CN117395901B - High-efficient heat dissipation forced air cooling energy storage machine case - Google Patents

Abstract

The utility model relates to the technical field of cases and discloses a high-efficiency heat-dissipation air-cooling energy storage case, which comprises a case, wherein one side plate of the case is a side plate, and the side plate is connected with the case through a push-pull mechanism arranged on the case; the push-pull mechanism comprises a first sliding plate, a second sliding plate and a fixed plate which are sequentially and elastically spliced, wherein the first sliding plate and the second sliding plate are both in sliding connection with the case, the elastic sliding resistance of the first sliding plate is smaller than that of the second sliding plate, the fixed plate is fixedly connected with the case, and a first opening piece which is rotationally connected with the side cover plate is arranged between the first sliding plate and the second sliding plate. The utility model can change the size of the opening to increase the heat discharging speed only by acting the force application part through creative design of the push-pull mechanism, and can change the heat discharging flow direction at the same time to avoid the limitation of air flow outside the case on the heat discharging in the case.

Description

High-efficient heat dissipation forced air cooling energy storage machine case

Technical Field

The utility model relates to the technical field of chassis, in particular to a high-efficiency heat-dissipation air-cooling energy storage chassis.

Background

The energy storage equipment is mainly divided into electricity storage and heat storage, and provides electric energy and heat energy for external equipment. The outer layer of the energy storage device is a case and is used for providing protection for the energy storage device. Because the energy storage equipment can release a large amount of heat when working, various vent holes are formed in a case of the energy storage equipment to enable the heat to be dissipated.

The utility model patent with the name of a cabinet for energy storage equipment, disclosed by the utility model, is a box body, wherein a box cover is arranged on the upper cover of the box body, two side walls in the width direction of the box cover extend downwards and are clung to the outer wall of the box body, radiating holes are formed in the upper parts of the two side walls in the length direction of the box body, radiating fans are embedded in the radiating holes, a thermal switch for opening and closing the radiating fans is connected to the radiating fans, baffle plates are downwards connected to the two side walls in the length direction of the box cover, and an interval exists between the baffle plates and the outer wall of the box body. The heat dissipation holes are formed in the two side walls of the length direction of the box body, the heat dissipation fans are arranged in the heat dissipation holes, heat generated during operation of the energy storage equipment in the box body is conveniently and rapidly discharged, the box cover is arranged on the upper side of the box body in a covering mode, the two side walls of the width direction of the box cover are tightly attached to the outer wall of the box body, the two side walls of the length direction of the box cover are downwards connected with the baffle, the baffle is convenient to cover the heat dissipation fans, the probability that water or other sundries enter the box body from the heat dissipation fans is reduced, accordingly, the cleaning and drying of the energy storage equipment in the box body are guaranteed, and hot air exhausted by the heat dissipation fans escapes from between the baffle and the side wall of the box body, so that normal heat dissipation of the box body is guaranteed.

The case provided by the patent is provided with the radiating fan in the radiating hole, so that the flow of gas is quickened, and the heat in the case flows out from between the baffle and the side wall of the case body, thereby realizing the discharge of the heat; in the case in the prior art, when heat is dissipated, heat directly flows out of the heat dissipation holes formed in the case, and heat can still be exhausted. However, the cases in the above patents and the prior art all have common disadvantages: because the size of the radiating hole is fixed, the size of the space between the baffle and the side wall of the box body is also fixed, so that no matter the heat flows out of the radiating hole or flows out of the space between the baffle and the side wall of the box body, when the heat in the box is higher, the heat discharging speed can not be increased; the flow direction of the heat can not be changed when the heat is discharged, and when the air flow direction outside the case is just opposite to the heat outflow direction, the heat can be limited to be discharged, and even the heat can not be discharged. Therefore, the case in the prior art has a great disadvantage when using air cooling to dissipate heat, and therefore, how to change the size of the heat dissipation holes to increase the heat dissipation speed when needed and change the heat dissipation flow direction when needed to avoid the limitation of the air flow outside the case to the heat dissipation in the case is a technical problem to be solved urgently.

Disclosure of Invention

The utility model aims to provide an efficient heat-dissipation air-cooling energy storage machine case so as to solve the defects in the prior art.

In order to achieve the above object, the present utility model provides the following technical solutions: the efficient heat-dissipation air-cooling energy storage machine case comprises a machine case, wherein one side plate of the machine case is a side plate, and the side plate is connected with the machine case through a push-pull mechanism arranged on the machine case;

the push-pull mechanism comprises a first sliding plate, a second sliding plate and a fixed plate which are sequentially and elastically spliced, wherein the first sliding plate and the second sliding plate are both in sliding connection with the chassis, the elastic sliding resistance of the first sliding plate is smaller than that of the second sliding plate, the fixed plate is fixedly connected with the chassis, a first opening part which is rotationally connected with the side cover plate is arranged between the first sliding plate and the second sliding plate, and a second opening part which is rotationally connected with the side cover plate is arranged between the second sliding plate and the fixed plate;

the opening mechanism comprises a case, a first sliding plate, a second sliding plate, a first opening piece, a second opening piece, a first sliding plate, a second sliding plate, a first opening piece, a second opening piece, a side cover plate and a second opening piece.

