A lead-acid battery energy storage cradle that is easy to install
By designing an easy-to-install lead-acid battery energy storage bracket, adopting a quick-connect structure with connecting columns and plugs, and equipping it with a spark sensor and a microprocessor-controlled high-pressure carbon dioxide fire extinguishing system, the problems of complex installation and insufficient safety monitoring of lead-acid battery brackets are solved, achieving rapid installation and effective fire extinguishing in case of spontaneous combustion.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ANHUI HONGDA ELECTRICAL SOURCE
- Filing Date
- 2025-06-18
- Publication Date
- 2026-06-09
AI Technical Summary
Existing lead-acid battery brackets are complex to install and lack effective safety monitoring and emergency fire extinguishing measures, resulting in inconvenient installation and potential safety hazards.
An easy-to-install lead-acid battery energy storage bracket was designed, featuring a quick-connect structure with connecting columns and plugs, and equipped with a spark sensor and a microprocessor-controlled high-pressure carbon dioxide fire extinguishing system for monitoring and emergency fire suppression.
It enables rapid installation of lead-acid batteries and effective fire extinguishing in case of spontaneous combustion, improving the practicality and safety of the device.
Smart Images

Figure CN224342425U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of bracket technology, and in particular to a lead-acid battery energy storage bracket that is easy to install. Background Technology
[0002] Lead-acid batteries include various types, such as conventional flooded lead-acid batteries, gel maintenance-free lead-acid batteries designed specifically for solar energy, and lead-carbon batteries. In practical applications, lead-acid batteries are widely used in energy storage systems due to their efficient chemical energy conversion, compatible voltage design, and diverse types.
[0003] When using lead-acid batteries as storage batteries in an energy storage system, brackets are needed to support and fix the lead-acid batteries. The current lead-acid battery brackets often have a relatively complex installation structure, which is often troublesome to install. At the same time, since lead-acid batteries may spontaneously combust during use, it is necessary to monitor the batteries placed on the brackets and to promptly extinguish any fires that occur.
[0004] Therefore, it is necessary to improve the existing technology to solve the above-mentioned technical problems. Utility Model Content
[0005] To address the shortcomings of existing technologies, this utility model provides an easy-to-install lead-acid battery energy storage bracket, solving the problems mentioned in the background section.
[0006] To achieve the above objectives, this utility model provides the following technical solution: a lead-acid battery energy storage bracket that is easy to install, comprising a base plate, a support column fixedly installed on the upper side of the outer wall of the base plate, a linearly arranged placement plate provided on the upper end of the outer wall of the support column, a connecting column detachably connecting the upper and lower placement plates, a connecting plate fixedly installed on the rear end of the upper side of the outer wall of the placement plate, a connecting pipe fixedly connected to the connecting plate, the front end of the outer wall of the connecting pipe penetrating the front side of the outer wall of the connecting plate and fixedly connected to a connecting frame, and nozzles linearly arranged and fixedly installed on the front side of the outer wall of the connecting frame.
[0007] As a further technical solution of this utility model, the bottom plate has symmetrically fixed plugs installed on the upper and lower sides and left and right ends of the outer wall, and the connecting column is simultaneously plugged into the upper and lower plugs.
[0008] As a further technical solution of this utility model, the upper and lower ends of the connecting column and the side wall of the plug are provided with through mounting holes, and each mounting hole is fitted with a mounting screw, and each mounting screw is threaded with a locking nut.
[0009] As a further technical solution of this utility model, a fixing plate is fixedly installed on the lower side of the outer wall of the placement plate, and mounting hoops are linearly arranged and fixedly connected on the lower side of the outer wall of the fixing plate. A high-pressure carbon dioxide cylinder is fixedly installed inside the mounting hoops, and the lower end of the outer wall of the connecting pipe is fixedly connected to the output end of the high-pressure carbon dioxide cylinder.
[0010] As a further technical solution of this utility model, a solenoid valve is fixedly installed on the connecting pipe, a connecting frame is fixedly connected to the upper left end of the outer wall of the placement plate, a spark sensor is fixedly installed on the upper end of the outer wall of the connecting frame, and a microprocessor is fixedly connected to the upper right end of the outer wall of the placement plate. The solenoid valve and the spark sensor are both electrically connected to the microprocessor.
[0011] As a further technical solution of this utility model, a connecting rod is fixedly installed on the right end of the placement plate, and an alarm light is fixedly connected to the upper end of the outer wall of the connecting rod. The microprocessor is electrically connected to the alarm light.
