CN116598829B - Pollution-free energy storage device - Google Patents

Abstract

The application relates to a pollution-free energy storage device, which relates to the technical field of energy storage devices, and comprises an energy storage box and an energy storage power supply arranged in the energy storage box, wherein a top cover is arranged on the energy storage box, an input wiring terminal and an output wiring terminal are arranged on the top cover, a protective sleeve is arranged on the top cover, the protective sleeve is positioned at the outer sides of the input wiring terminal and the output wiring terminal, a chassis is arranged in the protective sleeve, a disc is arranged on the chassis, a through hole for the input wiring terminal to pass through is arranged at the central position of the disc, a strip-shaped groove is arranged at the edge of the disc, the strip-shaped groove is arranged around the central axis of the disc at equal angles, a sliding block is arranged in the strip-shaped groove of the disc in a sliding manner, a sealing block is arranged on the sliding block, a rotating block is arranged in the through hole communicated with the through hole is arranged in the through hole, a rotary drum is arranged between the rotating block and the chassis, and a clockwork spring is arranged at the outer side of the rotary drum. The pollution-free energy storage device has the function of pollution-free protection of the input wiring terminal and the output wiring terminal.

Description

Pollution-free energy storage device

Technical Field

The application relates to the technical field of energy storage devices, in particular to a pollution-free energy storage device.

Background

Energy storage means refers to the process of storing energy by means of a medium or device and releasing it when needed. The energy storage mainly refers to the storage of electric energy, and comprises pumping energy storage belonging to hydropower, flywheel energy storage belonging to wind power and the like; a power battery, a lead-acid battery, a lithium ion battery and the like which belong to the new energy industry; electromagnetic energy storage, such as super capacitor, superconductive energy storage, etc., belongs to the power equipment industry.

At present, the energy storage device is provided with an input wiring terminal and an output wiring terminal, however, the input wiring terminal and the output wiring terminal are exposed outside and are easy to be corroded by oxygen, humidity and other chemical substances, so that the phenomenon of leakage of the energy storage device is caused, and pollution-free protection is difficult to realize.

Disclosure of Invention

The application provides a pollution-free energy storage device which has the function of pollution-free protection of an input wiring terminal and an output wiring terminal.

The application provides a pollution-free energy storage device, which adopts the following technical scheme:

the utility model provides a pollution-free energy storage device, includes the energy storage case and locates the energy storage power supply in the energy storage case, be equipped with the top cap on the energy storage case, be equipped with input binding post and output binding post on the top cap, be equipped with the protective sleeve on the top cap, the protective sleeve is located the outside of input binding post and output binding post, the inside of protective sleeve is equipped with the chassis, be equipped with the disc on the chassis, be equipped with the through-hole that supplies the input binding post to pass on the central point of disc, the edge of disc is equipped with the bar groove, the bar groove sets up around the central axis equi-angle of disc, the bar inslot slip of disc is equipped with the slider, be equipped with the sealing block on the slider, be equipped with the commentaries on classics piece in the through-hole of disc, be equipped with the rotary drum between commentaries on classics piece and the chassis, the outside of rotary drum is equipped with the clockwork spring, the one end of clockwork spring is connected to change the piece, be equipped with the connecting rod between commentaries on classics piece and the slider, rotate between connecting rod and the slider and a plurality of sealing block in the sealing block form a plurality of sealing member in the sealing sleeve.

Through adopting above-mentioned technical scheme, through the sealing member that a plurality of sealing block formed in the protective sleeve, can effectually play sealed protective sleeve's effect, thereby play the effect of protection input binding post and output binding post, in addition, when external terminal needs connection input binding post and output binding post, pass protective sleeve with external terminal, make sealing block promote the slider, and move towards the outside of bar groove, and the interlock takes place for the connecting rod, at this moment, take place to rotate between rotor and the chassis, in this process, the surface of external terminal is laminated all the time to the inner wall of sealing block, in addition when input binding post and output binding post break away from external terminal, under the effect of clockwork spring, make the rotor reset and rotate, thereby make sealing block inwards move, utilize the sealing member that a plurality of sealing block constitutes, realize the effect sealed to protective sleeve, can effectually avoid input binding post and output binding post to expose in the air, receive the corruption of oxygen, humidity and other chemicals, thereby can effectually avoid leaking liquid, realize pollution-free protection.

