KR101399323B1 - Assembly enclosure for inverter - Google Patents

Abstract

The present invention relates to an assembly enclosure for an inverter, which includes a main frame assembly (110) provided therein with internal parts and having openings formed at front, rear, and top surfaces thereof; a roof frame assembly (170) assembled with an upper portion of the main frame assembly (110); a base frame assembly (175) assembled with a lower portion of the main frame assembly (110), a door assembly (180) assembled with a front surface of the main frame assembly (110); and a rear cover assembly (190) assembled with a rear surface of the main assembly (110).

Description

[0001] ASSEMBLY ENCLOSURE FOR INVERTER [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an assembly type enclosure for an inverter, and more particularly, to an enclosure for an inverter, which can be disassembled and assembled, so that installation or maintenance work is much more convenient than before. To an assembled type enclosure for an inverter.

An enclosure is widely used as an equipment for protecting and monitoring an inverter that receives DC power generated from a solar cell module and converts it to AC power.

As described above, these enclosures are used to protect and monitor the inverter. Therefore, it is common that the enclosure is made of a metal material which is strong against external force but does not break easily.

However, in the case of an enclosure currently being applied, it is not easy to install or maintain the enclosure because it is at least partly integrated with at least part of the structure even if it is integrally formed by welding or is not completely integrated. Further, And it is urgent to supplement the structure of the system.

Korea Patent Office Application No. 10-2004-0081078 Korea Patent Office Application No. 10-2002-0029791 Korea Patent Office Application No. 20-1986-0010569 Korea Patent Office Application No. 20-1998-0022678

An object of the present invention is to provide an assembling type enclosure for an inverter that can be disassembled and assembled, so that installation or maintenance work is much more convenient than the conventional one, and in particular, utilization efficiency of the internal space can be maximized due to an efficient structure.

The above object is achieved by a main frame assembly (110) in which a built-in part is provided and an opening is formed on a front surface, a rear surface and an upper surface; A roof frame assembly 170 assembled to the upper portion of the main frame assembly 110; A base frame assembly 175 assembled to a lower portion of the main frame assembly 110; A door assembly 180 assembled to a front surface of the main frame assembly 110; And a rear cover assembly (190) assembled to the rear surface of the main frame assembly (110).

The main frame assembly 110 includes an AC power frame unit 110a provided with internal components related to AC power conversion; And a DC power frame unit 110b in which internal components related to direct current power (DC) conversion are provided.

The AC power frame unit 110a includes: an AC power front frame 120a forming a front surface of the AC power frame unit 110a; An AC power rear frame 130a forming a rear surface of the AC power frame unit 110a; A top frame 140a for AC power forming an upper surface of the AC power frame unit 110a; An AC power bottom frame 150a forming a bottom surface of the AC power frame unit 110a; And a sidewall frame 160a for AC power forming a side surface of the AC power frame unit 110a.

The AC power front frame 120a is formed with first and second AC front frame openings H1 and H2 which are opened in the same size and arranged in the left and right direction. First and second AC power rear frame openings H3 and H4 which are vertically arranged while being opened in different sizes are formed in the top frame 140a for AC power, Can be formed.

The top frame opening 140b may be disposed at an eccentric position to one side in the center region of the AC power tower frame 140a.

The DC power frame unit 110b includes a DC power front frame 120b forming a front surface of the DC power frame unit 110b; A DC power rear frame 130b forming the rear surface of the DC power frame unit 110b; A DC power top frame 140b forming an upper surface of the DC power frame unit 110b; A DC power bottom frame 150b forming a bottom surface of the DC power frame unit 110b; And a sidewall frame 160b for DC power forming a side surface of the DC power frame unit 110b.

First and second DC power front frame openings H6 and H7 are formed in the DC power front frame 120b in different sizes and arranged in the left-right direction. The DC power rear frame 130b, The first and second direct current power rear frame openings H8 and H9 are vertically arranged while being opened to different sizes. The direct current power top frame 140b is provided with a top frame opening H10 May be formed.

The top frame opening 140b may be disposed at an eccentric position to one side in the center area of the DC power top frame 140b.

A plurality of connection fulcrums C1 and C2 for coupling the loop frame assembly 170 may be coupled to the AC power frame unit 110a and the DC power frame unit 110b.

The loop frame assembly 170 includes an AC power loop frame 170a coupled to an upper portion of the AC power frame unit 110a; And a DC power loop frame 170b coupled to an upper portion of the DC power frame unit 110b.

Both of the AC power loop frame 170a and the DC power loop frame 170b include roof plates 171a and 171b of a plate shape forming an upper surface; And a plurality of skirts 172a and 172b extending from the peripheral surfaces of the roof plates 171a and 171b toward the main frame assembly 110. The skirts 172a and 172b have openings 173a , 173b may be formed.