[0012] This utility model provides an easy-to-install lead-acid battery energy storage bracket, which has the following advantages compared with the prior art:
[0013] 1. This utility model achieves quick connection between the upper and lower placement plates by plugging in the connecting column and the plug, and fixes the connection between the plug and the connecting column by inserting the mounting screw into the mounting hole and tightening the locking nut, making the installation of the device convenient and quick. At the same time, the device can hold multiple lead-acid battery blocks by using multiple upper and lower connected placement plates, thereby increasing the practicality of the device.
[0014] 2. In use, the device monitors the lead-acid batteries placed on the placement plate using a spark sensor. When a lead-acid battery on the placement plate spontaneously combusts, the spark sensor feeds back the monitoring signal to the microprocessor. The microprocessor then opens the solenoid valve to input carbon dioxide gas from the high-pressure carbon dioxide cylinder into the connecting frame through the connecting pipe. The carbon dioxide gas is then sprayed out through multiple nozzles on the connecting frame to provide emergency fire extinguishing for the lead-acid batteries on the placement plate, thereby increasing the safety of the device during use. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the structure of this utility model;
[0016] Figure 2 This is a schematic diagram of the structure when the placement plate and the connecting post of this utility model are inserted together;
[0017] Figure 3 This is an enlarged view of the structure at point A of this utility model;
[0018] Figure 4This is a schematic diagram of the rear structure of the placement plate of this utility model;
[0019] Figure 5 This is a bottom view of the placement plate of this utility model.
[0020] In the diagram: 100, base plate; 110, support column; 200, placement plate; 210, connecting column; 220, connector; 230, mounting hole; 240, mounting screw; 250, lock nut; 300, connecting plate; 310, connecting frame; 320, nozzle; 400, connecting pipe; 500, fixing plate; 510, mounting clamp; 520, high-pressure carbon dioxide cylinder; 530, solenoid valve; 600, connecting bracket; 610, spark sensor; 620, microprocessor; 700, connecting rod; 710, alarm light. Detailed Implementation
[0021] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present utility model without creative effort are within the protection scope of the present utility model.
[0022] Please see Figure 1-5 This utility model provides a technical solution for an easy-to-install lead-acid battery energy storage bracket: it includes a base plate 100, a support column 110 fixedly installed on the upper side of the outer wall of the base plate 100, a linearly arranged placement plate 200 provided on the upper end of the outer wall of the support column 110, a connecting column 210 detachably connected between the upper and lower placement plates 200, a connecting plate 300 fixedly installed on the rear end of the upper side of the outer wall of the placement plate 200, a connecting pipe 400 fixedly connected to the connecting plate 300, the front end of the outer wall of the connecting pipe 400 penetrating through the front side of the outer wall of the connecting plate 300 and fixedly connected to a connecting frame 310, and nozzles 320 linearly arranged and fixedly installed on the front side of the outer wall of the connecting frame 310. The device places multiple lead-acid battery blocks through multiple upper and lower connected placement plates 200. The bottom plate 100 has symmetrically fixed connectors 220 on the upper and lower sides and left and right ends of its outer wall. The connecting column 210 is simultaneously inserted into the two connectors 220. The upper and lower ends of the connecting column 210 and the side wall of the connector 220 are provided with through mounting holes 230. Each mounting hole 230 is inserted into the mounting screw 240, and each mounting screw 240 is threaded with a locking nut 250. The device realizes the quick connection between the upper and lower placement plates 200 through the insertion between the connecting column 210 and the connector 220, and fixes the connection between the connector 220 and the connecting column 210 by inserting the mounting screw 240 into the mounting hole 230 and tightening the locking nut 250.
[0023] like Figure 1 , Figure 2 , Figure 4 and Figure 5 As shown, a fixing plate 500 is fixedly installed on the lower side of the outer wall of the placement plate 200. Mounting clamps 510 are linearly arranged and fixedly connected to the lower side of the outer wall of the fixing plate 500. A high-pressure carbon dioxide cylinder 520 is fixedly installed inside the mounting clamps 510. The lower end of the outer wall of the connecting pipe 400 is fixedly connected to the output end of the high-pressure carbon dioxide cylinder 520. A solenoid valve 530 is fixedly installed on the connecting pipe 400. A connecting bracket 600 is fixedly connected to the upper left end of the outer wall of the placement plate 200. A spark sensor 610 is fixedly installed on the upper end of the outer wall of the connecting bracket 600. A microprocessor 62 is fixedly connected to the upper right end of the outer wall of the placement plate 200. Both the solenoid valve 530 and the spark sensor 610 are electrically connected to the microprocessor 620. The spark sensor 610 monitors the lead-acid batteries placed on the placement plate 200. When a lead-acid battery on the placement plate 200 spontaneously combusts, the spark sensor 610 sends a monitoring signal back to the microprocessor 620. The microprocessor 620 then opens the solenoid valve 530 to introduce carbon dioxide gas from the high-pressure carbon dioxide cylinder 520 into the connecting frame 310 through the connecting pipe 400, and sprays the carbon dioxide gas through multiple nozzles 320 on the connecting frame 310. Simultaneously, when the spark sensor 610 detects spontaneous combustion of a lead-acid battery on the placement plate 200, the microprocessor 620 activates the alarm light 710 to alert nearby personnel.
