CN113085612B - Heat dissipation drying device, charging pile with same and heat dissipation drying method - Google Patents

Abstract

The application discloses a heat dissipation drying device, a charging pile with the heat dissipation drying device and a heat dissipation drying method, and relates to the technical field of charging piles. In the present application, a heat dissipation and drying device includes: the organism sets up on the plane, and the organism includes: the box body is arranged on the plane, and an accommodating space is arranged in the box body; the reel is arranged in the box body and is movably connected with the box body; the cable is arranged in the box body; the charging gun is arranged at one side of the box body; the number of the reels is two, the number of the cables and the number of the charging guns are two, and the cables and the charging guns are respectively arranged on the left side and the right side of the box body; the covering device is arranged on the periphery of the box body; the drying device is arranged in the box body. The application is used for solving the problems that in the prior art, when the charging pile is in a low-temperature environment, after the charging gun contacts water mist or rainwater, the charging gun can generate icing phenomenon through low temperature, and the charging gun can freeze with the charging pile, so that the charging pile can not be pulled out when the charging gun is used, and the charging gun is forcedly pulled out to cause damage.

Description

Heat dissipation drying device, charging pile with same and heat dissipation drying method

Technical Field

The application relates to the technical field of charging piles, in particular to a heat dissipation drying device, a charging pile with the heat dissipation drying device and a heat dissipation drying method.

Background

In recent years, with the increasing severity of urban environmental pollution and the increasing awareness of environmental protection, low-carbon economy and energy-saving and emission-reduction technologies are rapidly developed.

Because of the pollution-free advantage of the electric automobile, the electric automobile is popularized by people, and the charging pile is an important basic matched charging facility of the electric automobile. The use process of the charging pile is quite similar to the automobile refueling process.

And along with electric automobile is more and more, the supporting electric pile that fills of using also is more and more, however general electric pile long-time placing and installing in open-air external environment, when using in north, can pile up sleet at electric pile's top winter, is inconvenient for its clearance, pile up for a long time can cause certain influence to electric pile.

Moreover, when using the charging pile in winter, the charging gun is in the inside of the placing port of the charging pile, if the invasion of rainwater or the invasion of water mist occurs, the charging gun port and the charging pile can be frozen due to the low temperature, so that the charging gun can not be pulled out of the charging pile, and if the charging pile is pulled out forcibly, the charging gun can be damaged.

Disclosure of Invention

The application aims to provide a heat dissipation drying device which is used for solving the problem that a charging gun can freeze with a charging pile due to the fact that the charging gun cannot be pulled out of the charging pile when the charging gun is used and the charging gun is forcedly pulled out to cause damage after the charging gun contacts water mist or rainwater in the low-temperature environment in the prior art.

The second objective of the present application is to provide a charging pile.

In order to achieve the above purpose, the embodiment of the present application adopts the following technical scheme: a heat dissipation drying device, comprising: organism, this organism sets up on the plane, and this organism includes: the box body is arranged on a plane, and an accommodating space is arranged in the box body; the reel is arranged in the box body and is movably connected with the box body; a cable arranged in the box body, the cable is connected with the reel in a matching way, and the cable is wound on the periphery of the reel; the charging gun is arranged on one side of the box body, one end of the charging gun is fixedly connected with the cable, and a charging port of the charging gun is connected with one side of the box body in a matching way; the two reels are arranged, the two cables and the two charging guns are arranged, and the two cables and the two charging guns are respectively arranged at the left side and the right side of the box body; the cover device is arranged on the periphery of the box body, is movably connected with the box body, is positioned on the back surface of the box body when not in use, and is positioned above the box body when in use; and the drying device is arranged in the box body and is fixedly connected with the box body.

According to the technical scheme, the cover device and the drying device are used for generating heat in the box body when the charging pile is used, then the drying device is used for moving the heat to the drying plate, the drying plate is used for enabling the internal heat to flow out through the heat dissipation opening, the heat is contacted with the shielding plate when the heat flows out of the heat dissipation opening, the surface of the shielding plate continuously receives the heat transferred by the heat, snow can be prevented from being accumulated on the surface of the shielding plate in winter, the situation that the shielding plate is broken due to excessive stress can be caused, and the charging gun in the box body is continuously heated through the drying device, so that the charging gun is prevented from icing due to the external temperature when the charging gun is static.

