CN223559512U - An installation structure for a charging pile power module - Google Patents

Abstract

The utility model discloses a mounting structure of a charging pile power supply module, which comprises a charging pile body, two frame plates, a clamping plate and a clamping plate, wherein the charging pile body is provided with a cavity, the two frame plates are symmetrically distributed on two opposite sides in the cavity, the two frame plates are respectively provided with a connecting structure and a limiting structure, the connecting structure is fixedly connected with the inner wall of the cavity through a fastener, the limiting structures of the two frame plates are respectively used for limiting two opposite sides of the power supply module vertically mounted in the cavity, the clamping plate is clamped in the bottom areas of the two frame plates and used for bearing the weight of the power supply module, and the clamping plate is connected with the two frame plates through the fastener. In the utility model, the power module is not fixed by using the mounting plate of the power module, and the weight of the power module is born by the clamping plate, so that the power module is more reliable to mount, the mounting structure is relatively simple, the occupied space is small, and the power module is more convenient to dismount and replace.

Description

Mounting structure of charging pile power module

Technical Field

The utility model relates to the field of new energy automobile charging equipment, in particular to a mounting structure of a charging pile power supply module.

Background

With the popularization of new energy automobiles, direct current charging piles for rapidly charging new energy automobiles are also more widely used. The direct current charging pile generally uses a power module, and the main function of the power module is to convert alternating current commercial power into direct current capable of charging a battery, so that the direct current charging pile is a core component of the direct current charging pile. The power module is large in size and heavy in weight, so that the installation structure of the power module has important influences on the performance, appearance, cost and the like of the charging pile.

The installation of the charging pile power module needs to be careful about the following problems that (1) the power module is heavy in weight and reliable in installation and fixation, (2) the power module needs to be installed, disassembled and replaced conveniently, and (3) the heat dissipation air inlet and air outlet of the power module need to be ensured to be smooth after the power module is installed.

At present, partly fill electric pile power module and can pull out plug-in installation with the horizontal direction, when using this kind of scheme, because the module itself is rectangular, fill electric pile in order to hold the module that charges, whole horizontal width can be great, influences and fills electric pile whole pleasing to the eye. Still some fill electric pile power module can be with vertical direction plug-in installation, and when using this kind of scheme, fill electric pile fuselage whole narrower, it is relatively pleasing to the eye, but power module inserts the back and generally uses self panel screw hole fixed, does not have extra support, and the installation is unreliable, or the module inserts the back and fixes the lock in the mode of tying up or compressing tightly in the side, and the structure is complicated relatively, occupation space is great, dismantles and changes the difficulty.

Disclosure of utility model

In order to solve the above problems, the present utility model provides a mounting structure of a power module of a direct current charging pile, which can ensure the mounting reliability, low space occupation and easy disassembly and replacement of the power module when the power module is mounted in a vertical direction in a plug-in manner.

The utility model provides a mounting structure of a charging pile power supply module, which comprises the following components:

The charging pile body is provided with a cavity;

the two frame plates are symmetrically distributed on two opposite sides in the cavity, and are respectively provided with a connecting structure and a limiting structure, wherein the connecting structure is fixedly connected with the inner wall of the cavity through a fastener, and the limiting structures of the two frame plates are respectively used for limiting two opposite sides of a power module vertically installed in the cavity;

The clamping plates are clamped in the bottom areas of the two frame plates and used for bearing the weight of the power supply module, and the clamping plates are connected with the two frame plates through fasteners.

Further, the connecting structure comprises a first connecting surface and a second connecting surface;

the first connecting surface is fixedly connected with the inner wall at the rear side of the cavity through a fastener;

One of the second connecting surfaces of the frame plates is fixedly connected with the inner wall on the left side of the cavity through a fastener, and the other second connecting surface of the frame plate is fixedly connected with the inner wall on the right side of the cavity through a fastener.

Further, one of the limit structures of the frame plate limits the left side wall of the power module and the front side wall and the rear side wall near the left side wall in a coating mode, and the other limit structure of the frame plate limits the right side wall of the power module and the front side wall and the rear side wall near the right side wall in a coating mode.