The first opening piece comprises a first sliding pressing plate, a first supporting plate, a first rotating plate and a sliding connecting piece, wherein the first sliding pressing plate is fixedly installed on a first sliding plate, a first sliding pressing groove is formed in the first sliding pressing plate, the first supporting plate is fixedly installed on a second sliding plate, the sliding connecting piece is fixedly installed on a side cover plate, a sliding interface is formed in the sliding connecting piece, a first sliding column is rotatably installed at one end of the first rotating plate, a first push-pull column is rotatably connected with the other end of the first rotating plate, the first sliding column is slidably arranged in the first sliding pressing groove, the first push-pull column is slidably connected with the sliding interface, a first supporting pad in contact with the bottom of the sliding connecting piece is fixedly installed at the bottom of the first push-pull column, and the first rotating plate and the first supporting plate are rotatably connected through a first pin shaft.

The first opening piece comprises a first sliding pressing plate, a first supporting plate, a first rotating plate and a first switching piece, wherein the first sliding pressing plate is fixedly arranged on a first sliding plate, a first sliding pressing groove is formed in the first sliding pressing plate, the first supporting plate is fixedly arranged on a fixing plate, the switching piece is fixedly arranged on a side cover plate, a switching hole is formed in the switching piece, one end of the first rotating plate is rotatably provided with a first sliding column, the other end of the first sliding plate is rotatably connected with a first push-pull column, the first sliding column is slidably arranged in the first sliding pressing groove, the first push-pull column is rotatably connected with the switching hole in a plug-in mode, a first supporting pad is fixedly arranged at the bottom of the first push-pull column and is in butt joint with the bottom of the switching piece, and the first rotating plate is rotatably connected with the first supporting plate through a first pin shaft.

The efficient heat dissipation air-cooled energy storage machine case is characterized in that a first pressure spring is connected between the first sliding plate and the second sliding plate.

The high-efficiency heat dissipation air-cooled energy storage machine case is characterized in that a second pressure spring is connected between the second sliding plate and the fixed plate, and the elastic force of the second pressure spring is larger than that of the first pressure spring.

According to the efficient heat dissipation air-cooled energy storage machine case, the guide rail is fixedly installed in the machine case, the guide plates are fixedly installed on the first sliding plate and the second sliding plate, and the guide plates are in sliding connection with the guide rail.

The high-efficiency heat dissipation air-cooled energy storage machine case comprises the force application piece, wherein the force application piece comprises a first screw rod, a screw sleeve is fixedly installed on the machine case, the first screw rod is in screw connection with the screw sleeve, a connecting plate is fixedly installed on the first sliding plate, the end part of the first screw rod is rotationally connected with the connecting plate, and the connecting plate is rotated to push the first sliding plate to elastically slide.

According to the efficient heat dissipation air-cooled energy storage case, the number of the push-pull mechanisms is two, the two push-pull mechanisms are vertically symmetrically arranged or vertically arranged in parallel, and two ends of the connecting plate are fixedly connected with the first sliding plates on the two push-pull mechanisms in a one-to-one correspondence manner so that the two first sliding plates can be driven to synchronously and elastically slide when the first screw rods are rotated.

The above-mentioned high-efficient heat dissipation forced air cooling energy storage machine case, set up the screw hole that runs through its left and right sides terminal surface on the fixed plate, the spiro union has the second screw rod in the screw hole, the one end of second screw rod is corresponding with the terminal surface of second slide, the other end slip runs through the machine case after extend to the outside of machine case, rotate the second screw rod makes its tip and second slide butt so that the second slide can't slide, rotates at this moment first screw rod in order to promote the continuous elastic sliding's of first slide in-process first push-pull column slides to the opening part of smooth interface until break away from with the smooth interface so that the side cap board rotates around the second push-pull column after opening.

According to the efficient heat dissipation air cooling energy storage machine case, the first pressure spring is always in a compressed state.

The beneficial effects are that: in the technical scheme, the high-efficiency heat-dissipation air-cooled energy storage case is provided with the first sliding plate, the second sliding plate and the fixed plate which are sequentially and elastically spliced, the elastic sliding resistance of the first sliding plate is smaller than that of the second sliding plate, when the force application part is used, the force application part firstly pushes the first sliding plate to elastically slide and the second sliding plate is not moved so as to enable the first sliding plate and the second sliding plate to generate relative sliding, the first opening part is arranged between the first sliding plate and the second sliding plate, the relative sliding of the first sliding plate and the second sliding plate drives the first opening part to start so as to drive the side cover plate to rotate, one side of the side cover plate is continuously outwards opened to form an opening, the opening is equivalent to a radiating hole, so that heat in the case is discharged from the opening, the opening is continuously increased along with the increase of the rotation angle of the side cover plate, and the heat discharge of the heat can be accelerated by increasing the opening when the heat in the case is higher; when the first sliding plate elastically slides a certain distance and then the opening is increased to a specific angle, the second sliding plate is driven by the first sliding plate to elastically slide under the action of the force application part, so that the second sliding plate and the fixed plate relatively slide, the second opening part is started at the moment, the second opening part can push the side cover plate to move, the direction of the opening is changed, the heat flow direction in the case is driven to be changed, and therefore, when the direction of the external airflow is opposite to the direction of the original opening to block heat discharge, the direction of the original opening is controlled by the force application part to be changed, and the limitation of external airflow on heat discharge can be avoided. Therefore, the utility model can change the opening size to increase the heat discharging speed only by acting the force application part when needed through creative design of the push-pull mechanism, and can change the heat discharging flow direction at the same time to avoid the limitation of air flow outside the case on heat discharging in the case, thereby effectively solving the defects in the prior art;

meanwhile, the size of the opening is adjusted and the direction of the opening is changed by acting the force application part, so that the utilization rate of the force application part is improved, the corresponding function can be realized under the condition that the corresponding structure is reduced, and unexpected technical effects are generated;

furthermore, when the opening direction is changed, the utility model is realized by reserving the original opening direction and adding a new opening different from the original opening direction, so that the external air flow opposite to the original opening direction can blow heat to be discharged along the new opening direction, and the external air flow becomes the power for blowing heat to be discharged to accelerate the heat discharging speed, thereby realizing waste recycling.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present utility model, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