The door assembly 180 includes a plurality of first and second AC power front frame openings H1 and H2 and a plurality of first and second DC power front frame openings H6 and H7, The unit doors 181 to 184 may be provided.

The rear cover assembly 190 includes a unit rear portion that is sequentially assembled to the first and second rear electric power rear frame openings H3 and H4 and the first and second direct electric power rear frame openings H8 and H9, Covers 191-194.

The base frame assembly 175 includes a pair of base walls 175b spaced apart from one another and arranged in parallel and having a plurality of protrusions 175a formed on a surface thereof; A pair of side reinforcement walls 175c coupled to the inner walls of the pair of base walls 175b to reinforce the pair of base walls 175b; A center reinforcement wall 175d arranged in parallel with the side reinforcement wall 175c in a central region of the pair of side reinforcement walls 175c; A pair of end walls (175e) assembled and reinforced at the ends of the pair of base walls (175b) in a direction crossing the base wall (175b); And a plurality of cross reinforcement walls 175f disposed between the pair of end walls 175e to reinforce the pair of side reinforcement walls 175c and the center reinforcement wall 175d .

According to the present invention, since the disassembling and assembling is possible, the installation or maintenance work is much more convenient than the conventional one, and in particular, an assembling type enclosure for an inverter capable of maximizing utilization of the internal space due to an efficient structure is provided.

1 is a perspective view of an assembled enclosure for an inverter according to an embodiment of the present invention.
2 is a front view of Fig.
3 is a bottom view of Fig.
Fig. 4 is a rear view of Fig. 1; Fig.
5 is an exploded perspective view of FIG.
6 is an exploded perspective view of the mainframe assembly.
7 is an enlarged view of the base frame assembly.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

2 is a front view of Fig. 1, Fig. 3 is a bottom view of Fig. 1, Fig. 4 is a rear view of Fig. 1, Fig. 5 is a front view of the enclosure for the inverter according to one embodiment of the present invention, 1 is an exploded perspective view of the main frame assembly, Fig. 6 is an exploded perspective view of the main frame assembly, and Fig. 7 is an enlarged view of the base frame assembly.

Referring to these drawings, since the inverter enclosure 100 according to the present embodiment can be disassembled and assembled, the installation or maintenance work is much more convenient than the conventional one. In particular, due to the efficient structure, the utilization of the internal space can be maximized A main frame assembly 110, a roof frame assembly 170, a base frame assembly 175, a door assembly 180, and a rear cover assembly (not shown) 190, and a rear cover assembly.

The main frame assembly 110 is a main skeleton of the inverter enclosure 100 of the present embodiment in which a built-in component is provided.

Openings are formed on the front, rear, and top surfaces of the mainframe assembly 110, which will be described below.

6, the main frame assembly 110 can be largely divided into an AC power frame unit 110a and a DC power frame unit 110b.

The AC power frame unit 110a forms a place where built-in parts related to AC power conversion are provided, and the DC power frame unit 110b forms a place where built-in parts related to direct current (DC) .

A plurality of connecting fulcrums C1 and C2 for connecting the loop frame assembly 170 are coupled to the upper portion of the AC power frame unit 110a and the DC power frame unit 110b.

Larger ones can be used because the feldspar C2 in the center receives more force than the feldspar C1 in the side.

The concrete structure of the AC power frame unit 110a and the DC power frame unit 110b will be described below.

First, the structure of the AC power frame unit 110a will be described. In the present embodiment, the AC power frame unit 110a includes an AC power front frame 120a forming a front face of the AC power frame unit 110a, an AC power frame 120b forming the rear face of the AC power frame unit 110a, A rear frame 130a for AC power, a top frame 140a for AC power forming an upper surface of the frame unit 110a for AC power, an AC power bottom frame 150a for forming a bottom surface of the frame unit 110a for AC power, And a sidewall frame 160a for an AC power which forms a side surface of the AC power frame unit 110a.

In such a structure, the front frame 120a of the AC power is formed with first and second AC front frame openings H1 and H2 which are opened in the same size and arranged in the left-right direction.

The rear frame 130a for AC power includes first and second rear frame openings H3 and H4 which are opened in different sizes and arranged in the vertical direction. A top frame opening H5 for AC power is formed.

At this time, the top frame opening 140b is disposed at a position eccentrically to one side in the center region of the AC power tower frame 140a. Each of the openings H1 to H5 has a rectangular shape, but need not necessarily be.

Next, the structure of the DC power frame unit 110b will be described. In the present embodiment, the DC power frame unit 110b is manufactured in substantially the same manner as the above-described structure of the AC power frame unit 110a.