Further, the limiting structure comprises a first limiting surface, a second limiting surface and a third limiting surface;

The first limiting surface of one frame plate is used for limiting the left side wall of the power supply module, and the first limiting surface of the other frame plate is used for limiting the right side wall of the power supply module;

The second limiting surface is used for limiting the rear side wall of the power module;

The third limiting surface is used for limiting the front side wall of the power module.

Further, the mounting structure further comprises a power module connecting surface, a first connecting hole is formed in the power module connecting surface, and the first connecting hole corresponds to a positioning hole in the mounting plate on the lower side of the power module and is connected through a fastener.

Further, the first limiting surface is of a planar structure, the front side and the rear side of the first limiting surface are long sides, and the upper side and the lower side of the first limiting surface are wide sides;

The first connecting surface is also of a plane structure, the first connecting surface is connected with the long edge at the rear side of the first limiting surface, and the first connecting surface is mutually perpendicular to the first limiting surface;

The third limiting surface is also of a plane structure, the third limiting surface is connected with the long side of the front side of the first limiting surface, and the third limiting surface is parallel to the first connecting surface;

A boss protruding towards one side close to the power module is formed on one side, away from the first limiting surface, of the first connecting surface, the second limiting surface is a protruding surface of the boss, and the protruding surface is parallel to the first connecting surface;

The power module connecting surface is also of a planar structure, is connected to the wide edge of the lower side of the first limiting surface, is perpendicular to the first limiting surface and deviates to one side deviating from the first connecting surface;

The second connecting surface is also of a plane structure, and is connected to one side, far away from the first limiting surface, of the power module connecting surface and is parallel to the first limiting surface.

Further, a clamping groove is formed in the bottom area of the boss, and the clamping direction of the clamping groove is perpendicular to the second limiting surface.

Further, the clamping plate comprises a vertical surface, a narrow top surface and a wide bottom surface;

The vertical face, the narrow top face and the wide bottom face enable the clamping plate to form a structure with a narrow top and a wide bottom and approximately in a U shape;

When the narrow top surface is inserted into the clamping groove, the top of the wide bottom surface is attached to the bottom of the boss, and the top of the narrow top surface is used for being attached to the bottom of the power module in order to bear the weight of the power module.

Further, a cover plate is arranged at the bottom of the boss, and a second connecting hole is formed in the cover plate;

the wide bottom surface is provided with a waist hole, and the waist hole corresponds to the second connecting hole and is connected through a fastener.

Further, the frame plate is formed by bending sheet metal or is assembled from two or even more mutually independent parts.

Further, the fastener is a screw.

The beneficial effects of the utility model are as follows:

In the embodiment, after the power module is inserted between the two frame plates from bottom to top, and then is clamped into the clamping plate along the clamping direction of the clamping groove, at the moment, even if the lower side mounting plate of the power module and the clamping plate are not connected by using screws, the lower side mounting plate of the power module is supported by the clamping plate, so that the power module can not slide down from between the two frame plates;

In addition, the power module is supported by the clamping plate after being installed, and screws are not directly supported, so that the screws are not influenced by the weight of the power module, even if the screws connected to the clamping plate and the mounting plate at the lower side of the power module are loosened, the power module cannot displace, the weight of the power module can still be pressed on the clamping plate to obtain the support of the clamping plate, and the clamping plate can be limited by the clamping groove and cannot fall off easily;

Secondly, because the narrow top surface width of cardboard is narrower, only supports the edge of power module downside mounting panel, does not form the ventilation hole at downside mounting panel middle part and shelters from, consequently can not influence power module's ventilation heat dissipation.

Drawings

FIG. 1 is an exploded view of an embodiment of the present utility model;

Fig. 2 is a schematic view of the structure of a frame plate in the embodiment of the present utility model, which shows the structure of the frame plate on the left side and the structure of the frame plate on the right side symmetrical to each other;

FIG. 3 is a state diagram of the embodiment of the present utility model when the clamping plates are not clamped into the clamping grooves of the two frame plates;

fig. 4 is a state diagram of the card board when the card board is clamped into the clamping grooves of the two frame plates on the basis of fig. 3;

FIG. 5 is a diagram of one embodiment of the present utility model during installation;

FIG. 6 is a second illustration of an installation process according to an embodiment of the present utility model;

FIG. 7 is a third illustration of an installation process of an embodiment of the present utility model;

Fig. 8 is a diagram of a fourth embodiment of the present utility model during installation.