Fig. 1 is a schematic structural diagram of a chassis when a side cover provided by an embodiment of the present utility model is opened;

FIG. 2 is a schematic view of a chassis according to an embodiment of the present utility model with a top plate and three side plates removed;

fig. 3 is an enlarged schematic view of a portion a in fig. 2 according to an embodiment of the present utility model;

fig. 4 is an enlarged schematic view of a portion B in fig. 2 according to an embodiment of the present utility model;

fig. 5 is a schematic diagram illustrating the detachment between the push-pull mechanism and the guide rail according to the embodiment of the present utility model;

fig. 6 is a schematic structural diagram of a push-pull mechanism according to an embodiment of the present utility model;

fig. 7 is a schematic diagram of a split structure of a push-pull mechanism according to an embodiment of the present utility model;

fig. 8 is a schematic diagram of a split structure of a first opening member according to an embodiment of the present utility model;

fig. 9 is a schematic diagram of a split structure of a second opening member according to an embodiment of the present utility model;

fig. 10 is a schematic diagram of an internal structure of a chassis according to an embodiment of the present utility model;

FIG. 11 is a schematic diagram illustrating an internal cross-sectional structure of a chassis according to an embodiment of the present disclosure;

fig. 12 is a schematic structural diagram of a push-pull mechanism and a side cover plate in an initial state according to an embodiment of the present utility model;

FIG. 13 is a schematic top view of a first opening device according to an embodiment of the present utility model when the first opening device pushes the side cover to rotate to form an opening;

fig. 14 is a schematic top view of a second opening device according to an embodiment of the present utility model when a new opening is formed between a side cover and a chassis;

fig. 15 is a schematic top view of the first push-pull column according to the embodiment of the present utility model when the first push-pull column is separated from the sliding interface.

Reference numerals illustrate:

1. a chassis; 101. a side cover plate; 2. a first screw; 3. a screw sleeve; 4. a limiting piece; 5. a connecting plate; 6. a first slide plate; 7. a second slide plate; 8. a fixing plate; 801. a threaded hole; 9. a guide rail; 901. a mounting piece; 10. a first slide plate; 1001. a first sliding pressing groove; 11. a slip joint; 1101. a sliding interface; 12. a first support plate; 1201. a first pin; 13. a first rotating plate; 1301. a first strut; 1302. a first push-pull column; 1303. a first pad; 14. a second slide plate; 1401. a second sliding pressing groove; 15. an adapter; 16. a second support plate; 1601. a second pin; 17. a second rotating plate; 1701. a second strut; 1702. a second push-pull column; 1703. a second support pad; 18. a second screw; 19. a guide plate; 20. a first compression spring; 21. and a second compression spring.

Detailed Description

In order to make the technical scheme of the present utility model better understood by those skilled in the art, the present utility model will be further described in detail with reference to the accompanying drawings.

As shown in fig. 1-15, the efficient heat dissipation air-cooled energy storage case provided by the embodiment of the utility model comprises a case 1, wherein one side plate of the case 1 is a side cover plate 101, and the side cover plate 101 is connected with the case 1 through a push-pull mechanism arranged on the case 1;

the push-pull mechanism comprises a first sliding plate 6, a second sliding plate 7 and a fixed plate 8 which are sequentially and elastically spliced, wherein the first sliding plate 6 and the second sliding plate 7 are in sliding connection with the case 1, the elastic sliding resistance of the first sliding plate 6 is smaller than that of the second sliding plate 7, the fixed plate 8 is fixedly connected with the case 1, a first opening part which is rotationally connected with the side cover plate 101 is arranged between the first sliding plate 6 and the second sliding plate 7, and a second opening part which is rotationally connected with the side cover plate 101 is arranged between the second sliding plate 7 and the fixed plate 8;

the device also comprises a force application part arranged on the case 1, wherein the force application part is used for pushing the first sliding plate 6 to elastically slide so as to drive the first opening part to push the side cover plate 101 to rotate to form an opening, and after the opening is increased to a specific angle, the first sliding plate 6 is used for pushing the second sliding plate 7 to elastically slide so as to drive the second opening part to push the side cover plate 101 to move so as to change the opening direction.