Further, in an embodiment of the present application, the covering device includes: the shielding plate is arranged on the periphery of the box body and is movably connected with the box body; the lifting plate is arranged on the back surface of the box body and is movably connected with the box body; the supporting plate is arranged on the surface of the shielding plate, the supporting plate is integrally connected with the shielding plate, and one end of the supporting plate is connected with the lifting plate; the guide column is arranged on the back surface of the box body, a space is reserved between the guide column and the box body, and the guide column is movably connected with the lifting plate; the driving motor is arranged on the back surface of the box body and is connected with the lifting plate in a matching way; the protection casing, this protection casing setting is in the periphery of this driving motor, this protection casing and this box fixed connection.

Further, in the embodiment of the application, the shielding plate is provided with a U-arc shape, the supporting plate is movably connected with the top end of the lifting plate, and the supporting plate can drive the shielding plate to rotate around the center of the top end of the lifting plate.

Further, in an embodiment of the present application, the guide post is hollow, and the lifting plate is located in the hollow of the guide post, and the lifting plate passes through the guide post.

Further, in the embodiment of the application, the surface of the lifting plate is provided with tooth grooves, the rotating end of the driving motor is provided with a gear, the gear of the driving motor is meshed with the tooth grooves of the lifting plate, and the driving motor rotates to control the movement of the shielding plate to be closed.

Further, in an embodiment of the present application, the drying apparatus includes: the heat collection box is arranged in the box body and is positioned above the reel; the first heat conducting plate is arranged in the box body and is positioned below the heat collecting box; the heat conduction assembly is arranged above the heat collection box and is fixedly connected with the heat collection box; the second heat conducting plate is arranged above the heat conducting component, and a space is reserved between the second heat conducting plate and the heat conducting component; the first heat-conducting plate is arranged on one side of the heat collection box and is connected with the heat collection box in a matched mode; the second heat-conducting plate is arranged on the other side of the heat collection box and is opposite to the first heat-conducting plate; the drying plate is arranged between the second heat-conducting plate and the first heat-conducting plate; a heat radiation port arranged above the box body; and the heat dissipation components are arranged on the left side and the right side of the heat collection box and are connected with the box body in a matched manner.

Further, in the embodiment of the application, the first heat conduction plate and the second heat conduction plate are in butt joint to form a complete backflow plate, and the second heat conduction plate, the heat conduction assembly, the heat collection box and the first heat conduction plate are contained in the lower part of the backflow plate; the drying plate and the placing opening of the box body are integrally formed, and the charging gun is placed in the drying plate.

Further, in the embodiment of the application, a fan is arranged in the heat conduction assembly, the first heat conduction plate is provided with an arc-shaped surface, and the arc-shaped surface of the first heat conduction plate faces upwards; the second heat conducting plate is provided with an arc-shaped surface, the arc-shaped surface of the second heat conducting plate faces downwards, and the heat conducting component absorbs heat in the box body and is conducted to the heat radiating component through the first heat conducting plate and the second heat conducting plate.

Further, in the embodiment of the application, two heat dissipation components are provided, each heat dissipation component comprises a heat dissipation plate and a heat dissipation plate, a space is reserved between each heat dissipation component and the heat collection box to form a heat channel, and hot air in the heat channel exchanges heat to outside air through the heat dissipation plate and the heat dissipation plate.

In order to achieve the second objective, the following technical scheme is adopted in the embodiment of the application: a charging pile, wherein, the heat dissipation drying device that has one of the above-mentioned purpose.

