Energy storage and cold storage device heat preservation shell support frame

Abstract

The utility model relates to the technical field of energy storage, especially to a heat preservation shell support frame of energy storage and cold storage device, provides a heat preservation shell support frame of energy storage and cold storage device can extend the extension plate, increase the support contact area, prevent toppling, increase the stability, a heat preservation shell support frame of energy storage and cold storage device, including have heat preservation shell, temperature insulation base, swivel stand, rotating disc and first electric push rod etc., the heat preservation shell is placed to temperature insulation base upside, a plurality of swivel stands are rotatably connected to temperature insulation base upside, the rotating disc is connected between swivel stand upside, temperature insulation base front rotatably connected with first electric push rod, the utility model discloses when the sliding block moves down, drives the connecting rod to rotate between the sliding block and the extension plate, drives the extension plate to extend outward, makes the gyro wheel rotate, carries out additional support through the extension plate, reaches can extend the extension plate, increase the support contact area, prevent toppling, increase the effect of the stability.

Description

Technical Field

[0001] This utility model relates to the field of energy storage technology, and in particular to a thermal insulation shell support frame for an energy storage and cold storage device. Background Technology

[0002] With the increasing proportion of renewable energy power generation, energy storage technology has become crucial for ensuring the efficient and stable operation of renewable systems. As a type of energy storage equipment, cold storage devices are widely used in building HVAC, cold chain logistics, and other fields. They require more stable and reliable structures to ensure the effective storage and release of cold energy, thus placing higher demands on the stability of their insulation shell support frames.

[0003] Existing support frames mostly adopt a fixed support contact surface design. When the volume and weight of the insulation shell are large, the fixed support area will lead to an increase in the force per unit area, which may cause the shell to tilt. The support area cannot be adjusted according to the actual working conditions.

[0004] Therefore, it is necessary to design a support frame for the insulation shell of an energy storage and cold storage device that can extend the extension plate, increase the support contact area, prevent tipping, and increase stability. Utility Model Content

[0005] To overcome the shortcomings of existing support frames that mostly use fixed support contact surfaces, which can lead to increased stress per unit area when the insulation shell is large and heavy, potentially causing the shell to tip over, and where the support area cannot be adjusted according to actual working conditions, this utility model provides a support frame for the insulation shell of an energy storage and cold storage device that can extend an extension plate to increase the support contact area, prevent tipping, and increase stability.

[0006] The technical solution is as follows: A thermal insulation shell support frame for an energy storage and cold storage device includes a thermal insulation shell, a thermal insulation base, a rotating frame, a rotating disk, a first electric push rod, a sliding frame, a fixing component, and an extension component. The thermal insulation shell is placed on the upper side of the thermal insulation base. Multiple rotating frames are rotatably connected to the thermal insulation base. A rotating disk is connected between the upper sides of the rotating frames. The first electric push rod is rotatably connected to the front of the thermal insulation base. The first electric push rod and the processor are electrically connected via a module. The telescopic end of the first electric push rod is rotatably connected to its adjacent rotating frame. Multiple sliding frames are slidably connected to the thermal insulation base. All sliding frames slide in cooperation with the rotating disk. The sliding frames are provided with fixing components for clamping and fixing the thermal insulation shell. An extension component is provided at the lower part of the thermal insulation base to increase the contact area.

[0007] As a further preferred embodiment, the fixing assembly includes a second electric actuator, a fixing block, a third electric actuator, a slider, and a fourth electric actuator. The upper part of each sliding frame is connected to the second electric actuator, which is electrically connected to the processor via a module. The upper part of each sliding frame is connected to the third electric actuator, which is electrically connected to the processor via a module. Each sliding frame is slidably connected to a slider. The telescopic ends of the third electric actuators are connected to adjacent sliders. The middle part of each slider is connected to the fourth electric actuator, which is electrically connected to the processor via a module. The telescopic ends of each second electric actuator are connected to a fixing block, and the telescopic ends of each fourth electric actuator are also connected to a fixing block.

[0008] As a further preferred option, it also includes thermal insulation pads, with thermal insulation pads connected to the inner side of each fixing block.

[0009] As a further preferred option, the insulation pads are all made of glass fiber reinforced plastic.

[0010] As a further preferred option, the insulation pads are all equipped with anti-slip textures.

[0011] As a further preferred embodiment, it also includes an extension assembly, which includes an extension plate, rollers and connecting rods. Multiple extension plates are slidably connected to the lower part of the heat-insulating base. Rollers are rotatably connected to the bottom of each extension plate, and connecting rods are rotatably connected between each extension plate and the adjacent slider.