In the efficient heat dissipation air-cooled energy storage chassis provided in this embodiment, the words related to the direction and the position are relative to the attached drawings. Specifically, the chassis 1 includes a top plate, a bottom plate, and four side plates, where the side cover plate 101 is any one of the four side plates, the side cover plate 101 is not opened in an initial state, and when the side cover plate 101 moves to form an opening between any one side of the side cover plate and the chassis 1, heat in the chassis 1 can be discharged to the outside of the chassis 1 through the opening. The push-pull mechanism is used for pushing the side cover plate 101 to move so as to form an opening between the side cover plate 101 and the chassis 1, the power of the push-pull mechanism is derived from the force application member, and the force application member is acted to provide power for the push-pull mechanism. The first slide 6, the second slide 7, fixed plate 8 in the push-pull mechanism arranges in proper order, fixed plate 8 fixed mounting is on the inner wall of quick-witted case 1, first slide 6 and second slide 7 all slide and set up on the inner wall of quick-witted case 1, first spout that supplies second slide 7 slip male is offered to the one end that first slide 6 is close to, the second spout that supplies fixed plate 8 slip male is offered to the one end that second slide 7 kept away from first slide 6, the one end elasticity slip grafting of second slide 7 is in first spout, the one end elasticity slip grafting of fixed plate 8 is in the second spout, of course, the grafting mode between first slide 6, second slide 7, the fixed plate 8 also can change, not described in detail. The power output of the force application member acts on the first slide plate 6, the elastic sliding resistance of the first slide plate 6 is smaller than the elastic sliding resistance of the second slide plate 7, when the force application member acts, the power generated by the force application member is transmitted to the first slide plate 6 and is directed to the second slide plate 7 along the length direction of the first slide plate 6, and after the first slide plate 6 receives the acting force of the force application member, the first slide plate 6, the second slide plate 7 and the fixed plate 8 can move in two different stages, namely: the first stage is that the first sliding plate 6 starts to elastically slide towards the second sliding plate 7 and the second sliding plate 7 is kept still, at the moment, relative sliding is generated between the first sliding plate 6 and the second sliding plate 7, and the second sliding plate 7 and the fixed plate 8 are relatively stationary; since the first sliding plate 6 is elastically sliding, the sliding resistance of the first sliding plate 6 gradually increases during the sliding process, and therefore, in the second stage, when the sliding resistance of the first sliding plate 6 is equal to the sliding resistance of the second sliding plate 7, not only the first sliding plate 6 can continue to elastically slide, but also the second sliding plate 7 can be pushed by the first sliding plate 6 to elastically slide, and at this time, the second sliding plate 7 and the fixed plate 8 also relatively slide. The relative sliding between the first slide 6 and the second slide 7 is used for activating the first opening member and the relative sliding between the second slide 7 and the fixed plate 8 is used for activating the second opening member. The first opening piece and the second opening piece are both connected with the side cover plate 101, when the first opening piece is started, the side cover plate 101 can be pushed to rotate so that an opening is formed between the side cover plate 101 and the case 1, and the opening is opened in a way of continuously opening from small to large; when the second opening piece is started, the side cover plate 101 can be pushed to move towards the opening direction of the opening, at the moment, the opening direction is changed to form a new opening, wherein the opening generated by the first opening piece is the original opening, the opening generated by the second opening piece is the new opening, the direction of the new opening is different from the direction of the original opening, as shown in fig. 13, the state diagram is shown when the first opening piece pushes the side cover plate 101 to rotate to form the opening, at the moment, the opening is positioned on the right side of the case 1 and faces the front side, the upper side and the lower side of the case 1, and at the moment, the opening is the original opening; as shown in fig. 14, at this time, the second opening member is activated, so that the right side edge of the side cover plate 101 passes over the right side surface of the chassis 1, and a new opening is formed between the side cover plate 101 and the chassis 1, the new opening is located on the right side and the left side of the chassis 1, the direction of the new opening located on the right side of the chassis 1 is changed to be directed to the right side, the upper side and the lower side of the chassis 1, and the direction of the new opening located on the left side of the chassis 1 is directed to the front side, the upper side and the lower side of the chassis 1, namely, the direction of the original opening is maintained, and the new direction is added when the direction of the original opening is changed. In the prior art, taking fig. 13 and 14 as an example, when the external air flow of the case 1 vertically faces the inner side of the side cover plate 101, the heat discharged from the original opening is blocked and limited by the external air flow, so that the amount of heat discharged from the original opening is greatly reduced, and when the original opening is changed to a new opening, the direction facing the right side of the case 1 is increased, at this time, because the right side of the side cover plate 101 passes over the right side of the case 1, the external air flow blows on the outer side of the side cover plate 101 and is blocked by the side cover plate 101, and then the heat in the case 1 can be discharged through the right side of the case 1, so that the amount of heat discharge is greatly reduced, and the external air flow can enter the case 1 through the left side of the new opening and blows the heat in the case 1, so that the heat is continuously discharged through the right side of the new opening after providing power for the heat, and the heat discharge speed can be greatly improved.