Preferably, the inner surface of the sealing block is provided with a special-shaped inclined surface, the special-shaped inclined surface comprises a first straight section and a second straight section, a guide surface is arranged in front of the first straight section and the second straight section, and the guide surface is inclined downwards.

Through adopting above-mentioned technical scheme, special-shaped inclined plane can guide external terminal correctly insert the sealing block, makes its alignment and inserts smoothly, can simplify the installation like this, reduces the error, improves installation effectiveness, through the direction of accuracy, external terminal can correctly insert and be connected with input binding post and the output binding post in the sealing block, ensures transmission quality and the reliability of signal of telecommunication or electric energy.

Preferably, a heat dissipation area is formed between the energy storage power supply and the energy storage box, a plurality of protection baffles are arranged in the heat dissipation area of the energy storage box, the bottoms of the protection baffles are connected with the bottoms of the energy storage box, and a plurality of protection baffles form a surrounding guard plate on the outer side of the energy storage power supply.

By adopting the technical scheme, the protective baffle can guide air to flow so that the air flows through the heat dissipation part of the energy storage power supply; through reasonable design and arrangement, the protective baffle can form a proper air channel around the energy storage power supply to guide hot air to flow out, so that the heat dissipation effect is improved; the accumulation of hot gas can cause heat accumulation, so that the heat dissipation effect of the energy storage power supply is affected; the protective baffle can enhance the working efficiency of the heat dissipation system and improve the heat dissipation effect by guiding the air flow and preventing the hot air from accumulating, thereby reducing the temperature of the energy storage power supply and keeping the energy storage power supply to run in a safe temperature range; the protective baffle can also play a role in protecting the energy storage power supply; the protective baffle plates are arranged around the energy storage power supply, so that external sundries, liquid or other substances can be prevented from entering the heat dissipation part of the energy storage power supply, and damage or faults to other electronic elements are avoided.

Preferably, the outside of the protective baffle is provided with a cooling cover, the cooling cover comprises a plurality of annular bulges, a plurality of heat insulation nets are arranged between the annular bulges, and the heat insulation nets are fixedly connected with the annular bulges.

By adopting the technical scheme, the annular bulge can change the direction and speed of air flow, and form turbulence and vortex phenomena. The turbulence and the vortex can enhance the heat exchange between the air and the surface of the radiator, and increase the heat conduction and the heat dissipation effect; the heat insulation net can play a role in heat insulation, and heat conduction between adjacent bulges is prevented; this helps to prevent heat transfer between the protrusions, thereby reducing heat loss and improving heat dissipation efficiency; and the adjacent bulges are connected through the heat insulation net, so that heat can be dispersed to more areas; the heat insulation net can transfer heat from one protrusion to the other protrusion, so that a heat transmission path is increased, hot spots are reduced, and the overall heat dissipation uniformity is improved; in addition, the presence of the insulating mesh can alter the path and velocity of the air flow, promoting the formation of turbulence and eddies. This helps to enhance the heat exchange between the air and the raised surface.

Preferably, a plurality of cooling struts are arranged between the inner surface of the annular bulge and the outer wall of the protective baffle, and the cooling struts are uniformly distributed along the inner surface of the annular bulge.

By adopting the technical scheme, the cooling support column can provide more heat conduction paths so as to promote heat conduction between the annular bulge and the protective baffle; this helps to transfer heat efficiently from the inner surface to the outer wall, increases the heat dissipation rate and efficiency of the heat, and the presence of cooling struts can alter the path and speed of air flow creating turbulence and vortex phenomena; this helps to enhance the heat exchange between the air and the cooling strut surface, improving the convective heat dissipation effect.