[0024] The working principle of this utility model is as follows: In use, the device first achieves a quick connection between the upper and lower placement plates 200 through the insertion of the connecting post 210 and the plug 220. The connection between the plug 220 and the connecting post 210 is fixed by inserting the mounting screw 240 into the mounting hole 230 and tightening the locking nut 250. The device places multiple lead-acid battery blocks through multiple upper and lower connected placement plates 200. The device can monitor the lead-acid batteries placed on the placement plates 200 through the spark sensor 610. When the lead-acid batteries placed on the placement plates 200 spontaneously combust, the spark sensor 610 can feed back the monitoring signal to the microprocessor 620. The microprocessor 620 opens the solenoid valve 530 to input carbon dioxide gas from the high-pressure carbon dioxide cylinder 520 into the connecting frame 310 through the connecting pipe 400, and sprays carbon dioxide gas through multiple nozzles 320 set on the connecting frame 310 to perform emergency fire extinguishing treatment on the lead-acid batteries placed on the placement plates 200.
[0025] The above description is merely a preferred embodiment of this utility model. It should be noted that those skilled in the art can make various improvements and modifications without departing from the principles of this utility model, and these improvements and modifications should also be considered within the scope of protection of this utility model. Structures, devices, and operating methods not specifically described or explained in this utility model are implemented according to conventional methods in the art, unless otherwise specified or limited.
Claims
1. A lead-acid battery energy storage bracket that is easy to install, comprising a base plate (100), characterized in that: A support column (110) is fixedly installed on the upper side of the outer wall of the base plate (100). A linearly arranged placement plate (200) is provided on the upper end of the outer wall of the support column (110). A connecting column (210) is detachably connected between the upper and lower placement plates (200). A connecting plate (300) is fixedly installed on the rear end of the upper side of the outer wall of the placement plate (200). A connecting pipe (400) is fixedly connected to the connecting plate (300). The front end of the outer wall of the connecting pipe (400) penetrates the front side of the outer wall of the connecting plate (300) and is fixedly connected to a connecting frame (310). A nozzle (320) is fixedly installed linearly on the front side of the outer wall of the connecting frame (310).
2. The easily installable lead-acid battery energy storage bracket according to claim 1, characterized in that, The bottom plate (100) has symmetrically fixed plugs (220) on the upper and lower sides of the outer wall, and the connecting column (210) is simultaneously plugged into the two plugs (220).
3. The easily installable lead-acid battery energy storage bracket according to claim 2, characterized in that, The upper and lower ends of the connecting column (210) and the side wall of the plug (220) are provided with through mounting holes (230). Each mounting hole (230) is fitted with a mounting screw (240), and each mounting screw (240) is threaded with a locking nut (250).
4. The easily installable lead-acid battery energy storage bracket according to claim 1, characterized in that, A fixing plate (500) is fixedly installed on the lower side of the outer wall of the placement plate (200). A mounting hoop (510) is linearly arranged and fixedly connected on the lower side of the outer wall of the fixing plate (500). A high-pressure carbon dioxide cylinder (520) is fixedly installed inside the mounting hoop (510). The lower end of the outer wall of the connecting pipe (400) is fixedly connected to the output end of the high-pressure carbon dioxide cylinder (520).
5. The easily installable lead-acid battery energy storage bracket according to claim 4, characterized in that, A solenoid valve (530) is fixedly installed on the connecting pipe (400). A connecting frame (600) is fixedly connected to the upper left end of the outer wall of the placement plate (200). A spark sensor (610) is fixedly installed on the upper end of the outer wall of the connecting frame (600). A microprocessor (620) is fixedly connected to the upper right end of the outer wall of the placement plate (200). The solenoid valve (530) and the spark sensor (610) are both electrically connected to the microprocessor (620).
6. A lead-acid battery energy storage bracket for easy installation according to claim 5, characterized in that, A connecting rod (700) is fixedly installed on the right end of the placement plate (200), and an alarm light (710) is fixedly connected to the upper end of the outer wall of the connecting rod (700). The microprocessor (620) is electrically connected to the alarm light (710).