Detailed Description

The present utility model will be described in further detail with reference to specific examples, but embodiments of the present utility model are not limited thereto.

Examples:

The embodiment provides a mounting structure of a charging pile power module, which comprises a charging pile body 100, two frame plates 200 and a clamping plate 300.

The charging pile body 100 is provided with a cavity 110, an opening is formed at the bottom of the cavity 110, and the power module 600 of the charging pile can be vertically installed in the cavity 110 from bottom to top.

Two of the frame plates 200 are symmetrically disposed on opposite sides of the cavity 110. The two frame plates 200 are provided with a connecting structure and a limiting structure, the connecting structure is fixedly connected with the inner wall of the cavity 110 through a fastener, and the limiting structures of the two frame plates 200 are respectively used for limiting two opposite sides of the power module 600 vertically installed in the cavity 110.

The clamping plates 300 are clamped at the bottom areas of the two frame plates 200 and are used for bearing the weight of the power module 600, and the clamping plates 300 are connected with the two frame plates 200 through fasteners.

With respect to the frame plate 200, in a preferred embodiment, as shown in fig. 2, the connection structure includes a first connection face 210 and a second connection face 220.

The first connecting surface 210 is fixedly connected with the inner wall of the rear side of the cavity 110 by a fastener. That is, at least one first mounting hole 211 is provided on the first connection surface 210, and a first fixing hole 120 corresponding to the first mounting hole 211 is provided on a wall surface of the rear side of the cavity 110.

The second connecting surface 220 of one of the frame plates 200 is fixedly connected with the inner wall on the left side of the cavity 110 through a fastener, and the second connecting surface 220 of the other frame plate 200 is fixedly connected with the inner wall on the right side of the cavity 110 through a fastener. That is, at least one second mounting hole 221 is provided on the second connection surface 220, and second fixing holes 130 corresponding to the second mounting holes 221 are provided on the wall surfaces of the left and right sides of the cavity 110.

When the frame plate 200 is installed, the frame plate 200 is firstly placed into the cavity 110 of the charging pile body 100, then the first connecting surface 210 is aligned with the inner wall at the rear side of the cavity 110, and meanwhile the second connecting surface 220 is aligned with the inner wall at the left side or the right side of the cavity 110, then the first connecting surface 210 is fixedly connected with the inner wall at the rear side of the cavity 110 by penetrating the first fixing holes 120 and the first mounting holes 211 through screws, the second fixing holes 130 and the second mounting holes 221 through screws, and the second connecting surface 220 is fixedly connected with the inner wall at the left side or the right side of the cavity 110, so that the installation of the frame plate 200 can be completed.

In a preferred embodiment, one of the limiting structures of the frame plate 200 limits the left sidewall and the front sidewall and the rear sidewall near the left sidewall of the power module 600 in a coating manner, and the other limiting structure of the frame plate 200 limits the right sidewall and the front sidewall and the rear sidewall near the right sidewall of the power module 600 in a coating manner.

Specifically, as shown in fig. 2, the limiting structure includes a first limiting surface 230, a second limiting surface 240, and a third limiting surface 250.

The first limiting surface 230 of one frame plate 200 is used for limiting the left side wall of the power module 600, and the first limiting surface 230 of the other frame plate 200 is used for limiting the right side wall of the power module 600. The second limiting surface 240 is used for limiting the rear sidewall of the power module 600. The third limiting surface 250 is used for limiting the front sidewall of the power module 600.

Preferably, as shown in fig. 2, the mounting structure further includes a power module connection surface 260, a first connection hole 261 is provided on the power module connection surface 260, and the first connection hole 261 corresponds to a positioning hole 611 on the mounting plate 610 on the lower side of the power module 600 and is connected by a fastener.