Preferably, the bottom of cooling cover is equipped with the injection condenser that is used for spraying the condensation gas, the inside at the energy storage case is fixed to the injection condenser, the output of injection condenser is connected with the output tube, the injection condenser is connected to the one end of output tube, the other end of output tube is equipped with the annular pipe, the upper surface of annular pipe is equipped with a plurality of outlet duct, the gas outlet of outlet duct is located the internal surface of cooling cover.

By adopting the technical scheme, the spray condenser can provide a high-efficiency cooling effect; by the jet cooler, cooling air is jetted to the inner surface of the cooling cover at a high speed, a powerful cooling effect is provided, and the temperature of the energy storage power supply is rapidly reduced.

Preferably, the top of cooling cover is equipped with the opening, the opening part of cooling cover is equipped with first arc baffle ring, the upside of first arc baffle ring is equipped with the second arc baffle ring, form the conversion passageway between first arc baffle ring and the second arc baffle ring, be equipped with gas inlet and gas outlet on the conversion passageway, the gas inlet is located the internal surface of cooling cover, the gas outlet is located the surface of cooling cover.

Through adopting above-mentioned technical scheme, utilize the conversion passageway that forms between first arc baffle ring and the second arc baffle ring, can effectually lead the air current after the heat exchange to the outside of cooling cover.

Preferably, a corrugated cover is arranged on the outer side of the cooling cover, and the inner surface and the outer surface of the corrugated cover are both corrugated structures.

By adopting the technical scheme, the corrugated structure of the corrugated cover can change the path and speed of air flow, and form turbulence and vortex phenomena. This helps to enhance the heat exchange between the air and the bellows surface, improving the convective heat dissipation; and the corrugated structure of the corrugated cover can disperse heat to more areas, so that heat is prevented from being concentrated on a certain part. The heat dissipation device is beneficial to improving the overall heat dissipation uniformity, reducing the generation of hot spots and keeping the temperature of the energy storage power supply within a safe range; in addition, the corrugated structure of the corrugated cover can increase the strength and rigidity of the structure and improve the shock resistance and vibration resistance of the energy storage power supply. Therefore, structural deformation or damage caused by external environment or vibration can be reduced, the safety and stability of the energy storage power supply are protected, and the corrugated structure of the corrugated cover can reduce noise during air flow. Because the corrugated structure of the corrugated cover can change the path and speed of air flow, turbulence and vortex noise during air flow are reduced, and the noise level during the operation of the energy storage power supply is reduced.

Preferably, the inside of ripple cover just is close to its bottom and is equipped with a plurality of louvre, be equipped with the heat dissipation chamber between the lateral wall of ripple cover and the inside wall of energy storage case, communicate each other between heat dissipation chamber and the louvre.

Through adopting above-mentioned technical scheme, the cooling air after the heat exchange passes from the louvre of ripple cover bottom, can increase the air velocity of flow for thermal dissipation and take away the speed, reinforcing radiating effect.

Preferably, the energy storage box is provided with a heat dissipation port, and the heat dissipation port is communicated with the heat dissipation cavity.

By adopting the technical scheme, the energy storage power supply in the energy storage box can generate heat in the working process, and the heat can be emitted from the interior of the energy storage box through the heat radiation opening; therefore, the working temperature of the energy storage box can be effectively reduced, and the performance of the energy storage power supply is prevented from being reduced or damaged due to overheating.

In summary, the application has the following beneficial effects:

1. the sealing piece formed in the protective sleeve through the sealing blocks can effectively play a role in sealing the protective sleeve, so that the protective sleeve can protect the input wiring terminal and the output wiring terminal, in addition, when the external wiring terminal needs to be connected with the input wiring terminal and the output wiring terminal, the external wiring terminal passes through the protective sleeve, the sealing blocks push the sliding blocks and move towards the outer sides of the strip-shaped grooves, and are linked with the connecting rods, at the moment, the rotating blocks and the chassis rotate, the inner walls of the sealing blocks always attach to the surfaces of the external wiring terminal, in addition, when the input wiring terminal and the output wiring terminal are separated from the external wiring terminal, the rotating blocks are reset and rotate under the action of the spring, so that the sealing blocks move inwards, the sealing piece formed by the sealing blocks is utilized, the protective sleeve is sealed, the input wiring terminal and the output wiring terminal can be effectively prevented from being exposed in the air and being corroded by oxygen, humidity and other chemical substances, and pollution-free protection can be realized.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the application. Also, like reference numerals are used to designate like parts throughout the figures. In the drawings:

FIG. 1 is a schematic diagram of the whole structure of a pollution-free energy storage device in the present embodiment;

fig. 2 is a schematic diagram of the overall structure of the energy storage tank in the present embodiment;

FIG. 3 is a schematic view of an exploded structure between a disc and a seal block in the present embodiment;

FIG. 4 is a schematic view showing the internal structure of the profiled inclined plane in the present embodiment;

FIG. 5 is a schematic diagram of an exploded structure between the energy storage power supply and the energy storage tank in this embodiment;

FIG. 6 is a schematic view showing the overall structure of the cooling cover in the present embodiment;

FIG. 7 is a schematic view showing a connection structure between the annular protrusion and the cooling tower in the present embodiment;

FIG. 8 is a schematic view showing the overall structure of the annular projection in the present embodiment;

FIG. 9 is an enlarged schematic view of the structure of FIG. 8A in the present embodiment;

FIG. 10 is a schematic view of an explosive structure between the protective sleeve and the seal block in the present embodiment;

reference numerals illustrate: 1. an energy storage tank; 2. an energy storage power supply; 3. a top cover; 4. an input terminal; 5. an output connection terminal; 6. a protective sleeve; 7. a chassis; 8. a disc; 9. a through hole; 10. a bar-shaped groove; 11. a slide block; 12. a sealing block; 13. a rotating block; 14. a through hole; 15. a rotating drum; 16. a clockwork spring; 17. a connecting rod; 18. a special-shaped inclined plane; 1801. a first straight section; 1802. a guide surface; 1803. a second straight section; 19. a protective baffle; 20. a cooling cover; 2001. an annular protrusion; 2002. a thermal insulation screen; 21. a cooling strut; 22. a spray condenser; 23. an output pipe; 24. an annular tube; 25. an air outlet pipe; 26. a first arc-shaped baffle ring; 27. a second arc-shaped baffle ring; 28. a corrugated cover; 29. and a heat radiation port.

Detailed Description

The present application will be described in further detail with reference to the accompanying drawings, wherein it is to be understood that the following detailed description is for the purpose of further illustrating the application only and is not to be construed as limiting the scope of the application, as various insubstantial modifications and adaptations of the application to those skilled in the art can be made in light of the foregoing disclosure.

