A temperature control assembly for intelligently regulating the reaction rate of lithium iron phosphate battery material
By introducing structures such as hollow blocks, protective plates, and storage springs into the temperature control component, the problem of accidental triggering of the temperature controller button has been solved, achieving higher safety and stability, and improving battery safety and component durability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGSU OLITER ENERGY TECH CO LTD
- Filing Date
- 2025-07-15
- Publication Date
- 2026-06-09
AI Technical Summary
In existing temperature control components for adjustable lithium iron phosphate battery material reaction rates, the control buttons of the temperature controller are exposed and easily triggered by external impacts, affecting normal operation and potentially damaging the battery, or even causing safety accidents.
A temperature control component for intelligently regulating the reaction rate of lithium iron phosphate battery materials was designed. Through a combination structure of hollow block, protective plate, energy storage spring and snap-fit block, the temperature controller button is automatically blocked and fixed to prevent accidental triggering by external force.
It improves the safety and stability of the temperature control component, prevents accidental button triggering, enhances battery safety and component durability, and extends service life.
Smart Images

Figure CN224343545U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of battery thermal management technology, and in particular to a temperature control component for intelligently regulating the reaction rate of lithium iron phosphate battery materials. Background Technology
[0002] A temperature control unit is a collection of components that realize the function of temperature control. The temperature controller is its core component, which consists of a temperature sensor, a control chip, and an actuator. It controls the start and stop of heating or cooling equipment by sensing temperature signals, thereby regulating the temperature.
[0003] Regarding the above and existing related technologies, the inventors believe that the following defects often exist: Existing temperature control components that can regulate the reaction rate of lithium iron phosphate battery materials usually include a temperature controller. However, during its use, since the control buttons on the temperature controller are directly exposed, they are easily triggered by external impacts. This not only affects the normal operation of the temperature control component, but may also damage the lithium iron phosphate battery in severe cases, or even cause a safety accident. Utility Model Content
[0004] The technical problem to be solved by this utility model is that existing temperature control components for adjusting the reaction rate of lithium iron phosphate battery materials usually contain a temperature controller. However, during use, the temperature controller control button is directly exposed and is easily triggered by external force collisions. This not only affects the normal operation of the temperature control component, but may also damage the lithium iron phosphate battery in severe cases, or even cause safety accidents. Therefore, we propose a temperature control component for intelligently adjusting the reaction rate of lithium iron phosphate battery materials.
[0005] To achieve the above objectives, this application adopts the following technical solution: a temperature control component for intelligently regulating the reaction rate of lithium iron phosphate battery materials, comprising a temperature controller: a hollow block is fixedly connected to one end of the temperature controller, a protective plate is slidably connected inside the hollow block, an adjustment groove is provided at one end of the hollow block, a cavity block is fixedly connected to one end of the protective plate, a U-shaped block is fixedly connected to one end of the hollow block, a snap-fit groove is provided at one end of the U-shaped block, a storage spring is fixedly connected inside the cavity block, and a snap-fit block is fixedly connected to one end of the storage spring.
[0006] Preferably, the surface of the snap-fit block is slidably connected to the interior of the snap-fit groove, and the external shape of the snap-fit block matches the internal shape of the snap-fit groove.
[0007] Preferably, the cavity block has sliding grooves on both sides of its inner cavity, and the snap-fit block has sliders fixedly connected to both sides of its inner cavity, with the surface of the sliders slidably connected to the inside of the sliding grooves.
[0008] Preferably, the protective plate is made of a high-strength wear-resistant alloy material.
[0009] Preferably, limit grooves are provided on both sides of the inner cavity of the hollow block, and limit blocks are fixedly connected to both sides of the protective plate, with the surface of the limit block slidingly connected to the inside of the limit groove.
[0010] Preferably, the bottom of the protective plate is fixedly connected to a plurality of tension springs, and the bottom of the tension springs is fixedly connected to the bottom of the inner cavity of the hollow block.
[0011] The technical effects and advantages of this utility model are as follows:
[0012] In this invention, the operator pulls the cavity block upwards, causing the cavity block to slide the protective plate inside the hollow block until it completely blocks the control button at one end of the temperature controller. Then, through the cooperation of the storage spring and the snap-fit block, the snap-fit block can be inserted into the snap-fit groove to fix the position of the protective plate, thereby preventing the button from being accidentally triggered by external force collisions and further improving the safety and stability of the temperature control component. Attached Figure Description
[0013] The disclosure of this utility model is illustrated with reference to the accompanying drawings. It should be understood that the drawings are for illustrative purposes only and are not intended to limit the scope of protection of this utility model. In the drawings, the same reference numerals are used to refer to the same parts:
[0014] Figure 1 This is a schematic diagram of the main structure of this utility model;
[0015] Figure 2 This is a partial structural diagram of the temperature controller of this utility model;
[0016] Figure 3 This is a partial structural diagram of the hollow block of this utility model;
[0017] Figure 4 This is a partial structural diagram of the protective plate of this utility model.