The embodiment of the application also discloses a heat dissipation and drying method of the heat dissipation and drying device, which comprises the following steps:

the method comprises the steps that an object to be charged is moved to the front of a case, a charging gun is taken out and inserted into a charging port of the object to be charged, heat is generated in the charging pile when the charging gun conveys current to the object to be charged, and heat is also generated at the joint of the charging gun and the charging port of the object to be charged;

when the charging gun is used in winter, the charging gun and the charging port of the object to be charged continuously keep current transmission, heat is generated around the charging port of the object to be charged, and water mist in the external environment cannot form icing phenomenon on the surface of the charging gun due to low temperature;

in the charging process, heat is also generated in the box body due to the transmission of current, the heat in the box body is moved upwards through the drying device, after the hot air is guided by the fan of the heat conducting assembly, the hot air flows through the second heat conducting plate to move towards the drying plate, and the heat can move to the left and right sides through the second heat conducting plate because the charging gun is not separated from the drying plate and flows out to the outer side of the box body through the heat radiating assembly;

when the charging gun at the other end is used, hot air can move to the heat dissipation port through the drying plate without the charging gun, excessive internal heat is discharged outwards, and the internal heat of the box body is moved bidirectionally through the drying device.

The application has the beneficial effects that: firstly, the heat dissipation drying device provided by the application can generate a large amount of heat energy in the charging pile when the charging pile is used, the heat in the charging pile is discharged to the outside through the drying device, so that the damage caused by overheat in the charging pile is prevented, and when the charging gun is positioned in the charging pile in winter, the heat cannot be generated in the charging pile, at the moment, due to the low temperature of the outside, the charging gun is provided with water mist, the charging gun and the charging pile can generate icing phenomenon, the drying device can continuously carry out heat transfer on the charging gun when the charging gun is positioned in the charging pile, and the charging gun is kept to have partial heat so as to reduce the icing condition of the charging gun and the charging pile, so that the charging gun is prevented from being damaged by forcibly pulling out the charging pile after icing when the charging gun is used.

Drawings

The application will be further described with reference to the drawings and examples.

Fig. 1 is a non-used schematic diagram of a cover device of a heat dissipating and drying device according to an embodiment of the present application.

Fig. 2 is a schematic diagram of a cover device of a heat dissipating and drying device according to an embodiment of the present application after use.

Fig. 3 is an internal schematic view of a heat dissipating and drying device according to an embodiment of the present application.

Fig. 4 is a schematic back view of a heat dissipating and drying device according to an embodiment of the present application.

Fig. 5 is a schematic side view of an embodiment of a heat dissipating and drying device according to the present application.

Fig. 6 is an enlarged schematic view of a portion of fig. 3 at a.

Fig. 7 is a schematic diagram of a drying device using a heat dissipating and drying device according to an embodiment of the present application.

Fig. 8 is a schematic diagram illustrating a working process of the heat dissipating and drying device according to an embodiment of the present application.

10. Organism 101, box 102, cable

103. Charging gun 104, reel

20. Cover device 201, shutter 202, and lifting plate

203. Support plate 204, guide column 205 and driving motor

206. Protective cover

30. Drying device 301, heat collection box 302 and first heat conduction plate

303. Heat conducting assembly 304, second heat conducting plate 305, first heat conducting plate

306. Second heat-conducting plate 307, drying plate 308 and heat radiation port

309. Radiating component 310, heat insulation board 311 and telescopic column

Detailed Description

In order to make the objects, technical solutions, and advantages of the present application more apparent, a further detailed description of embodiments of the present application will be given below with reference to the accompanying drawings

. It should be understood that the specific embodiments described herein are some, but not all, embodiments of the present application, are intended to be illustrative only and not limiting of the embodiments of the present application, and that all other embodiments obtained by persons of ordinary skill in the art without making any inventive effort are within the scope of the present application.

In the description of the present application, it should be noted that the terms "center," "middle," "upper," "lower," "left," "right," "inner," "outer," "top," "bottom," "side," "vertical," "horizontal," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate description of the present application and simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application. Furthermore, the terms "a," an, "" the first, "" the second, "" the third, "" the fourth, "" the fifth, "and the sixth" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present application will be understood in specific cases by those of ordinary skill in the art.