[0012] Compared with the prior art, the present invention has the following advantages: 1. When the slider moves downward, the connecting rod rotates between the slider and the extension plate, causing the extension plate to extend outward, so that the roller rotates and provides additional support through the extension plate, thereby achieving the effect of extending the extension plate, increasing the support contact area, preventing tipping, and increasing stability.

[0013] 2. This utility model, by activating the second and fourth electric push rods, drives the fixing block to move inward to clamp the insulation shell, so that the heat insulation pad comes into contact with the insulation shell, achieving the effect of adapting to different clamping needs according to different sizes of the insulation shell, and making it flexible in use.

[0014] 3. This utility model activates the first electric push rod, which drives the rotating frame to rotate, causing the rotating disk to rotate. This causes the sliding frame to move along the rotating disk and move inward synchronously. The insulation shell is clamped and fixed by the fixing block, and the heat insulation pad and heat insulation base prevent the temperature from being conducted outward. This achieves the effect of supporting the insulation shell of the energy storage and cold storage device while preventing the temperature from being conducted outward, thus improving the insulation effect. Attached Figure Description

[0015] Figure 1 This is a three-dimensional structural diagram of the present invention.

[0016] Figure 2 This is a three-dimensional structural diagram of the heat-insulating base and the first electric push rod of this utility model.

[0017] Figure 3 This is a three-dimensional structural diagram of the rotating frame and rotating disk components of this utility model.

[0018] Figure 4 This is a three-dimensional structural diagram of the third electric actuator and fixing block of this utility model.

[0019] Figure 5 This is a three-dimensional structural diagram of the extension plate and connecting rod of this utility model.

[0020] The components are: 1-Insulation shell, 2-Insulation base, 21-Rotating frame, 3-Rotating disk, 4-First electric push rod, 5-Sliding frame, 6-Second electric push rod, 7-Fixing block, 8-Insulation pad, 9-Third electric push rod, 10-Slider, 11-Fourth electric push rod, 12-Extension plate, 13-Roller, 14-Connecting rod. Detailed Implementation

[0021] The technical solutions in the embodiments of this utility model will be clearly and completely described below. Obviously, the described embodiments are only a part of the embodiments of this utility model, and not all of them. Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort are within the protection scope of this utility model.

[0022] A support frame for the insulation shell of an energy storage and cold storage device, such as Figures 1-5 As shown, it includes an insulation shell 1, an insulation base 2, a rotating frame 21, a rotating disk 3, a first electric push rod 4, a sliding frame 5, a fixing component, and an extension component. The insulation shell 1 is placed on the upper side of the insulation base 2. Three rotating frames 21 are rotatably connected to the insulation base 2. The rotating disk 3 is connected between the upper sides of the rotating frames 21. The first electric push rod 4 is rotatably connected to the front of the insulation base 2. The first electric push rod 4 and the processor are electrically connected through a module. The telescopic end of the first electric push rod 4 is rotatably connected to the adjacent rotating frame 21. Three sliding frames 5 are slidably connected to the insulation base 2. The sliding frames 5 are all slidably engaged with the rotating disk 3. The sliding frames 5 are provided with a fixing component. The lower part of the insulation base 2 is provided with an extension component.

[0023] like Figures 2-4As shown, the fixing assembly includes a second electric actuator 6, a fixing block 7, a third electric actuator 9, a slider 10, and a fourth electric actuator 11. The upper part of the sliding frame 5 is connected to the second electric actuator 6, and the second electric actuator 6 and the processor are electrically connected via a module. The upper part of the sliding frame 5 is connected to the third electric actuator 9, and the third electric actuator 9 and the processor are electrically connected via a module. The slider 10 is slidably connected to the sliding frame 5. The telescopic end of the third electric actuator 9 is connected to the adjacent slider 10. The middle part of the slider 10 is connected to the fourth electric actuator 11, and the fourth electric actuator 11 and the processor are electrically connected via a module. The telescopic end of the second electric actuator 6 is connected to the fixing block 7, and the telescopic end of the fourth electric actuator 11 is also connected to the fixing block 7.

[0024] like Figure 4 As shown, it also includes a heat insulation pad 8. The inner side of the fixing block 7 is connected to the heat insulation pad 8. The heat insulation pad 8 is made of glass fiber reinforced plastic, which is convenient for heat insulation. The heat insulation pad 8 is provided with anti-slip texture.

[0025] like Figure 1 , Figure 2 and Figure 5 As shown, it also includes an extension assembly, which includes an extension plate 12, a roller 13 and a connecting rod 14. Three extension plates 12 are slidably connected to the lower part of the heat insulation base 2. The bottom of each extension plate 12 is rotatably connected to a roller 13. Each extension plate 12 is rotatably connected to an adjacent slider 10 via a connecting rod 14.