The application discloses a pollution-free energy storage device, as shown in figures 1, 2, 3 and 10, which comprises a radiator, an energy storage box 1 and an energy storage power supply 2 arranged in the energy storage box 1, wherein an internal control unit of the radiator is arranged at the bottom of the energy storage box 1, radiating fins in the radiator are arranged on the surface of the energy storage box 1 and penetrate through the surface of the energy storage box 1 and are used for integrally radiating the energy storage box 1, a top cover 3 is arranged on the energy storage box 1, an input wiring terminal 4 and an output wiring terminal 5 are arranged on the top cover 3, a protective sleeve 6 is arranged on the top cover 3, the protective sleeve 6 is positioned at the outer side of the input wiring terminal 4 and the output wiring terminal 5, a chassis 7 is arranged in the protective sleeve 6, a disc 8 is arranged on the chassis 7, a through hole 9 for the input wiring terminal 4 to penetrate through is arranged at the central position of the disc 8, a strip groove 10 is arranged at the edge of the disc 8, a strip groove 10 is arranged around the central axis of the disc 8 at equal angle, a sliding block 11 is arranged in the strip groove 10, a sealing block 12 is arranged on the sliding block 11, a rotating block 13 is arranged in the through hole 9 of the disc 8, a rotating block 13 is arranged in the through hole 9 of the disc 13, the rotating block 13 is arranged at the central position of the rotating block 9, an input wiring terminal 4 is arranged at the same time, an input wiring terminal 4 is arranged at the central position of the disc 4, an input wiring terminal 4 is communicated with the output wiring terminal 4 through a connecting rod 11, a connecting spring 11 and a plurality of the rotating spring 13 and a connecting rod and a sealing spring 13 is arranged at the other end, and the rotating block 13 is arranged at the central position is connected with the rotating rod and the rotating rod 13; the sealing piece formed in the protective sleeve 6 through the plurality of sealing blocks 12 can effectively play a role in sealing the protective sleeve 6, thereby play a role in protecting the input wiring terminal 4 and the output wiring terminal 5, in addition, when the external connection terminal needs to be connected with the input wiring terminal 4 and the output wiring terminal 5, the external connection terminal passes through the protective sleeve 6, the sealing block 12 pushes the sliding block 11 and moves towards the outer side of the strip-shaped groove 10, and the connecting rod 17 is linked, at the moment, the rotating block 13 rotates with the chassis 7, in the process, the inner wall of the sealing block 12 always contacts with the surface of the external connection terminal, in addition, when the input wiring terminal 4 and the output wiring terminal 5 are separated from the external connection terminal, the rotating block 13 is reset to rotate under the action of the spring 16, so that the sealing block 12 moves inwards, the sealing piece formed by the plurality of sealing blocks 12 is utilized, the sealing effect on the protective sleeve 6 is realized, the input wiring terminal 4 and the output wiring terminal 5 can be effectively prevented from being exposed in the air and being corroded by oxygen, humidity and other chemical substances, and pollution-free protection can be realized.

As shown in fig. 4, the inner surface of the sealing block 12 is provided with a special-shaped inclined surface 18, the special-shaped inclined surface 18 comprises a first straight section 1801 and a second straight section 1803, a guide surface 1802 is arranged in front of the first straight section 1801 and the second straight section 1803, and the guide surface 1802 is inclined downwards; the special-shaped inclined surface 18 can guide the external terminal to be correctly inserted into the sealing block 12 so as to lead the external terminal to be aligned and smoothly inserted, thus simplifying the installation process, reducing errors and improving the installation efficiency, and the external terminal can be correctly inserted into and connected with the input wiring terminal 4 and the output wiring terminal 5 in the sealing block 12 through correct guiding so as to ensure the transmission quality and reliability of electric signals or electric energy; the profiled inclined surface 18 can prevent the external terminal from being erroneously inserted into the sealing block 12 according to a specific shape and angle, which helps to prevent circuit failure or equipment damage caused by erroneous connection; by providing a sealing ring or gasket on the profiled inclined surface 18, the sealing performance between the external terminal and the sealing block 12 can be enhanced, which helps to prevent intrusion of external environmental substances such as moisture, dust, liquid, etc. into the inside of the sealing block 12, protecting the safety and reliability of the internal electrical components.

In general, by providing the inner surface of the sealing block 12 with the profiled bevel 18, better external terminal guidance is provided, increased ease of installation, contact reliability and sealing performance, error insertion and related problems are avoided, and overall product quality and reliability is improved.

As shown in fig. 2 and 5, a heat dissipation area is formed between the energy storage power supply 2 and the energy storage box 1, four protection baffles 19 are arranged in the heat dissipation area of the energy storage box 1, the bottom of each protection baffle 19 is connected with the bottom of the energy storage box 1, and the four protection baffles 19 form a surrounding baffle plate on the outer side of the energy storage power supply 2; the protective baffle 19 can guide air to flow so that the air flows through the heat dissipation part of the energy storage power supply 2; the accumulation of hot gas can cause heat accumulation, and the heat dissipation effect of the energy storage power supply 2 is affected; the protective baffle 19 can enhance the working efficiency of the heat dissipation system and improve the heat dissipation effect by guiding the air flow and preventing the hot air from accumulating, thereby reducing the temperature of the energy storage power supply 2 and keeping the energy storage power supply to operate in a safe temperature range; the protective baffle 19 can also play a role in protecting the internal components of the energy storage power supply 2; the protective baffle 19 is arranged around the energy storage power supply 2, so that foreign matters, liquid or other substances can be prevented from entering the heat dissipation part of the energy storage power supply 2, and damage or faults to other electronic components can be avoided.