For purposes of brevity and description, the principles of the embodiments are described primarily by reference to examples. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the embodiments. It will be apparent, however, to one of ordinary skill in the art that the embodiments may be practiced without limitation to these specific details. In some instances, well-known methods and structures have not been described in detail so as not to unnecessarily obscure the embodiments. In addition, all embodiments may be used in combination with each other.

Embodiment one:

as shown in fig. 1, 2 and 3, this embodiment discloses a heat dissipation and drying device, which includes: the organism 10, organism 10 sets up on the plane, organism 10 includes: the box body 101, the box body 101 is arranged on a plane, and an accommodating space is arranged in the box body 101; a reel 104, the reel 104 is arranged in the box 101, and the reel 104 is movably connected with the box 101; a cable 102, the cable 102 is arranged in the box 101, the cable 102 is connected with the reel 104 in a matching way, and the cable 102 is wound on the periphery of the reel 104; the charging gun 103, the charging gun 103 is arranged on one side of the box body 101, one end of the charging gun 103 is fixedly connected with the cable 102, and a charging port of the charging gun 103 is connected with one side of the box body 101 in a matching way; the number of the reels 104 is two, the number of the cables 102 and the charging guns 103 is two, and the cables 102 and the charging guns 103 are respectively arranged on the left side and the right side of the box body 101; the cover device 20 is arranged on the periphery of the box body 101, the cover device 20 is movably connected with the box body 101, covers the back surface of the box body 101 when not in use, and is positioned above the box body 101 when the cover device 20 is in use; and a drying device 30, wherein the drying device 30 is arranged inside the box 101, and the drying device 30 is fixedly connected with the box 101.

As shown in fig. 3 and 4, the cover device 20 includes: the shielding plate 201, the shielding plate 201 is arranged on the periphery of the case 101, and the shielding plate 201 is movably connected with the case 101; the lifting plate 202, the lifting plate 202 is arranged on the back surface of the box body 101, and the lifting plate 202 is movably connected with the box body 101; a supporting plate 203, the supporting plate 203 is arranged on the surface of the shielding plate 201, the supporting plate 203 is integrally connected with the shielding plate 201, and one end of the supporting plate 203 is connected with the lifting plate 202; the guide column 204, the guide column 204 is arranged on the back of the box body 101, a space is reserved between the guide column 204 and the box body 101, and the guide column 204 is movably connected with the lifting plate 202; the driving motor 205, the driving motor 205 is arranged on the back surface of the box body 101, and the driving motor 205 is connected with the lifting plate 202 in a matching way; the protection casing 206, protection casing 206 sets up in driving motor 205's periphery, protection casing 206 and box 101 fixed connection.

The shielding plate 201 is set to be U-arc, the supporting plate 203 is movably connected with the top end of the lifting plate 202, and the supporting plate 203 can drive the shielding plate 201 to rotate around the center of the top end of the lifting plate 202.

The inside of the guide post 204 is hollow, the lifting plate 202 is positioned in the hollow inside of the guide post 204, and the lifting plate 202 passes through the guide post 204.

The surface of the lifting plate 202 is provided with tooth grooves, the rotating end of the driving motor 205 is provided with a gear, the gear of the driving motor 205 is meshed with the tooth grooves of the lifting plate 202, and the driving motor 205 rotates to control the movement of the shielding plate 201 to be closed. The cover device 20 prevents snow from covering the upper side of the box body 101 to block the heat dissipation opening 308 in winter, and the cover device 20 is matched with the drying device 30, so that when the drying device 30 emits heat outwards, the heat flows out upwards to conduct heat to the cover device 20, the surface of the shielding plate 201 is provided with temperature to melt the snow, and the shielding plate 201 is prevented from being damaged due to the pressure of snow.