In a preferred embodiment, as shown in fig. 2, the first limiting surface 230 has a planar structure, and the front and rear sides of the first limiting surface 230 are long sides, and the upper and lower sides are wide sides. The first connecting surface 210 is also a planar structure, the first connecting surface 210 is connected to a long edge of the rear side of the first limiting surface 230, and the first connecting surface 210 is perpendicular to the first limiting surface 230. The third limiting surface 250 is also in a planar structure, the third limiting surface 250 is connected to the long edge of the front side of the first limiting surface 230, and the third limiting surface 250 is parallel to the first connecting surface 210. A boss c protruding toward a side close to the power module 600 is formed on a side of the first connection surface 210 away from the first limiting surface 230, and the second limiting surface 240 is a protruding surface of the boss c, and the protruding surface is parallel to the first connection surface 210. The power module connecting surface 260 is also a planar structure, and the power module connecting surface 260 is connected to the broad side of the lower side of the first limiting surface 230 and perpendicular to the first limiting surface 230 and is biased to a side facing away from the first connecting surface 210. The second connecting surface 220 is also a planar structure, and the second connecting surface 220 is connected to a side of the power module connecting surface 260 away from the first limiting surface 230 and parallel to the first limiting surface 230.

In a preferred embodiment, as shown in fig. 2, a clamping groove c1 is formed in the bottom area of the boss c, and the clamping direction of the clamping groove c1 is perpendicular to the second limiting surface 240.

Further, referring to fig. 3 and 4, the card 300 includes a vertical surface 310, a narrow top surface 320, and a wide bottom surface 330. The narrow top surface 320 is connected to the top of the card vertical surface 310, and the wide bottom surface 330 is connected to the bottom of the card vertical surface 310. The vertical surface 310, narrow top surface 320 and wide bottom surface 330 form the card 300 into a structure that is narrow at the top, wide at the bottom and generally U-shaped. Referring to fig. 4, when the narrow top surface 320 is inserted into the card slot c1, the top of the wide bottom surface 330 is attached to the bottom of the boss c, and the top of the narrow top surface 320 is used to be attached to the bottom of the power module 600, so as to bear the weight of the power module 600. At the same time, the narrow top surface 320 is narrower in width, which is necessary to ensure that the vent holes 612 in the middle of the mounting plate 610 on the underside of the power module 600 are not obscured.

Preferably, as shown in fig. 2 and 3, a cover plate 270 is disposed at the bottom of the boss c, and a second connection hole 271 is disposed on the cover plate 270. The wide bottom 330 is provided with a waist hole 331, and the waist hole 331 corresponds to the second connection hole 271 and is connected by a fastener.

Preferably, as shown in fig. 2, a limit stop 280 is further connected to the upper side of the first limit surface 230, and the limit stop 280 is perpendicular to the first limit surface 230 and is biased toward a side close to the first connection surface 210.

In this embodiment, the frame plate 200 may be formed by bending a sheet metal (as shown in fig. 2) multiple times, or may be assembled by two or more independent components, and the assembly may be welded or screwed.

Typically, the fasteners are screws.

The application method of the embodiment is as follows:

During installation, two frame plates 200 are firstly installed in the cavity 110 of the charging pile body 100, the first connecting surface 210 is enabled to be in alignment with the inner wall at the rear side of the cavity 110, and the second connecting surface 220 is enabled to be in alignment with the inner wall at the left side or the right side of the cavity 110;

