plate 2. Both ends of the battery body 8 are connected to cables 37. The battery body 8 ensures power supply, and the cables 37 realize the power transmission.

[0060] The control mechanism 6 is fixedly connected inside the control box 3. There are multiple control mechanisms 6. Each control mechanism 6 is electrically connected to two cables 37 on the corresponding battery body. The two cables are connected by wires. The control mechanism 6 realizes the need for auxiliary control. At the same time, it is connected to the battery body 8 through the cable 37 to realize real-time sensing and control.

[0061] The main control unit 7 is fixedly connected to one side of the control box 3 and is connected to the control mechanism via wires. The main control unit 7 is an existing structure that performs electronic control of the overall circuit and integrates a remote transmission module to transmit data, ensuring the electronic control of the entire battery.

[0062] An auxiliary mechanism is installed inside the control box 3, and one end of the auxiliary mechanism is fitted with a flexible hose 10. One end of the flexible hose 10 is connected to a conductive mechanism. The auxiliary mechanism performs necessary auxiliary work, while the flexible hose 10 transmits gas.

[0063] Control mechanism 6 includes:

[0064] Mounting box 15 is fixedly connected to control box 3 by rods. Mounting box 15 is used for necessary installation and fixation, and also for necessary protection.

[0065] The current stabilizer 31 is fixedly connected inside the mounting box 15, with one end connected to the cable 37. The current stabilizer 31 performs necessary current stabilization to reduce the impact of initial or sudden current on the entire device.

[0066] The electromagnet 30 has one end connected to the current stabilizer 31 via a wire. The electromagnet 30 is fixed on the mounting box 15. The output end of the electromagnet 30 is connected to the trigger unit 16 connected to the mounting box 15. When the electromagnet 30 is energized, it performs necessary operations on the trigger unit 16 to realize signal transmission.

[0067] The comparison unit is connected in the middle of the mounting box 15 and is connected to the trigger unit 16. The comparison unit also performs necessary operations to ensure the safety of the circuit.

[0068] Circuit breaker 25 is fixedly connected inside mounting box 15. Its control terminal is connected to damping rod 24, which is fixedly connected to mounting box 15. The control terminal of circuit breaker 25 is connected to comparison unit. Circuit breaker 25 realizes the opening and closing of circuit according to the control of main control 7 and comparison unit.

[0069] The monitoring device is fixedly connected inside the installation box 15. It is connected to the circuit breaker 25 via wires, and its output is connected to the main control 7. The monitoring device performs necessary monitoring.

[0070] The comparison unit includes:

[0071] The air guide ring 29 is fixedly connected to the mounting box 15, and a limiter is connected to one side of it. A control ring 17, which is fixedly connected to the mounting box 15, is connected to one side of the limiter. The two control rings 17 are symmetrically arranged. The air guide ring 29 has a hollow structure and the interior of the air guide ring 29 is interconnected. The control ring 17 realizes the necessary control of the circuit opening and closing.

[0072] The conductive rod 18 rotates in the middle of the mounting box 15, and its two ends are rotatably connected to the control coil 17. Through the conduction of the conductive rod 18, the two control coils 17 are connected to each other, so that electricity can pass through. The conductive rod 18 is rotatably connected to the mounting box 15 by a spring hinge, so that it can return to its original position without external force.

[0073] There are two micro motors 28. One micro motor 28 is connected to one of the control coils 17 via a wire, and the other micro motor 28 is connected to an adjacent cable 37 via a wire. The two micro motors 28 are of the same specification and are connected to the main battery body 8 and the adjacent battery body 8 respectively. When both batteries are stable, the whole system can work. When one battery body 8 is overloaded or open-circuited, the current decreases, causing the torque between the two micro motors 28 to be different. Through the first pull rope 27, the angle of the conductive rod 18 is changed, thereby causing the two ends of the conductive rod 18 to be in different positions of the control coil 17.

[0074] There are two first pull ropes 27. One end of each first pull rope 27 is wound around the output end of each of the two micro motors 28, and the other end of each first pull rope 27 is fixedly connected to both ends of the conductive rod 18.

[0075] There are two second pull ropes 19. One end of each second pull rope 19 is fixedly connected to both ends of the conductive rod 18, and the other end of each second pull rope 19 is fixedly connected to the control terminal of the circuit breaker 25. The second pull ropes 19 are connected to the control terminal of the circuit breaker 25 via a fixed pulley. When the conductive rod 18 rotates, one end will inevitably loosen and the other end will tighten, thereby causing the control terminal to switch from the energized state to the de-energized state, realizing the de-energization of the entire circuit. After normal operation, the conductive rod 18 returns to its original position, and the circuit breaker 25 is re-energized through the damping rod 24.