As shown in fig. 5, 6, and 7, the drying device 30 includes: the heat collection box 301, the heat collection box 301 is arranged in the box body 101, and the heat collection box 301 is positioned above the reel 104; the first heat-conducting plate 302, the first heat-conducting plate 302 is arranged inside the box body 101, and the first heat-conducting plate 302 is positioned below the heat collection box 301; the heat conduction assembly 303, the heat conduction assembly 303 is arranged above the heat collection box 301, and the heat conduction assembly 303 is fixedly connected with the heat collection box 301; the second heat conducting plate 304, the second heat conducting plate 304 is arranged above the heat conducting component 303, and a space is reserved between the second heat conducting plate 304 and the heat conducting component 303; the first heat-conducting plate 305, the first heat-conducting plate 305 is arranged on one side of the heat collection box 301, and the first heat-conducting plate 305 is connected with the heat collection box 301 in a matching way; the second heat-conducting plate 306, the second heat-conducting plate 306 is set up on another side of the heat-collecting tank 301, the second heat-conducting plate 306 is set up opposite to first heat-conducting plate 305; a drying plate 307, the drying plate 307 being disposed in the middle of the second heat transfer plate 306 and the first heat transfer plate 305; a heat radiation port 308, wherein the heat radiation port 308 is arranged above the box body 101; the heat dissipation components 309, the heat dissipation components 309 are disposed at the left and right sides of the heat collection box 301, and the heat dissipation components 309 are connected with the box 101 in a matching manner.

The first heat-conducting plate 305 and the second heat-conducting plate 306 are in butt joint to form a complete backflow plate, and the second heat-conducting plate 304, the heat-conducting assembly 303, the heat collection box 301 and the first heat-conducting plate 302 are contained in the lower part of the backflow plate; the drying plate 307 is integrally formed with a placement opening of the case 101, and the charging gun 103 is placed inside the drying plate 307.

A fan is arranged in the heat conduction assembly 303, the first heat conduction plate 302 is provided with an arc-shaped surface, and the arc-shaped surface of the first heat conduction plate 302 faces upwards; the second heat conducting plate 304 is provided with an arc surface, the arc surface of the second heat conducting plate 304 faces downwards, and the heat conducting component 303 absorbs heat in the box 101 and is conducted to the heat radiating component 309 through the first heat conducting plate 302 and the second heat conducting plate 304.

The two heat dissipation components 309 are provided, the heat dissipation components 309 comprise heat dissipation fins and heat dissipation plates, a space is reserved between the heat dissipation components 309 and the heat collection box 301 to form a heat channel, and hot air in the heat channel exchanges heat to outside air through the heat dissipation plates and the heat dissipation fins. The inside heat of stake of will charging outwards diverges through drying device 30, simultaneously at the in-process of dispersing for being in the inside rifle 103 that charges of charging stake and carrying out the temperature maintenance, prevent to charge rifle 103 under the static state that does not use, charge rifle 103 surface water smoke because low temperature produces and freezes, charges rifle 103 unable extract and charges the stake and cause the damage when using.

In the above technical solution, the cover device 20 and the drying device 30 are used to generate heat in the casing 101 when the charging pile is used, then the drying device 30 moves the heat to the drying plate 307, the drying plate 307 allows the internal heat to flow out through the heat dissipation port 308, and the heat contacts the shielding plate 201 when the heat flows out of the heat dissipation port 308, the surface of the shielding plate 201 continuously receives the heat, and the surface of the shielding plate 201 is provided with the heat, so that snow can be prevented from being accumulated on the surface of the shielding plate 201 in winter, the situation that the shielding plate 201 is broken due to excessive stress can be avoided, and the charging gun 103 in the casing 101 is continuously heated by the drying device 30, so that the icing phenomenon of the charging gun 103 due to the external temperature can be prevented when the charging gun is stationary.

Embodiment two:

the charging pile is provided with the heat dissipation and drying device in the first embodiment.