As shown in fig. 5 and 6, a cooling cover 20 is arranged on the outer side of the protective baffle 19, the cooling cover 20 comprises a plurality of annular protrusions 2001, a heat insulation net 2002 is arranged between the annular protrusions 2001, and the heat insulation net 2002 is fixedly connected with the annular protrusions 2001; providing more surface to dissipate heat; by increasing the heat radiation surface area, the heat radiation capability can be enhanced, the heat radiation efficiency can be improved, and in addition, the annular projection 2001 can change the direction and speed of the air flow, forming turbulence and vortex phenomenon. The turbulence and the vortex can enhance the heat exchange between the air and the surface of the radiator, and increase the heat conduction and the heat dissipation effect; and the heat insulation net 2002 can play a role of heat insulation, and prevent heat conduction between adjacent bulges; this helps to prevent heat transfer between the protrusions, thereby reducing heat loss and improving heat dissipation efficiency; and adjacent bulges are connected through the heat insulation net 2002, so that heat can be dispersed to more areas; the heat insulation net 2002 can transfer heat from one protrusion to another protrusion, so that a heat transmission path is increased, hot spots are reduced, and the overall heat dissipation uniformity is improved; additionally, the presence of the insulating mesh 2002 may alter the path and velocity of the air flow, promoting the formation of turbulence and eddies. This helps to enhance the heat exchange between the air and the raised surface, improving the convective heat dissipation effect; in addition, the shape of the protrusions can increase the surface area of radiation heat dissipation and promote convection heat dissipation by turbulence and eddy current, thereby enhancing heat dissipation effect, and the annular protrusions 2001 can disperse heat to a larger area, avoiding heat concentration at a certain portion. This helps to improve overall heat dissipation uniformity, reduce the occurrence of hot spots, and keep the temperature of the energy storage power supply 2 within a safe range.

In summary, the longitudinally distributed annular protrusions 2001 can increase the heat dissipation surface area, promote air flow, enhance radiant and convective heat dissipation effects, and evenly distribute heat. These characteristics have a positive effect on the heat dissipation of the energy storage power supply 2, and can effectively reduce the temperature of the energy storage power supply 2, maintain its normal operation and prolong its lifetime.

As shown in fig. 7, a plurality of cooling struts 21 are provided between the inner surface of the annular projection 2001 and the outer wall of the shield plate 19, the cooling struts 21 being uniformly distributed along the inner surface of the annular projection 2001; the cooling struts 21 may provide more heat conduction paths, facilitating heat conduction between the annular protrusion 2001 and the shield plate 19; this helps to transfer heat efficiently from the inner surface to the outer wall, increases the heat dissipation rate and efficiency of the heat, and the presence of the cooling struts 21 can alter the path and speed of air flow, creating turbulence and vortex phenomena; this helps to enhance the heat exchange between the air and the surface of the cooling stay 21, improving the convection heat dissipation effect; and the cooling struts 21 can disperse heat to more areas, avoiding heat concentration in a certain portion. This helps to improve overall heat dissipation uniformity, reduce the generation of hot spots, and keep the temperature of the energy storage power supply 2 or other devices within a safe range.

As shown in fig. 7, the bottom of the cooling cover 20 is provided with a spray condenser 22 for spraying condensed gas, the spray condenser 22 is fixed in the energy storage box 1, the output end of the spray condenser 22 is connected with an output pipe 23, one end of the output pipe 23 is connected with the spray condenser 22, the other end of the output pipe 23 is provided with an annular pipe 24, the upper surface of the annular pipe 24 is provided with a plurality of air outlet pipes 25, and the air outlet of the air outlet pipes 25 are positioned on the inner surface of the cooling cover 20; the ejector condenser 22 can provide an efficient cooling effect; by the jet cooler, the cooling air is jetted to the inner surface of the cooling jacket 20 at a high speed, providing a powerful cooling effect, and rapidly lowering the temperature of the energy storage power source 2.