[0076] The connecting pipe 26 is connected at one end to the air guide ring 29 and at the other end to the auxiliary mechanism. The connecting pipe 26 connects the air guide ring 29 and the auxiliary mechanism to ensure the needs of operation.

[0077] The control ring 17 includes insulating arcs 42 on both sides. One end of the insulating arc 42 is fixedly connected to the mounting box 15, and the other end is fixedly connected to a high-resistance arc 43. A conductive arc 45 is fixedly connected between the two high-resistance arcs 43. The limiter is connected to the high-resistance arc 43. The trigger unit 16 is connected to the conductive arc 45 through a wire. During the rotation of the conductive rod 18, both ends first come into contact with the conductive arc 45 to achieve conductivity. Then, driven by the motor, it passes through the high-resistance arc 43 to reduce the current and perform a certain buffering. Then it continues to drive and enters the insulating arc 42. At this time, it is limited by the limiter and cannot return.

[0078] The limiter includes a limiting ring 41 fixedly connected to the air guide ring 29. A first spring 40 is fixedly connected inside the limiting ring 41, and the other end of the first spring 40 is fixedly connected to a sliding rod 44 that is slidably sleeved with the air guide ring 29. The sliding rod 44 is slidably sleeved with a high-resistance arc 43, and one end of the sliding rod 44 extends to the inner side of the control ring 17. A conductive tube 39 connected to the air guide ring 29 is connected to one side of the limiting ring 41. The first spring 40 keeps the sliding rod 44 in a certain position. During the rotation of the conductive rod 18, the sliding rod 44 is squeezed, causing the first spring 40 to contract. Then, after the conductive rod 18 passes, the first spring 40 makes the sliding rod 44 return to its position again, achieving stability. In subsequent use, the gas in the air guide ring 29 is evacuated, and atmospheric pressure is used to make the sliding rod 44 move inward. Under the action of the spring hinge, the conductive rod 18 also returns to its position, completing the necessary work.

[0079] Trigger unit 16 includes:

[0080] The trigger box 32 is fixedly connected to the top of the mounting box 15, and a second spring 34 is fixedly connected inside it. The trigger box 32 provides necessary constraints, and the second spring 34 drives the sliding plate 36 to move.

[0081] There are two symmetrically arranged contact plates 33. A sliding plate 36, which is fixedly connected to the bottom end of the second spring 34, is slidably connected between the two contact plates 33. Under the action of the electromagnet 30, it can slide. When it contacts the contact plate 33, it is energized. When it is not in contact with the contact plate 33, the whole system is de-energized.

[0082] The trigger 35 is fixedly connected to the top of the trigger box 32 and is located directly above the electromagnet 30. The trigger 35 is an existing structure. When it comes into contact with the contact plate 33, it can generate a signal and then transmit it to the main control 7.

[0083] Monitoring agencies include:

[0084] The multimeter 21 is fixedly connected to one side of the mounting box 15. Its pointer end is fixedly connected to a conductive needle 23 that rotates relative to the multimeter 21. The multimeter 21 detects the overall current. When the current changes, it drives the conductive needle 23 to rotate, which in turn causes the conductive needle 23 to contact the segmented arc 20 at different positions, thus achieving intermittent switching.

[0085] The segmented arc 20 is fixedly connected to the multimeter 21. Its middle section is made of conductive material, while its two ends are made of insulating material. The segmented arc 20 is in contact with the conductive needle 23 and is connected to the circuit breaker 25 via a wire.

[0086] The fuse 22 is installed inside the mounting box 15, with one end connected to the conductive pin 23 via an electric wire and the other end connected to the main control 7. The fuse 22 melts at high temperature, serving as a last resort for protection.

[0087] Auxiliary mechanisms include:

[0088] The pump body 14 is fixedly connected inside the control box 3. Its output end is connected to the high-pressure pipe 13. Multiple connecting pipes 26 are connected to the high-pressure pipe 13, and solenoid valves are connected to the connecting pipes 26. The pump body 14 compresses the external gas and then enters the high-pressure pipe 13. When necessary, it enters the air guide ring 29 through the connecting pipes 26 for filling. At the same time, the pump body 14 can also operate in two directions to discharge the gas in the high-pressure pipe 13, forming exhaust in two directions.

[0089] Storage tank 5 is located at the top of control box 3 and is connected to high pressure pipe 13. One-way valve is connected to high pressure pipe 13. Storage tank 5 performs necessary storage. Pump body 14 works to generate high pressure gas, which is temporarily stored in storage tank 5 and released when necessary.

[0090] The connecting strip 4 is fixedly connected to the storage box 5, and one end of it is connected to the hose 10. The connecting strip 4 and the hose 10 are connected to ensure the flow of gas.