Embodiment III:

as shown in the figure, the heat insulation plate 310 is arranged in the drying plate 307, the heat insulation plate 310 is horizontally arranged, four heat insulation plates 310 are arranged, every two heat insulation plates 310 are in a group, each group of heat insulation plates 310 corresponds to one charging gun 103 respectively, the heat insulation plates 310 are connected with the drying plate 307 through springs, a telescopic column 311 is arranged in a placing opening of the box body 101, the telescopic column 311 is connected with the heat insulation plates 310, one end of the telescopic column 311 penetrates through the placing opening of the box body 101, the telescopic column 311 is pushed to move in an oblique direction when the charging gun 103 is inserted into the placing opening of the box body 101, so that the heat insulation plates 310 are driven to move to two sides, and the heat conduction assembly 303 brings hot air into the drying plate 307 to dry and heat the charging gun 103. When the charging gun 103 is positioned in the charging pile through the arranged heat insulation plate 310 and the telescopic column 311, the heat insulation plate 310 can be opened to two sides through the charging gun 103 to enable heat in the heat collection box 301 to flow to the drying plate 307, the opening of the charging gun 103 is heated through the drying plate 307, the charging gun 103 is kept to be continuously provided with heat for preventing, the charging gun 103 is in a static state without use, the charging gun 103 is frozen in the inside due to low temperature and humidity, the charging gun 103 cannot be pulled out when in use, and the charging gun 103 is damaged when forced pulled out.

Embodiment four:

as shown in fig. 8, finally, there is provided a heat dissipation and drying method of a heat dissipation and drying device, comprising the following steps:

the object to be charged is moved to the front of the case, the charging gun 103 is taken out and inserted into a charging port of the object to be charged, heat is generated in the charging pile when the charging gun 103 transmits current to the object to be charged, and heat is also generated at the joint of the charging gun 103 and the charging port of the object to be charged;

when the charging gun 103 is used in winter, current transmission is continuously kept between the charging gun 103 and a charging port of an object to be charged, heat is generated around the charging port of the object to be charged, and water mist in the external environment cannot form icing on the surface of the charging gun 103 due to low temperature;

during charging, heat is also generated in the box 101 due to the transmission of current, the heat in the box 101 is moved upwards by the drying device 30, after the hot air is guided by the fan of the heat conducting component 303, the hot air flows through the second heat conducting plate 304 to move towards the drying plate 307, and the charging gun 103 is not separated from the drying plate 307, so that the heat can move to the left and right sides by the second heat conducting plate 304 and flow out to the outer side of the box 101 by the heat radiating component 309;

when the charging gun 103 at the other end is used, hot air can move to the heat dissipation port 308 through the drying plate 307 without the charging gun 103, excessive internal heat is discharged outwards, and the internal heat of the box body 101 is moved bidirectionally through the drying device 30.

According to the heat dissipation drying device, when the charging pile is used, a large amount of heat energy is generated in the charging pile, the heat in the charging pile is discharged to the outside through the drying device 30, damage caused by overheat in the charging pile is prevented, when the charging gun 103 is positioned in the charging pile in winter, the heat cannot be generated in the charging pile, at the moment, due to the fact that the outside is low temperature, the charging gun 103 is provided with water mist, the charging gun 103 and the charging pile can be frozen, the drying device 30 is used for continuously carrying out heat transfer on the charging gun 103 when the charging gun 103 is positioned in the charging pile, partial heat is kept, the situation that the charging gun 103 and the charging pile are frozen is reduced, and damage to the charging gun 103 caused by forced pulling out of the charging pile when the charging gun 103 is used after freezing is prevented.

While the foregoing describes illustrative embodiments of the present application so that those skilled in the art may understand the present application, the present application is not limited to the specific embodiments, and all applications and creations utilizing the inventive concepts are within the scope of the present application as long as the modifications are within the spirit and scope of the present application as defined and defined in the appended claims to those skilled in the art.