As shown in fig. 8 and 9, the top of the cooling cover 20 is provided with an opening, the opening of the cooling cover 20 is provided with a first arc baffle ring 26, the upper side of the first arc baffle ring 26 is provided with a second arc baffle ring 27, a current conversion channel is formed between the first arc baffle ring 26 and the second arc baffle ring 27, the current conversion channel is provided with an air inlet and an air outlet, the air inlet is positioned on one side of the inner surface of the cooling cover 20, and the air outlet is positioned on one side of the outer surface of the cooling cover 20; by using the flow exchanging passage formed between the first arc baffle ring 26 and the second arc baffle ring 27, the flow after the heat exchange can be effectively guided to the outside of the cooling jacket 20.

As shown in fig. 5, the outer side of the cooling cover 20 is provided with a corrugated cover 28, and the inner and outer surfaces of the corrugated cover 28 are corrugated; the corrugated structure of the bellows 28 may alter the path and velocity of the air flow creating turbulence and vortex phenomena. This helps to enhance the heat exchange between the air and the surface of the bellows 28, enhancing the convective heat dissipation; and the corrugated structure of the bellows 28 may spread the heat to more areas, avoiding heat concentration in a certain portion. This helps to improve overall heat dissipation uniformity, reduce the generation of hot spots, and keep the temperature of the energy storage power supply 2 within a safe range; in addition, the corrugated structure of the corrugated cover 28 can increase the strength and rigidity of the structure and improve the shock resistance and vibration resistance of the energy storage power supply 2. This reduces structural deformation or damage caused by external environment or vibration, protects the safety and stability of the energy storage power supply 2, and the corrugated structure of the corrugated cover 28 reduces noise when air flows. Because the corrugated structure of the corrugated cover 28 can change the path and speed of the air flow, turbulence and vortex noise during the air flow are reduced, and the noise level during the operation of the energy storage power supply 2 is reduced; a plurality of heat dissipation holes are formed in the corrugated cover 28 and close to the bottom of the corrugated cover, a heat dissipation cavity is formed between the outer side wall of the corrugated cover 28 and the inner side wall of the energy storage box 1, and the heat dissipation cavity and the heat dissipation holes are communicated with each other; the cooling air after heat exchange passes through the radiating holes at the bottom of the corrugated cover 28, so that the air flow rate can be increased, the radiating and taking-away speeds of heat can be accelerated, and the radiating effect can be enhanced; the energy storage box 1 is provided with a heat dissipation port 29, and the heat dissipation port 29 is communicated with the heat dissipation cavity; the energy storage power supply 2 in the energy storage box 1 can generate heat in the working process, and the heat can be emitted from the interior of the energy storage box 1 through the heat radiation opening 29; therefore, the working temperature of the energy storage box 1 can be effectively reduced, and the performance of the energy storage power supply 2 is prevented from being reduced or damaged due to overheating.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (10)

1. The utility model provides a pollution-free energy storage device, includes energy storage case (1) and locates energy storage power supply (2) in energy storage case (1), its characterized in that: the energy storage box (1) is provided with a top cover (3), the top cover (3) is provided with an input wiring terminal (4) and an output wiring terminal (5), the top cover (3) is provided with a protective sleeve (6), the protective sleeve (6) is positioned at the outer side of the input wiring terminal (4) and the output wiring terminal (5), the inside of the protective sleeve (6) is provided with a chassis (7), the chassis (7) is provided with a disc (8), the central position of the disc (8) is provided with a through hole (9) for the input wiring terminal (4) to pass through, the edge of the disc (8) is provided with a strip-shaped groove (10), the strip-shaped groove (10) is arranged around the central axis of the disc (8) at equal angles, a sliding block (11) is arranged in the strip-shaped groove (10) of the disc (8), the sliding block (11) is provided with a sealing block (12), the central position of the disc (8) is internally provided with a rotating block (13), the central position of the rotating block (13) is provided with a through hole (14) communicated with the through hole (9), the rotating block (13) is provided with a spring (15) and the outer side of the rotating drum (15), one end of the clockwork spring (16) is connected with the rotating block (13), the other end of the clockwork spring (16) is connected with the chassis (7), a connecting rod (17) is arranged between the rotating block (13) and the sliding block (11), the connecting rod (17) is rotatably arranged between the rotating block (13) and the sliding block (11), and a plurality of sealing blocks (12) form sealing elements in the protective sleeve (6).