[0091] The guiding mechanism includes a vent plate 11 connected to the hose 10. A plurality of vent pipes 9 are fixedly connected to one side of the vent plate 11, and the other end of the vent pipes 9 extends into the battery box 1. A pressure control valve and a solenoid valve are connected to the vent pipes 9.

[0092] The bottom of the control box 3 is provided with a T-shaped strip, and the outer wall of the battery box 1 is provided with a T-shaped groove to accommodate the T-shaped strip 12. The safety plate 2 is connected to a sensor 38, which is connected to the main control 7 via a wire. The T-shaped strip 12 facilitates the connection between the two boxes, and the two boxes can also be more tightly fixed with bolts. The sensor 38 includes a variety of sensors, including but not limited to temperature and humidity sensors and pressure sensors.

[0093] Working Principle: During operation, the control box 3 is installed on the battery box 1, and multiple cables 37 are connected to the control mechanism 6. Other lines are then connected to establish the circuit for the entire device. During operation, the existing central control unit 7 is used for information processing and transmission, ensuring remote control and viewing of multiple data points. When abnormal data occurs inside the battery, the control mechanism 6 reacts. Specifically, when a short circuit or excessive current occurs, the electromagnet 30's magnetic force increases, attracting 36 to move and contact 35, sending a signal to 7, which analyzes and controls the signal. Simultaneously, the sliding plate 36 moves, causing the two contact plates 33 to disconnect, forming an open circuit. At the same time, excessive current in one area causes the micro-motor 28 to have a larger torque relative to the other micro-motor 28. This torque, transmitted through the first pull rope 27, causes the conductive rod 18 to rotate. When the rotation of the conductive rod 18 exceeds the sliding rod 44, an open circuit is formed. Simultaneously, the second pull rope 19 causes the circuit breaker 25 to trip, and the excessive current... The multimeter 21 responds, and the pointer drives the conductive needle 23 to rotate. When it reaches one value, the circuit is broken, thus ensuring the safety of the overall circuit. When the current or voltage decreases, the second spring 34 drives the sliding plate 36 to fall back, thus breaking the circuit. At the same time, one current is normal and the other is small, so the micro motor 28 has a larger torque relative to the other micro motor 28. Then, the first pull rope 27 causes the conductive rod 18 to rotate in the opposite direction to the large current. When the rotation of the conductive rod 18 exceeds the sliding rod 44, the circuit is broken. At the same time, the second pull rope 19 causes the circuit breaker 25 to open. When the current is too small, the multimeter 21 responds, and the pointer drives the conductive needle 23 to rotate. When it reaches one value, the circuit is broken. According to external control, the main control can control the circuit breaker 25, pump body 14, and micro motor 28 to perform necessary operations, realize circuit opening and closing and safe operation, and improve the overall safety and stability.

[0094] In the description of this invention, it should be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," and "counterclockwise," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this invention.

[0095] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this invention, "a plurality of" means two or more, unless otherwise explicitly specified.

[0096] The above description is only a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.

Claims

1. A control device for remotely accessing and managing batteries, characterized in that, include: The battery box (1) has multiple safety plates (2) fixedly connected to its back. The control box (3) is slidably mounted on the outside of the battery box (1), and has an installation door on one side; A battery body (8) is provided in multiple forms and is snapped onto a safety plate (2). Both ends of the battery body (8) are connected to cables (37). The control mechanism (6) is fixedly connected inside the control box (3). There are multiple control mechanisms (6). Each control mechanism (6) is electrically connected to two cables (37) on the corresponding battery body (8). The two cables are connected by wires. The main control (7) is fixedly connected to one side of the control box (3) and is connected to the control mechanism (6) by wires; An auxiliary mechanism is installed inside the control box (3), and one end of the mechanism is fitted with a flexible hose (10), one end of which is connected to a conductive mechanism; The control mechanism (6) includes: Mounting box (15), which is fixedly connected to control box (3) by rods; A current stabilizer (31) is fixedly connected inside the mounting box (15), and one end of it is connected to a cable (37); An electromagnet (30) is connected at one end to a current stabilizer (31) via a wire. The electromagnet (30) is fixed on a mounting box (15). The output end of the electromagnet (30) is connected to a trigger unit (16) connected to the mounting box (15). The comparison unit is connected in the middle of the mounting box (15) and is connected to the trigger unit (16); The circuit breaker (25) is fixedly connected inside the mounting box (15), and its control end is connected to a damping rod (24) fixedly connected to the mounting box (15). The control end of the circuit breaker (25) is connected to the comparison unit. The monitoring unit is fixedly connected in the installation box (15), and is connected to the circuit breaker (25) by wires, and its output is connected to the main control (7); The comparison unit includes: The air guide ring (29) is fixedly connected to the mounting box (15), and a limiter is connected to one side of it. A control ring (17) fixedly connected to the mounting box (15) is connected to one side of the limiter. The two control rings (17) are symmetrically arranged. The conductive rod (18) rotates in the middle of the mounting box (15), and its two ends are rotatably connected to the control ring (17); There are two micro motors (28), one of which is connected to one of the control coils (17) by a wire, and the other micro motor (28) is connected to an adjacent cable (37) by a wire. The two micro motors (28) are of the same specification and are connected to the battery body (8) of the main body and the adjacent battery body (8) respectively. There are two first pull ropes (27). One end of each first pull rope (27) is wound around the output end of each of the two micro motors (28), and the other end of each first pull rope (27) is fixedly connected to both ends of the conductive rod (18). There are two second pull ropes (19). One end of each second pull rope (19) is fixedly connected to both ends of the conductive rod (18), and the other end of each second pull rope (19) is fixedly connected to the control end of the circuit breaker (25). The connecting pipe (26) is connected at one end to the air guide ring (29) and at the other end to the auxiliary mechanism.