[0026] When using this device, first place the insulation base 2 in the storage area of ​​the energy storage and cold storage device, then place the insulation shell 1 of the energy storage and cold storage device on the insulation base 2. Next, activate the third electric actuator 9 to move the slider 10 downwards, which in turn moves the fourth electric actuator 11 downwards. Adjust the distance between the fixing blocks 7 according to the size of the insulation shell 1. Then, activate the first electric actuator 4. The telescopic end of the first electric actuator 4 extends, causing the rotating frame 21 to rotate, which in turn causes the rotating disk 3 to rotate, thus displacing the sliding frame 5 along the rotating disk 3. 5. Move inward synchronously and clamp the insulation shell 1 with the fixing block 7. Prevent the heat from being conducted outward by the heat insulation pad 8 and the heat insulation base 2. This can support the insulation shell 1 of the energy storage and cold storage device while preventing the heat from being conducted outward, thus improving the heat preservation effect. When the size of the insulation shell 1 is small, the second electric push rod 6 and the fourth electric push rod 11 can be activated to drive the fixing block 7 to move inward to clamp the insulation shell 1, so that the heat insulation pad contacts the insulation shell 1. This can adapt to different clamping requirements according to different sizes of the insulation shell 1, making it flexible to use.

[0027] When the slider 10 moves downward, it drives the connecting rod 14 to rotate between the slider 10 and the extension plate 12, causing the extension plate 12 to extend outward, so that the roller 13 rotates and provides additional support through the extension plate 12, thereby extending the extension plate 12, increasing the support contact area, preventing tipping, and increasing stability.

[0028] The technical principles of the present invention have been described above with reference to specific embodiments. These descriptions are merely for explaining the principles of the present invention and should not be construed as limiting the scope of protection of the present invention in any way. Based on this explanation, those skilled in the art can conceive of other specific embodiments of the present invention without creative effort, and these embodiments will all fall within the scope of protection of the present invention.

Claims

1. A thermal insulation shell support frame for an energy storage and cold storage device, characterized in that: The device includes an insulation shell (1), an insulation base (2), a rotating frame (21), a rotating disk (3), a first electric push rod (4), a sliding frame (5), a fixing component, and an extension component. The insulation shell (1) is placed on the upper side of the insulation base (2). Multiple rotating frames (21) are rotatably connected to the insulation base (2). A rotating disk (3) is connected between the upper sides of the rotating frames (21). The first electric push rod (4) is rotatably connected to the front of the insulation base (2). The first electric push rod (4) and the processor are electrically connected through a module. The telescopic end of the first electric push rod (4) is rotatably connected to the adjacent rotating frame (21). Multiple sliding frames (5) are slidably connected to the insulation base (2). All sliding frames (5) are slidably engaged with the rotating disk (3). A fixing component is provided on the sliding frame (5) to clamp and fix the insulation shell (1). An extension component is provided at the lower part of the insulation base (2) to increase the contact area.

2. The insulation shell support frame for an energy storage and cold storage device as described in claim 1, characterized in that: The fixing components include a second electric push rod (6), a fixing block (7), a third electric push rod (9), a slider (10), and a fourth electric push rod (11). The upper part of the sliding frame (5) is connected to the second electric push rod (6). The second electric push rod (6) and the processor are electrically connected through a module. The upper part of the sliding frame (5) is connected to the third electric push rod (9). The third electric push rod (9) and the processor are electrically connected through a module. The slider (10) is slidably connected to the sliding frame (5). The telescopic end of the third electric push rod (9) is connected to the adjacent slider (10). The middle part of the slider (10) is connected to the fourth electric push rod (11). The fourth electric push rod (11) and the processor are electrically connected through a module. The telescopic end of the second electric push rod (6) is connected to the fixing block (7). The telescopic end of the fourth electric push rod (11) is also connected to the fixing block (7).

3. The insulation shell support frame for an energy storage and cold storage device as described in claim 1, characterized in that: It also includes a heat insulation pad (8), and the inner side of the fixing block (7) is connected with a heat insulation pad (8).

4. The insulation shell support frame for an energy storage and cold storage device as described in claim 3, characterized in that: All thermal insulation pads (8) are made of glass fiber reinforced plastic.

5. The thermal insulation shell support frame for an energy storage and cold storage device as described in claim 3, characterized in that: All the heat insulation pads (8) have anti-slip textures.

6. The insulation shell support frame for an energy storage and cold storage device as described in claim 1, characterized in that: It also includes an extension assembly, which includes an extension plate (12), a roller (13) and a connecting rod (14). Multiple extension plates (12) are slidably connected to the lower part of the heat insulation base (2). The bottom of each extension plate (12) is rotatably connected to a roller (13). Each extension plate (12) is rotatably connected to an adjacent slider (10) by a connecting rod (14).

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