2. The pollution-free energy storage device of claim 1, wherein: the inner surface of the sealing block (12) is provided with a special-shaped inclined surface (18), the special-shaped inclined surface (18) comprises a first straight section (1801) and a second straight section (1803), a guide surface (1802) is arranged in front of the first straight section (1801) and the second straight section (1803), and the guide surface (1802) is inclined downwards.

3. The pollution-free energy storage device of claim 1, wherein: the energy storage power supply comprises an energy storage power supply (2) and an energy storage box (1), wherein a heat dissipation area is formed between the energy storage power supply (2) and the energy storage box (1), a plurality of protection baffles (19) are arranged in the heat dissipation area of the energy storage box (1), the bottoms of the protection baffles (19) are connected with the bottoms of the energy storage box (1), and a plurality of protection baffles (19) form a surrounding guard plate on the outer side of the energy storage power supply (2).

4. A pollution-free energy storage device as claimed in claim 3, wherein: the outside of protective shield (19) is equipped with cooling cover (20), cooling cover (20) include a plurality of annular protruding (2001), a plurality of be equipped with between annular protruding (2001) thermal-insulated net (2002), thermal-insulated net (2002) and annular protruding (2001) fixed connection.

5. The pollution-free energy storage device of claim 4, wherein: a plurality of cooling struts (21) are arranged between the inner surface of the annular bulge (2001) and the outer wall of the protective baffle (19), and the cooling struts (21) are uniformly distributed along the inner surface of the annular bulge (2001).

6. The pollution-free energy storage device of claim 5, wherein: the bottom of cooling cover (20) is equipped with injection condenser (22) that are used for spraying the condensation gas, injection condenser (22) are fixed in the inside of energy storage case (1), the output of injection condenser (22) is connected with output tube (23), injection condenser (22) are connected to the one end of output tube (23), the other end of output tube (23) is equipped with annular pipe (24), the upper surface of annular pipe (24) is equipped with a plurality of outlet duct (25), the gas outlet of outlet duct (25) is located the internal surface of cooling cover (20).

7. The pollution-free energy storage device of claim 6, wherein: the top of cooling cover (20) is equipped with the opening, the opening part of cooling cover (20) is equipped with first arc baffle ring (26), the upside of first arc baffle ring (26) is equipped with second arc baffle ring (27), form the trade flow channel between first arc baffle ring (26) and second arc baffle ring (27), be equipped with gas inlet and gas outlet on the trade flow channel, the gas inlet is located the internal surface of cooling cover, the gas outlet is located the surface of cooling cover.

8. The pollution-free energy storage device of claim 7, wherein: the outside of cooling cover is equipped with ripple cover (28), the inside and outside surface of ripple cover (28) all is the wave form structure.

9. The pollution-free energy storage device of claim 8, wherein: the inside of ripple cover (28) just is close to its bottom and is equipped with a plurality of louvre, be equipped with the heat dissipation chamber between the lateral wall of ripple cover (28) and the inside wall of energy storage case (1), communicate each other between heat dissipation chamber and the louvre.

10. The pollution-free energy storage device of claim 9, wherein: the energy storage box (1) is provided with a heat dissipation opening (29), and the heat dissipation opening (29) is communicated with the heat dissipation cavity.