[0018] Figure 5 This is a schematic diagram of the cavity block disassembly structure of this utility model.
[0019] Legend: 1. Temperature controller; 2. Hollow block; 3. Protective plate; 4. Adjustment groove; 5. U-shaped block; 6. Snap-fit groove; 7. Cavity block; 8. Storage spring; 9. Snap-fit block; 10. Slide groove; 11. Slider; 12. Limit groove; 13. Limit block; 14. Tension spring. Detailed Implementation
[0020] It is readily understood that, based on the technical solution of this utility model, those skilled in the art can propose various interchangeable structural methods and implementation methods without changing the essential spirit of this utility model. Therefore, the following specific embodiments and accompanying drawings are merely exemplary descriptions of the technical solution of this utility model, and should not be regarded as the entirety of this utility model or as a limitation or restriction on the technical solution of this utility model.
[0021] Reference Figures 1-5 As shown, this utility model provides a technical solution: a temperature control component for intelligently regulating the reaction rate of lithium iron phosphate battery materials, including a temperature controller 1: a hollow block 2 is fixedly connected to one end of the temperature controller 1, a protective plate 3 is slidably connected inside the hollow block 2, an adjustment groove 4 is opened at one end of the hollow block 2, a cavity block 7 is fixedly connected to one end of the protective plate 3, a U-shaped block 5 is fixedly connected to one end of the hollow block 2, a snap-fit groove 6 is opened at one end of the U-shaped block 5, a storage spring 8 is fixedly connected inside the cavity block 7, and a snap-fit block 9 is fixedly connected to one end of the storage spring 8. When the operator pulls the cavity block 7 upward, the cavity block 7 causes the protective plate 3 to slide inside the hollow block 2 until the control button at one end of the temperature controller 1 is completely blocked. Through the cooperation of the storage spring 8 and the snap-fit block 9, the snap-fit block 9 can be inserted into the snap-fit groove 6 to fix the position of the protective plate 3, thereby preventing accidental button triggering caused by external force collision, and further improving the safety and stability of the temperature control component.
[0022] Reference Figure 3 and Figure 4 As shown in this embodiment: the surface of the snap-fit block 9 is slidably connected to the inside of the snap-fit groove 6, and the external shape of the snap-fit block 9 matches the internal shape of the snap-fit groove 6. Because the external shape of the snap-fit block 9 matches the internal shape of the snap-fit groove 6, the snap-fit block 9 can be smoothly and firmly inserted into the snap-fit groove 6, ensuring the stability of the protective plate 3 in a fixed position. When an external force is applied to the protective plate 3, the tight fit between the snap-fit block 9 and the snap-fit groove 6 can effectively prevent the protective plate 3 from moving accidentally.
[0023] Reference Figure 5 As shown in this embodiment: Slide grooves 10 are provided on both sides of the inner cavity of the cavity block 7, and sliders 11 are fixedly connected to both sides of the snap-fit block 9. The surface of the slider 11 is slidably connected to the inside of the slide groove 10. By setting the slide groove 10 and the slider 11 to cooperate, the movement trajectory of the snap-fit block 9 can be limited, preventing the snap-fit block 9 from deviating during movement. At the same time, it avoids the problem that the snap-fit block 9 cannot accurately snap into the snap-fit groove 6, further improving the stability of the protective plate 3, thereby increasing the effectiveness of the temperature controller 1.
[0024] Reference Figure 1As shown in this embodiment, the protective plate 3 is made of high-strength wear-resistant alloy material. The use of this high-strength wear-resistant alloy material significantly improves the durability and wear resistance of the protective plate 3. During long-term use, even when facing frequent friction and collision, the protective plate 3 can maintain its structural integrity and functionality.
[0025] Reference Figure 3 and Figure 4 As shown in this embodiment: Limiting grooves 12 are provided on both sides of the inner cavity of the hollow block 2, and limiting blocks 13 are fixedly connected to both sides of the protective plate 3. The surface of the limiting block 13 is slidably connected to the inside of the limiting groove 12. By setting the limiting groove 12 and the limiting block 13 to work together, the movement direction of the protective plate 3 can be constrained, ensuring that the protective plate 3 can move smoothly along the predetermined trajectory when it is opened or closed, avoiding the situation of the protective plate 3 shaking or misaligning during the movement, thereby enhancing the overall stability and service life of the thermostat 1.