In this embodiment, by arranging the first sliding plate 6, the second sliding plate 7 and the fixing plate 8 which are elastically spliced in sequence, and the elastic sliding resistance of the first sliding plate 6 is smaller than that of the second sliding plate 7, when the force application member is used, the force application member pushes the first sliding plate 6 to elastically slide and the second sliding plate 7 is not moved so as to enable the first sliding plate 6 and the second sliding plate 7 to generate relative sliding, the first opening member is arranged between the first sliding plate 6 and the second sliding plate 7, the relative sliding of the first sliding plate 6 and the second sliding plate 7 drives the first opening member to start to drive the side cover plate 101 to rotate, one side of the side cover plate 101 is continuously outwards opened to form an opening, the opening is equivalent to a radiating hole, so that heat in the chassis 1 is discharged from the opening, and the opening is continuously increased along with the increase of the rotation angle of the side cover plate 101, so that the heat in the chassis 1 can be accelerated to be discharged by increasing the opening when the heat in the chassis is higher; when the first sliding plate 6 elastically slides a certain distance and then the opening is increased to a specific angle, the second sliding plate 7 is driven by the first sliding plate 6 to elastically slide under the action of the force application part, so that the second sliding plate 7 and the fixed plate 8 relatively slide, at the moment, the second opening part is started, the second opening part can push the side cover plate 101 to move, the opening direction is changed, and then the heat flow direction in the case 1 is driven to be changed after the opening direction is changed, so that when the external airflow direction is opposite to the original opening direction to block heat discharge, the restriction of external airflow on heat discharge can be avoided by controlling the second opening part to change the original opening direction through the force application part. Therefore, the utility model can change the opening size to increase the heat discharging speed only by acting the force application part when needed through creative design of the push-pull mechanism, and can change the heat discharging flow direction at the same time to avoid the limitation of air flow outside the case on heat discharging in the case, thereby effectively solving the defects in the prior art;

meanwhile, the size of the opening is adjusted and the direction of the opening is changed by acting the force application part, so that the utilization rate of the force application part is improved, the corresponding function can be realized under the condition that the corresponding structure is reduced, and unexpected technical effects are generated;

furthermore, when the opening direction is changed, the utility model is realized by reserving the original opening direction and adding a new opening different from the original opening direction, so that the external air flow opposite to the original opening direction can blow heat to be discharged along the new opening direction, and the external air flow becomes the power for blowing heat to be discharged to accelerate the heat discharging speed, thereby realizing waste recycling.

In this embodiment, the first opening element includes a first sliding plate 10, a first support plate 12, a first rotating plate 13, and a sliding contact element 11, where the first sliding plate 10 is fixedly installed on the first sliding plate 6, the first sliding plate 10 is provided with a first sliding groove 1001, the first support plate 12 is fixedly installed on the second sliding plate 7, the sliding contact element 11 is fixedly installed on the side cover plate 101, the sliding contact element 11 is provided with a sliding interface 1101, one end of the first rotating plate 13 is rotatably installed with a first sliding column 1301, the other end is rotatably connected with a first sliding column 1302, the first sliding column 1301 is slidably disposed in the first sliding groove 1001, the first sliding column 1302 is slidably connected with the sliding interface 1101, the bottom of the first sliding column 1302 is fixedly installed with a first supporting pad 1303 abutted to the bottom of the sliding contact element 11, and the first rotating plate 13 and the first support plate 12 are rotatably connected through a first pin 1201. Specifically, the longitudinal section of the first sliding groove 1001 and the longitudinal section of the first sliding column 1301 are both inverted T-shaped, so that the first sliding column 1301 is slidably connected with the first sliding groove 1001 and cannot be separated from the first sliding groove 1001, the first sliding column 1301 and the first sliding column 1302 are rotationally connected with the first rotating plate 13, limiting sheets abutted to the top surface of the first rotating plate 13 are fixedly mounted on the tops of the first sliding column 1301 and the first sliding column 1302, so that the first sliding column 1301 and the first sliding column 1302 cannot be separated from the first rotating plate 13, the first supporting pad 1303 is used for supporting the sliding piece 11 to realize connection between the side cover plate 101 and the first opening piece, an opening is formed in one side of the sliding interface 1101, the first sliding column 1302 slides into the sliding interface 1101 from the opening of the sliding interface 1101, the inner wall of the sliding interface 1101 is abutted to the outer surface of the first sliding column 1302, the axial lead of the first pin 1201 is the rotating center of rotation of the first rotating plate 13, and the first pin 1201 is located between the first sliding column 1301 and the first sliding column 1201. The first compression spring 20 is connected between the first sliding plate 6 and the second sliding plate 7, wherein the first compression spring 20 is located in the first sliding groove, one end of the first compression spring 20 is fixedly connected with the second sliding plate 7, and the other end of the first compression spring is fixedly connected with or abutted against the inner wall of the first sliding groove.

The working principle of the first opening piece is as follows: the first opening part operates mainly in the first stage after the first sliding plate 6 receives the acting force of the force application part, since the first sliding plate 10 is fixedly installed on the first sliding plate 6, the first support plate 12 is fixedly installed on the second sliding plate 7, so that in the first stage after the first sliding plate 6 receives the acting force of the force application part, the first sliding plate 6 slides towards the second sliding plate 7 and presses the first pressure spring 20 to compress, so that the elastic force of the first pressure spring 20 is gradually increased, and since the second sliding plate 7 keeps still, relative sliding is generated between the first sliding plate 6 and the second sliding plate 7, at this time, the first sliding plate 6 drives the first sliding plate 10 to slide synchronously, the sliding of the first sliding plate 10 pushes the first sliding column 1301 to slide in the first sliding pressure groove 1001, so that the first rotating plate 13 rotates around the first pin shaft 1201, the first sliding column 1302 rotates to the outside of the case 1, the sliding connection part 11 is pushed to rotate around the second sliding column 1702 while the sliding column, the sliding connection part 11 rotates around the sliding plate 1101 rotates around the sliding column, and the sliding plate 11 rotates around the sliding plate 101 to the outside of the case 1, so that the sliding plate 101 rotates synchronously, and the length of the sliding plate 101 rotates along the opening side of the case 101 is controlled to be larger, and the opening side is controlled.