Claims (9)

1. A heat dissipation drying device, comprising:

organism, the organism sets up on the plane, the organism includes:

the box body is arranged on a plane, and an accommodating space is arranged in the box body;

the reel is arranged in the box body and is movably connected with the box body;

the cable is arranged in the box body, is connected with the reel in a matching way and is wound on the periphery of the reel;

the charging gun is arranged on one side of the box body, one end of the charging gun is fixedly connected with the cable, and a charging port of the charging gun is connected with one side of the box body in a matched mode;

the two reels are arranged, the two cables and the two charging guns are arranged, and the cables and the two charging guns are respectively arranged on the left side and the right side of the box body;

the cover device is arranged on the periphery of the box body, is movably connected with the box body, is positioned on the back surface of the box body when not used, and is positioned above the box body when used;

the drying device is arranged in the box body and is fixedly connected with the box body; the heat collection box is arranged in the box body and is positioned above the reel;

the first heat conducting plate is arranged in the box body and is positioned below the heat collecting box;

the heat conduction assembly is arranged above the heat collection box and is fixedly connected with the heat collection box;

the second heat conducting plate is arranged above the heat conducting component, and a space is reserved between the second heat conducting plate and the heat conducting component;

the first heat-conducting plate is arranged on one side of the heat collection box and is connected with the heat collection box in a matched mode;

the second heat-conducting plate is arranged on the other side of the heat collection box and is opposite to the first heat-conducting plate;

the drying plate is arranged between the second heat-conducting plate and the first heat-conducting plate;

the heat dissipation port is arranged above the box body;

the heat dissipation components are arranged on the left side and the right side of the heat collection box and are connected with the box body in a matched mode;

the heat insulation plate is arranged in the drying plate and is horizontally arranged in a transverse direction, and the heat insulation plate is connected with the drying plate through a spring;

the telescopic column is arranged inside the box body and is connected with the heat insulation plate.

2. The heat dissipating and drying device of claim 1, wherein the cover means comprises:

the shielding plate is arranged on the periphery of the box body and is movably connected with the box body;

the lifting plate is arranged on the back surface of the box body and is movably connected with the box body;

the supporting plate is arranged on the surface of the shielding plate, the supporting plate is integrally connected with the shielding plate, and one end of the supporting plate is connected with the lifting plate;

the guide post is arranged on the back of the box body, a space is reserved between the guide post and the box body, and the guide post is movably connected with the lifting plate;

the driving motor is arranged on the back surface of the box body and is connected with the lifting plate in a matched mode; the protection casing, the protection casing sets up driving motor's periphery, the protection casing with box fixed connection.

3. The heat dissipating and drying device according to claim 2, wherein the shielding plate is provided with a U-arc shape, the supporting plate is movably connected with the top end of the lifting plate, and the supporting plate can drive the shielding plate to rotate around the center of the top end of the lifting plate.

4. A heat dissipating and drying device according to claim 3, wherein the guide post is hollow, the lifting plate is located in the hollow of the guide post, and the lifting plate passes through the guide post.

5. The heat dissipating and drying device according to claim 4, wherein the elevating plate has a surface provided with tooth grooves, the rotating end of the driving motor is provided with a gear, the gear of the driving motor is engaged with the tooth grooves of the elevating plate, and the driving motor rotates to control the shutter to move and close.

6. The heat dissipating and drying device according to claim 1, wherein the first heat conducting plate and the second heat conducting plate are in butt joint to form a complete reflow plate, and the second heat conducting plate, the heat conducting assembly, the heat collecting box and the first heat conducting plate are accommodated in the lower part of the reflow plate;

the drying plate and the placing opening of the box body are integrally formed, and the charging gun is placed in the drying plate.

7. The heat dissipating drying device of claim 6, wherein a fan is disposed inside the heat conducting assembly, the first heat conducting plate is provided with an arcuate surface, and the arcuate surface of the first heat conducting plate faces upward;

the second heat conduction plate is provided with an arc-shaped surface, the arc-shaped surface of the second heat conduction plate faces downwards, and the heat conduction assembly absorbs heat in the box body and is conducted to the heat dissipation assembly through the first heat conduction plate and the second heat conduction plate.

8. The heat dissipation and drying device according to claim 7, wherein two heat dissipation components are provided, each heat dissipation component comprises a heat dissipation plate and a heat dissipation plate, a space is reserved between each heat dissipation component and the heat collection box to form a heat channel, and hot air in the heat channel exchanges heat to outside air through the heat dissipation plate and the heat dissipation plate.

9. A charging pile, wherein the charging pile has a heat dissipating and drying device according to any one of the preceding claims 1-8.