2. The control device for remote access management of batteries according to claim 1, characterized in that, The control ring (17) includes insulating arcs (42) on both sides. One end of the insulating arc (42) is fixedly connected to the mounting box (15), and the other end is fixedly connected to a high-resistance arc (43). A conductive arc (45) is fixedly connected between the two high-resistance arcs (43). The limiter is connected to the high-resistance arc (43), and the trigger unit (16) is connected to the conductive arc (45) through a wire.

3. A control device for remotely accessing and managing batteries according to claim 2, characterized in that, The limiter includes a limiting ring (41) fixedly connected to the air guide ring (29), a first spring (40) fixedly connected inside the limiting ring (41), and a sliding rod (44) slidably sleeved with the air guide ring (29) fixedly connected to the other end of the first spring (40). The sliding rod (44) slidably sleeved with the high resistance arc (43), and one end of the sliding rod (44) extends to the inner side of the control ring (17). A connecting tube (39) communicating with the air guide ring (29) is connected to one side of the limiting ring (41).

4. A control device for remotely accessing and managing batteries according to claim 2, characterized in that, The triggering unit (16) includes: The trigger box (32) is fixedly connected to the top of the mounting box (15), and a second spring (34) is fixedly connected inside it. There are two contact plates (33) symmetrically arranged, and a sliding plate (36) fixedly connected to the bottom end of the second spring (34) is slidably connected between the two contact plates (33). The trigger (35) is fixedly connected to the top of the trigger box (32) and is located directly above the electromagnet (30).

5. A control device for remotely accessing and managing batteries according to claim 1, characterized in that, The monitoring agencies include: The multimeter (21) is fixedly connected to one side of the mounting box (15), and its pointer end is fixedly connected to a conductive needle (23) that rotates relative to the multimeter (21). The segmented arc (20) is fixedly connected to the multimeter (21), with the middle part being a conductive material and the two ends being insulating materials. The segmented arc (20) is in contact with the conductive needle (23), and the segmented arc (20) is connected to the circuit breaker (25) through a wire. The fuse (22) is installed in the mounting box (15), and one end of it is connected to the conductive pin (23) by a wire, and the other end is connected to the main control (7).

6. A control device for remotely accessing and managing batteries according to claim 1, characterized in that, The auxiliary mechanism includes: The pump body (14) is fixedly connected in the control box (3), and its output end is connected to a high-pressure pipe (13). Multiple connecting pipes (26) are connected to the high-pressure pipe (13), and a solenoid valve is connected to the connecting pipe (26). Storage box (5) is located at the top of control box (3) and is connected to high pressure pipe (13), which is connected to a one-way valve; The connecting strip (4) is fixedly connected to the storage box (5), and one end of it is connected to the hose (10).

7. A control device for remotely accessing and managing batteries according to claim 1, characterized in that, The guiding mechanism includes a vent plate (11) connected to a hose (10). A plurality of vent pipes (9) are fixedly connected to one side of the vent plate (11), and the other end of the vent pipes (9) extends into the battery box (1). A pressure control valve and a solenoid valve are connected to the vent pipes (9).

8. A control device for remotely accessing and managing batteries according to claim 1, characterized in that, The bottom of the control box (3) is provided with a T-shaped strip (12), and the outer wall of the battery box (1) is provided with a T-shaped groove to accommodate the T-shaped strip (12). A sensor (38) is connected inside the safety plate (2), and the sensor (38) is connected to the main control (7) through a wire.