In this embodiment, the second opening member includes a second sliding plate 14, a second support plate 16, a second rotating plate 17, and an adapter member 15, where the second sliding plate 14 is fixedly installed on the second sliding plate 7, a second sliding groove 1401 is formed on the second sliding plate 14, the second support plate 16 is fixedly installed on the fixing plate 8, the adapter member 15 is fixedly installed on the side cover plate 101, an adapter hole 1501 is formed on the adapter member 15, one end of the second rotating plate 17 is rotatably installed with a second sliding column 1701, the other end is rotatably connected with a second sliding column 1702, the second sliding column 1701 is slidably arranged in the second sliding groove 1401, the second sliding column 1702 is rotatably connected with the adapter hole 1501, a second supporting pad 1703 abutting against the bottom of the adapter member 15 is fixedly installed at the bottom of the second sliding column 1702, and the second rotating plate 17 is rotatably connected with the second support plate 16 through a second pin 1601. Specifically, the longitudinal section of the second sliding groove 1401 and the longitudinal section of the second sliding column 1701 are both inverted T-shaped, so that the second sliding column 1701 is slidably connected with the second sliding groove 1401 and cannot be separated from the second sliding groove 1401, the second sliding column 1701 and the second sliding column 1702 are both rotatably connected with the second rotating plate 17, and the top parts of the second sliding column 1701 and the second sliding column 1702 are fixedly provided with limiting pieces abutted with the top surface of the second rotating plate 17 so that the second sliding column 1701 and the second sliding column 1702 cannot be separated from the second rotating plate 17, the second supporting pad 1703 is used for supporting the adapter 15 to realize connection between the side cover plate 101 and the second opening piece, the axis line of the second pin 1601 is the rotation center of the second rotating plate 17, and the second pin 1601 is located between the second sliding column 1701 and the second sliding column 1702. A second pressure spring 21 is connected between the second sliding plate 7 and the fixed plate 8, the elasticity of the second pressure spring 21 is larger than that of the first pressure spring 20, the second pressure spring 21 is positioned in the second sliding groove, one end of the second pressure spring 21 is fixedly connected with the fixed plate 8, and the other end of the second pressure spring is fixedly connected or abutted with the inner wall of the second sliding groove.

The working principle of the second opening piece is as follows: the second opening member operates mainly in the second stage after the first sliding plate 6 is acted by the urging member, in the first stage, as the compression elastic force of the first compression spring 20 increases continuously, after the elastic force of the first compression spring 20 is equal to the elastic force of the second compression spring 21, the sliding of the first sliding plate 6 pushes the second sliding plate 7 to slide elastically through the second compression spring 21, so that the second sliding plate 7 compresses the second compression spring 21 to generate elastic deformation, and thus the first sliding plate 6 and the second sliding plate 7 further generate relative sliding, meanwhile, the second sliding plate 7 and the fixed plate 8 also generate relative sliding, the sliding of the second sliding plate 7 drives the second sliding plate 14 to slide synchronously, the sliding of the second sliding plate 14 pushes the second sliding post 1701 to slide in the second sliding pressure groove 1401, so that the second rotating plate 17 rotates around the second pin shaft 1601, the rotation of the second rotating plate 17 drives the second push-pull column 1702 to rotate towards the outside of the chassis 1, so that the second push-pull column 1702 pushes the adapter 15 and the side cover plate 101 to move towards the outside and the right side of the chassis 1 around the first push-pull column 1302, the movement of the side cover plate 101 enables a distance to be generated between the left side of the side cover plate 101 and the chassis 1, the right side of the side cover plate 101 passes over the right side surface of the chassis 1, a new opening is generated, the direction of heat in the chassis 1 when the heat flows out from the right side of the new opening is towards the right side, the upper side and the lower side of the chassis 1, and the direction of heat in the chassis 1 flows out from the original opening is towards the front, the upper side and the lower side of the chassis 1, so that the direction of the new opening is changed; meanwhile, the left direction of the new opening is the same as the direction of the original opening and faces to the front, the upper and the lower of the case 1, so that the direction of the original opening is reserved in the direction of the new opening, and the new direction is added. When the external air flow is opposite to the original opening to limit the outflow of heat, the external air flow is introduced into the case 1 from the left side of the new opening and continuously discharged from the right side of the new opening after changing the direction of the original opening, and the external air flow provides power for the flow of heat after entering the case 1, so that the heat can be discharged from the right side of the new opening more quickly to accelerate the discharging speed.

Wherein, guide rail 9 is fixed in the chassis 1, guide plates 19 are fixed on the first slide plate 6 and the second slide plate 7, and guide plates 19 are in sliding connection with guide rail 9. The cross section of the inner cavity of the guide rail 9 and the cross section of the guide plate 19 are T-shaped, so that the guide plate 19 is not separated while being connected with the guide rail 9 in a sliding way. Both ends of the guide rail 9 are fixedly provided with a mounting plate 901, and the mounting plate 901 is fixedly connected with the inner wall of the case 1 through screws.