[0026] Reference Figure 4 As shown in this embodiment: multiple tension springs 14 are fixedly connected to the bottom of the protective plate 3. The bottom of the tension springs 14 is fixedly connected to the bottom of the inner cavity of the hollow block 2. When the protective plate 3 is released from its fixed position, the tension springs 14 can pull the protective plate 3 downwards through their own tension, so that the protective plate 3 can be quickly stored back into the interior of the hollow block 2, making it easier for staff to operate the buttons more quickly.
[0027] Working principle: By pulling the cavity block 7 upwards, the operator causes the protective plate 3 to slide inside the hollow block 2 until it completely blocks the control button at one end of the thermostat 1. Then, through the cooperation of the storage spring 8 and the locking block 9, the locking block 9 is inserted into the locking groove 6, fixing the position of the protective plate 3 and preventing accidental button triggering due to external impact. This further improves the safety and stability of the temperature control component. Because the external shape of the locking block 9 matches the internal shape of the locking groove 6, it can smoothly and firmly insert into the groove 6, ensuring the stability of the protective plate 3 in its fixed position. When external force is applied to the protective plate 3, the tight fit between the locking block 9 and the locking groove 6 effectively prevents accidental movement of the protective plate 3. The cooperation of the sliding groove 10 and the slider 11 limits the movement trajectory of the locking block 9, preventing it from shifting during movement. This avoids the problem of the snap-fit block 9 failing to accurately snap into the snap-fit groove 6, further improving the stability of the protective plate 3 and thus increasing the effectiveness of the thermostat 1. The use of this high-strength wear-resistant alloy material significantly improves the durability and wear resistance of the protective plate 3. During long-term use, even in the face of frequent friction and collision, the protective plate 3 can maintain its structural integrity and functionality. By setting the limit groove 12 and the limit block 13 in cooperation, the movement direction of the protective plate 3 can be constrained, ensuring that the protective plate 3 can move smoothly along the predetermined trajectory when opening or closing, avoiding the protective plate 3 from shaking or misaligning during movement, thereby enhancing the overall stability and service life of the thermostat 1. When the protective plate 3 is released from its fixed position, the tension spring 14 can pull the protective plate 3 downwards through its own tension, allowing the protective plate 3 to quickly retract into the hollow block 2, making it easier for the staff to operate the buttons more quickly.
[0028] The technical scope of this utility model is not limited to the content described above. Those skilled in the art can make various modifications and variations to the above embodiments without departing from the technical concept of this utility model, and all such modifications and variations should fall within the protection scope of this utility model.
Claims
1. A temperature control component for intelligently regulating the reaction rate of lithium iron phosphate battery materials, characterized in that, Includes a thermostat (1): a hollow block (2) is fixedly connected to one end of the thermostat (1), a protective plate (3) is slidably connected inside the hollow block (2), an adjustment groove (4) is opened at one end of the hollow block (2), a cavity block (7) is fixedly connected to one end of the protective plate (3), a U-shaped block (5) is fixedly connected to one end of the hollow block (2), a snap-fit groove (6) is opened at one end of the U-shaped block (5), a storage spring (8) is fixedly connected inside the cavity block (7), and a snap-fit block (9) is fixedly connected to one end of the storage spring (8).
2. The temperature control component for intelligently regulating the reaction rate of lithium iron phosphate battery materials according to claim 1, characterized in that: The surface of the snap-fit block (9) is slidably connected to the inside of the snap-fit groove (6), and the external shape of the snap-fit block (9) matches the internal shape of the snap-fit groove (6).
3. The temperature control component for intelligently regulating the reaction rate of lithium iron phosphate battery materials according to claim 1, characterized in that: The cavity block (7) has sliding grooves (10) on both sides of its inner cavity, and the snap-fit block (9) has sliders (11) fixedly connected to both sides of its inner cavity. The surface of the sliders (11) is slidably connected to the inside of the sliding grooves (10).
4. The temperature control component for intelligently regulating the reaction rate of lithium iron phosphate battery materials according to claim 1, characterized in that: The protective plate (3) is made of high-strength wear-resistant alloy material.
5. The temperature control component for intelligently regulating the reaction rate of lithium iron phosphate battery materials according to claim 1, characterized in that: The hollow block (2) has a limiting groove (12) on both sides of its inner cavity, and the protective plate (3) has a limiting block (13) fixedly connected to both sides. The surface of the limiting block (13) is slidably connected to the inside of the limiting groove (12).
6. The temperature control component for intelligently regulating the reaction rate of lithium iron phosphate battery materials according to claim 1, characterized in that: The bottom of the protective plate (3) is fixedly connected to a plurality of tension springs (14), and the bottom of the tension springs (14) is fixedly connected to the bottom of the inner cavity of the hollow block (2).