Then, the power module 600 is placed into the cavity 110 of the charging pile body 100, in the placing process, the left side wall of the power module 600 is close to the first limiting surface 230 of the left side frame plate 200, the right side wall of the power module 600 is close to the first limiting surface 230 of the right side frame plate 200, the second limiting surfaces 240 of the two frame plates 200 are close to the left and right sides of the rear side wall of the power module 600, and the third limiting surfaces 250 of the two frame plates 200 are close to the left and right sides of the front side wall of the power module 600, and meanwhile, when the power module 600 is placed in place, the lower side mounting plate 610 of the power module 600 is also close to the power module connecting surfaces 260 of the two frame plates 200, so that the power module 600 is limited between the two frame plates 200, as shown in fig. 6;

then, installing the clamping plate 300, wherein in the installation process, the narrow top surfaces 320 of the clamping plate 300 are simultaneously inserted into the clamping grooves c1 at the bottoms of the two frame plates 200, and after the clamping plate 300 is inserted, the wide bottom surfaces 330 of the clamping plate 300 are close to the cover plates 270 at the bottoms of the two frame plates 200;

the lower mounting plate 610 of the power module 600 is then coupled and fixed to the power module coupling face 260 of the frame plate 200 by passing the screws 400 through the positioning holes 611 of the lower mounting plate 610 of the power module 600 and the first coupling holes 261 of the frame plate 200, and simultaneously, the clamping plate 300 is coupled and fixed to the frame plate 200 by passing the screws 400 through the waist holes 331 of the clamping plate 300 and the second coupling holes 271 of the frame plate 200, as shown in fig. 8, in which the screws 400 coupled to the lower mounting plate 610 are used only to position the power module 600 and the screws 400 coupled to the clamping plate 300 are used only to fix the clamping plate 300, neither screws 400 bear the weight of the power module 600, and the weight of the power module 600 is borne by the narrow top face 320 of the clamping plate 300 which is caught in the catching groove c1, so that the screws 400 are hardly affected by the weight of the power module 600.

It can be seen that, in the present embodiment, after the power module 600 is inserted between the two frame plates 200 from bottom to top, and then is clamped into the clamping plate 300 along with the clamping direction of the clamping groove c1, even if the lower mounting plate 610 of the power module 600 and the clamping plate 300 are connected without using the screws 400, the lower mounting plate 610 of the power module 600 is supported by the clamping plate 300, so that the power module 600 can be ensured not to slide down from between the two frame plates 200. Therefore, the power module 600 is not fixed by using the mounting plate of the power module 600, the screws 400 on the mounting plate 610 at the lower side only play a role in positioning and do not bear the weight of the power module 600, so that the power module 600 is reliable in mounting, the mounting structure is relatively simple, the occupied space is small, the power module 600 is convenient to detach and replace, and the power module 600 can be detached and replaced by only unscrewing the screws 400 connected to the clamping plate 300 and the mounting plate 610 at the lower side of the power module 600 and then detaching the clamping plate 300.

In addition, since the power module 600 is supported by the card 300 after being mounted, the screws are not directly supported, and thus the screws are not affected by the weight of the power module 600, in the use process, even if the screws 400 connected to the card 300 and the mounting plate 610 at the lower side of the power module 600 are loosened, the power module 600 will not displace, the weight of the power module will still be pressed on the card 300 to obtain the support of the card 300, and the card 300 will be limited by the clamping groove c1 and will not fall easily.

Second, since the narrow top surface 320 of the card 300 has a narrow width, only the edge of the lower mounting plate 610 of the power module 600 is supported, and the ventilation hole 612 in the middle of the lower mounting plate 610 is not blocked, so that the ventilation and heat dissipation of the power module 600 are not affected.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, and various modifications and variations may be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (10)

1. A mounting structure of a charging pile power module, comprising:

The charging pile body (100) is provided with a cavity (110);

The two frame plates (200) are symmetrically distributed on two opposite sides in the cavity (110), the two frame plates (200) are respectively provided with a connecting structure and a limiting structure, the connecting structure is fixedly connected with the inner wall of the cavity (110) through a fastener, and the limiting structures of the two frame plates (200) are respectively used for limiting two opposite sides of a power module (600) vertically installed in the cavity (110);

And the clamping plates (300) are clamped at the bottom areas of the two frame plates (200) and are used for bearing the weight of the power supply module (600), and the clamping plates (300) are connected with the two frame plates (200) through fasteners.