In this embodiment, the force application member includes a first screw rod 2, a screw sleeve 3 is fixedly installed on the chassis 1, the first screw rod 2 is in screwed connection with the screw sleeve 3, a connecting plate 5 is fixedly installed on the first sliding plate 6, and the end portion of the first screw rod 2 is rotationally connected with the connecting plate 5, so as to push the first sliding plate 6 to elastically slide by rotating the connecting plate 5. Specifically, two limiting sheets 4 are fixedly arranged at intervals at the end parts of the first screw 2, which are rotationally connected with the connecting plate 5, the connecting plate 5 is positioned between the two limiting sheets 4 and is in sliding contact with the opposite surfaces of the two limiting sheets 4, when the first screw 2 is rotated in the forward direction, the first screw 2 is spirally advanced towards the inner side of the case 1, so that the limiting sheets 4 push the connecting plate 5 to slide towards the inner side of the case 1, and the connecting plate 5 drives the first sliding plate 6 to slide towards the inner side of the case 1 (namely, towards the direction of the second sliding plate 7); conversely, when the first screw rod 2 is reversely rotated, the first screw rod 2 is spirally advanced towards the outer side of the chassis 1, so that the limiting piece 4 pushes the connecting plate 5 to spirally advance towards the outer side of the chassis 1, so that the first sliding plate 6 moves away from the second sliding plate 7, and at the moment, the side cover plate 101 can be driven to reset under the action of the elasticity of the first pressure spring 20 and the second pressure spring 21, so that the opening is closed, and the details are omitted.

In this embodiment, the two groups of push-pull mechanisms are vertically symmetrically arranged or vertically arranged in parallel, and two ends of the connecting plate 5 are fixedly connected with the first sliding plates 6 on the two groups of push-pull mechanisms in a one-to-one correspondence manner, so that the two first sliding plates 6 can be driven to synchronously and elastically slide when the first screw rod 2 is rotated. The arrangement of the two groups of push-pull mechanisms can improve the stability of the side cover plate 101 during movement and the stress balance of the connecting plate 5.

More importantly, in this embodiment, the opening of the sliding interface 1101 is located on the right side of the sliding interface 1101, the fixing plate 8 is provided with a threaded hole 801 penetrating through the left and right end surfaces thereof, the threaded hole 801 is screwed with a second screw rod 18, the second screw rod 18 passes through the second pressure spring 21, one end of the second screw rod 18 corresponds to the end surface of the second sliding plate 7, the other end of the second screw rod 18 slides through the chassis 1 and extends to the outside of the chassis 1, the end of the second screw rod 18 is rotated to abut against the second sliding plate 7 so that the second sliding plate 7 cannot slide, and at this time, the first screw rod 2 is rotated to push the first sliding plate 6 to slide continuously towards the opening of the sliding interface 1101 until the first sliding column 1302 is separated from the sliding interface 1101 to enable the side cover plate 101 to rotate around the second sliding column 1702 after opening. Specifically, in the process that the first opening member pushes the first sliding plate 6 to slide, the first push-pull column 1302 is driven to slide towards the opening of the sliding interface 1101 continuously, when the opening angle is increased to a specific angle, the first push-pull column 1302 cannot be separated from the sliding interface 1101, meanwhile, in the second stage that the first sliding plate 6 is acted by the force application member, the first push-pull column 1302 can slide towards the opening of the sliding interface 1101 further, when the end part of the second screw 18 does not abut against the second sliding plate 7, the second push-pull column 1702 can push the side cover plate 101 to move towards the right side of the chassis 1, so that the first push-pull column 1302 cannot be separated from the sliding interface 1101 in the process that the first sliding plate 6 slides further; when the end of the second screw 18 abuts against the second sliding plate 7, the second sliding plate 7 is limited and cannot slide, at this time, along with the further sliding of the first sliding plate 6, the second rotating plate 17 will not rotate, and the first rotating plate 13 further rotates, so as to drive the first push-pull column 1302 to further slide towards the opening of the sliding interface 1101 to enable the first push-pull column 1302 to slide out of the sliding interface 1101 (as shown in fig. 15), at this time, the right side of the side cover plate 101 is opened, so that the side cover plate 101 can freely rotate around the second push-pull column 1702, and at this time, the components inside the chassis 1 can be mounted and dismounted. In this process, the force application member becomes a "key" for opening the side closure 101, the first opening member becomes a "lock", and the second push-pull post 1702 in the second opening member becomes a spindle for rotation when the side closure 101 is opened.

Therefore, in the utility model, by selecting different states of the second screw 18, different actions can be generated on the first opening member and the second opening member, so that unexpected technical effects are generated, and the side cover plate 101 is opened by rotating the first screw 2, so that the utilization rate of the force application member is further improved.

The first compression spring 20 is always in a compressed state, so that in an initial state, the first sliding plate 6 generates extrusion force on the first screw rod 2, thereby improving the stability of the first sliding plate 6 and being not easy to shake.

While certain exemplary embodiments of the present utility model have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the utility model, which is defined by the appended claims.

Claims (10)

1. The utility model provides a high-efficient heat dissipation forced air cooling energy storage machine case, includes machine case (1), its characterized in that:

one side plate of the case (1) is a side plate (101), and the side plate (101) is connected with the case (1) through a push-pull mechanism arranged on the case (1);

the push-pull mechanism comprises a first sliding plate (6), a second sliding plate (7) and a fixed plate (8) which are sequentially and elastically spliced, wherein the first sliding plate (6) and the second sliding plate (7) are both in sliding connection with the case (1), the elastic sliding resistance of the first sliding plate (6) is smaller than that of the second sliding plate (7), the fixed plate (8) is fixedly connected with the case (1), a first opening part which is rotationally connected with the side cover plate (101) is arranged between the first sliding plate (6) and the second sliding plate (7), and a second opening part which is rotationally connected with the side cover plate (101) is arranged between the second sliding plate (7) and the fixed plate (8);

the opening mechanism is characterized by further comprising a force application piece arranged on the chassis (1), wherein the force application piece is used for pushing the first sliding plate (6) to elastically slide so as to drive the first opening piece to push the side cover plate (101) to rotate to form an opening, and after the opening is increased to a specific angle, the first sliding plate (6) is used for pushing the second sliding plate (7) to elastically slide so as to drive the second opening piece to push the side cover plate (101) to move so as to change the opening direction.

2. The efficient heat dissipation air-cooled energy storage chassis of claim 1, wherein: the first opening piece comprises a first sliding plate (10), a first support plate (12), a first rotating plate (13) and a sliding connecting piece (11), wherein the first sliding plate (10) is fixedly installed on a first sliding plate (6), a first sliding groove (1001) is formed in the first sliding plate (10), the first support plate (12) is fixedly installed on a second sliding plate (7), the sliding connecting piece (11) is fixedly installed on a side cover plate (101), a sliding interface (1101) is formed in the sliding connecting piece (11), a first sliding column (1301) is installed at one end of the first rotating plate (13) in a rotating mode, a first sliding column (1302) is connected with the other end of the first rotating plate in a rotating mode, the first sliding column (1301) is arranged in the first sliding groove (1001) in a sliding mode, a first supporting pad (1303) in contact with the bottom of the sliding connecting piece (11) in a sliding mode is fixedly installed at the bottom of the first sliding column (1302), and the first rotating plate (1201) is connected with the first rotating plate (1201) in a sliding mode.

3. The efficient heat dissipation air-cooled energy storage chassis of claim 2, wherein: the second opening piece comprises a second sliding pressing plate (14), a second support plate (16), a second rotating plate (17) and a switching piece (15), wherein the second sliding pressing plate (14) is fixedly installed on a second sliding plate (7), a second sliding pressing groove (1401) is formed in the second sliding pressing plate (14), the second support plate (16) is fixedly installed on a fixed plate (8), the switching piece (15) is fixedly installed on a side cover plate (101), a switching hole (1501) is formed in the switching piece (15), a second sliding column (1701) is rotatably installed at one end of the second rotating plate (17), a second sliding column (1702) is rotatably connected to the other end of the second rotating plate, the second sliding column (1701) is slidably arranged in the second sliding pressing groove (1401), the second sliding column (1702) is rotatably connected with the switching hole (1501), a second supporting pad (3) is fixedly installed at the bottom of the second sliding column (1702) and is in contact with the bottom of the switching piece (15), and the second rotating plate (17) is rotatably connected with the second rotating plate (17016) through a second pin shaft (1701).

4. The efficient heat dissipation air-cooled energy storage chassis of claim 1, wherein: a first pressure spring (20) is connected between the first sliding plate (6) and the second sliding plate (7).

5. The high efficiency heat dissipating air cooled energy storage chassis of claim 4, wherein: a second pressure spring (21) is connected between the second sliding plate (7) and the fixed plate (8), and the elastic force of the second pressure spring (21) is larger than that of the first pressure spring (20).

6. The efficient heat dissipation air-cooled energy storage chassis of claim 1, wherein: guide rails (9) are fixedly arranged in the case (1), guide plates (19) are fixedly arranged on the first sliding plate (6) and the second sliding plate (7), and the guide plates (19) are in sliding connection with the guide rails (9).

7. The high efficiency heat dissipating air cooled energy storage chassis of claim 3, wherein: the force application piece comprises a first screw rod (2), a screw sleeve (3) is fixedly installed on the machine case (1), the first screw rod (2) is in threaded connection with the screw sleeve (3), a connecting plate (5) is fixedly installed on the first sliding plate (6), the end part of the first screw rod (2) is rotationally connected with the connecting plate (5), and the connecting plate (5) is rotated to push the first sliding plate (6) to elastically slide.

8. The high efficiency heat dissipating air cooled energy storage chassis of claim 7, wherein: the two groups of push-pull mechanisms are vertically symmetrically arranged or vertically arranged in parallel, and two ends of the connecting plate (5) are fixedly connected with the first sliding plates (6) on the two groups of push-pull mechanisms in a one-to-one correspondence manner so that the two first sliding plates (6) can be driven to synchronously and elastically slide when the first screw (2) is rotated.

9. The high efficiency heat dissipating air cooled energy storage chassis of claim 7, wherein: the fixed plate (8) is provided with a threaded hole (801) penetrating through the left end face and the right end face of the fixed plate, a second screw rod (18) is connected in the threaded hole (801) in a threaded mode, one end of the second screw rod (18) corresponds to the end face of the second sliding plate (7), the other end of the second screw rod slides through the chassis (1) and then extends to the outside of the chassis (1), the second screw rod (18) is rotated to enable the end of the second screw rod to abut against the second sliding plate (7) so that the second sliding plate (7) cannot slide, at the moment, the first screw rod (2) is rotated to push the first sliding plate (6) to slide towards the opening of the sliding interface (1101) until the second screw rod (1302) is separated from the sliding interface (1101) to enable the side cover plate (101) to rotate around the second sliding column (1702) after being opened.

10. The high efficiency heat dissipating air cooled energy storage chassis of claim 4, wherein: the first compression spring (20) is always in a compressed state.