2. The mounting structure of a charging pile power module according to claim 1, characterized in that the connection structure comprises a first connection face (210) and a second connection face (220);

the first connecting surface (210) is fixedly connected with the inner wall of the rear side of the cavity (110) through a fastener;

The second connecting surface (220) of one frame plate (200) is fixedly connected with the inner wall on the left side of the cavity (110) through a fastener, and the second connecting surface (220) of the other frame plate (200) is fixedly connected with the inner wall on the right side of the cavity (110) through a fastener.

3. The mounting structure of a charging pile power module according to claim 2, wherein the limit structure of one of the frame plates (200) limits the left side wall and the front and rear side walls near the left side wall of the power module (600) in a coating manner, and the limit structure of the other frame plate (200) limits the right side wall and the front and rear side walls near the right side wall of the power module (600) in a coating manner.

4. A mounting structure of a charging pile power module according to claim 3, characterized in that the limit structure comprises a first limit surface (230), a second limit surface (240) and a third limit surface (250);

The first limiting surface (230) of one frame plate (200) is used for limiting the left side wall of the power module (600), and the first limiting surface (230) of the other frame plate (200) is used for limiting the right side wall of the power module (600);

the second limiting surface (240) is used for limiting the rear side wall of the power module (600);

The third limiting surface (250) is used for limiting the front side wall of the power module (600).

5. The mounting structure of a charging pile power module according to claim 4, further comprising a power module connection surface (260), wherein a first connection hole (261) is provided on the power module connection surface (260), and the first connection hole (261) corresponds to a positioning hole (611) on a lower mounting plate (610) of the power module (600) and is connected by a fastener.

6. The mounting structure of a charging pile power module according to claim 5, wherein the first limiting surface (230) has a planar structure, and the front and rear sides of the first limiting surface (230) are long sides, and the upper and lower sides are wide sides;

the first connecting surface (210) is also of a planar structure, the first connecting surface (210) is connected with a long edge at the rear side of the first limiting surface (230), and the first connecting surface (210) is mutually perpendicular to the first limiting surface (230);

the third limiting surface (250) is also of a planar structure, the third limiting surface (250) is connected with the long edge of the front side of the first limiting surface (230), and the third limiting surface (250) is parallel to the first connecting surface (210);

a boss (c) protruding towards one side close to the power module (600) is formed on one side, away from the first limiting surface (230), of the first connecting surface (210), the second limiting surface (240) is a protruding surface of the boss (c), and the protruding surface and the first connecting surface (210) are parallel to each other;

The power module connecting surface (260) is also of a planar structure, and the power module connecting surface (260) is connected to the wide edge of the lower side of the first limiting surface (230) and is perpendicular to the first limiting surface (230) and deviates to the side away from the first connecting surface (210);

The second connecting surface (220) is also of a planar structure, and the second connecting surface (220) is connected to one side, away from the first limiting surface (230), of the power module connecting surface (260) and is parallel to the first limiting surface (230).

7. The mounting structure of a charging pile power module according to claim 6, wherein a clamping groove (c 1) is provided in a bottom area of the boss (c), and a clamping direction of the clamping groove (c 1) is perpendicular to the second limiting surface (240).

8. The mounting structure of a charging pile power module according to claim 7, wherein the clamping plate (300) comprises a vertical face (310), a narrow top face (320) and a wide bottom face (330);

The vertical surface (310), the narrow top surface (320) and the wide bottom surface (330) enable the clamping plate (300) to form a structure with a narrow top, a wide bottom and a U shape;

When the narrow top surface (320) is inserted into the clamping groove (c 1), the top of the wide bottom surface (330) is attached to the bottom of the boss (c), and the top of the narrow top surface (320) is used for being attached to the bottom of the power module (600) in order to bear the weight of the power module (600).

9. The mounting structure of a charging pile power module according to claim 8, wherein a cover plate (270) is provided at the bottom of the boss (c), and a second connection hole (271) is provided on the cover plate (270);

The wide bottom surface (330) is provided with a waist hole (331), and the waist hole (331) corresponds to the second connecting hole (271) and is connected through a fastener.

10. A mounting structure of a charging pile power module according to claim 1, characterized in that the frame plate (200) is formed by bending sheet metal or is assembled from two or even more mutually independent parts.