The DC power frame unit 110b includes a DC power front frame 120b forming the front surface of the DC power frame unit 110b and a DC power rear frame 120b forming the rear surface of the DC power frame unit 110b. A DC power top frame 140b forming an upper surface of the DC power frame unit 110b, a DC power bottom frame 150b forming a bottom surface of the DC power frame unit 110b, And a sidewall frame 160b for DC power forming a side surface of the power frame unit 110b.

In such a structure, the front frame 120b for direct current power is provided with first and second front frame opening portions H6 and H7 for opening and closing the front and rear faces of the front and rear frames, respectively.

First and second DC power rear frame openings H8 and H9 are formed in the rear frame 130b for DC power and are vertically arranged while being opened to different sizes. In the DC power top frame 140b, A top frame opening H10 for DC power is formed.

At this time, the top frame opening 140b is disposed at a position eccentrically to one side in the center area of the DC power top frame 140b. Each of the openings H6 to H10 has a rectangular shape, but need not necessarily be.

A roof frame assembly 170 is a structure that is assembled on top of the main frame assembly 110.

The loop frame assembly 170 includes an AC power loop frame 170a coupled to an upper portion of an AC power frame unit 110a and a DC power loop frame 170a coupled to an upper portion of the DC power frame unit 110b 170b.

Both the AC power loop frame 170a and the DC power loop frame 170b may have the same structure.

That is, both the AC power loop frame 170a and the DC power loop frame 170b are formed by the plate-shaped loop plates 171a and 171b forming the upper surface, and the loop plates 171a and 171b formed on the circumferential surfaces of the loop plates 171a and 171b, And a plurality of skirts 172a and 172b extending toward the side 110. [

At this time, long skirt openings 173a and 173b may be formed in the plurality of skirts 172a and 172b.

The base frame assembly 175 is assembled to the lower portion of the main frame assembly 110.

The base frame assemblies 175 are spaced apart from one another and are arranged in parallel to each other and are coupled to the inner walls of the pair of base walls 175b and the pair of base walls 175b having a plurality of protrusions 175a formed on the surface thereof A pair of side reinforcement walls 175c for reinforcing the pair of base walls 175b and a center reinforcement wall 175d arranged in parallel with the side reinforcement walls 175c in a central region of the pair of side reinforcement walls 175c A pair of end finishing walls 175e which are assembled and reinforced at the ends of the pair of base walls 175b in the direction intersecting the base wall 175b and a pair of end finishing walls 175e And a plurality of cross reinforcement walls 175f arranged to reinforce the pair of side reinforcement walls 175c and the center reinforcement wall 175d.

Since the base frame assembly 175 has such a structure, it is possible to stably support the upper structures without deformation.

A door assembly 180 is assembled to the front of the main frame assembly 110. The door assembly 180 can be applied as a hinged type, which is not fixed but can be opened or closed.

The door assembly 180 includes a plurality of units (not shown) disposed in sequence in the first and second AC front frame openings H1 and H2 and the first and second DC power front frame openings H6 and H7, Doors 181 - 184.

The unit doors 181 to 184 can be individually rotated to open and close the corresponding openings H1, H2, H6, and H7.

The rear cover assembly 190 is a kind of cover that is assembled to the rear surface of the main frame assembly 110.

The rear cover assembly 190 includes a unit rear cover H3 and H4 which are sequentially assembled to the first and second rear electric power frame rear opening portions H3 and H4 and the first and second direct electric power rear frame opening portions H8 and H9 191-194).

Although the rear cover assembly 190 is opened like the door assembly 180, it is not arbitrarily structured as the door assembly 180.

According to the assembled enclosure 100 for an inverter of the present embodiment having the above-described configuration, disassembly and assembly are possible, so that the installation or maintenance work is much more convenient than before. Especially, the efficiency of the internal space is maximized .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

100: an assembled enclosure for an inverter 110: a main frame assembly
110a: AC power frame unit 110b: DC power frame unit
120a: front frame for AC power 120b: front frame for DC power
130a: Rear frame for AC power 130b: Rear frame for DC power
140a: Top frame for AC power 140b: Top frame for DC power
150a: Bottom frame for AC power 150b: Bottom frame for DC power
160a: AC power side wall frame 160b: DC power side wall frame
170: Loop frame assembly 170a: Loop frame for AC power
170b: Loop frame for DC power 171a, 171b:
172a and 172b: Skirts 173a and 173b:
175: Base frame assembly 180: Door assembly
190: rear cover assembly

Claims (14)

A main frame assembly (110) having a built-in part formed therein and having an opening formed on a front surface, a rear surface, and an upper surface;
A roof frame assembly 170 assembled to the upper portion of the main frame assembly 110;
A base frame assembly 175 assembled to a lower portion of the main frame assembly 110;
A door assembly 180 assembled to a front surface of the main frame assembly 110; And
And a rear cover assembly (190) assembled to the rear surface of the main frame assembly (110)
The main frame assembly (110)
An AC power frame unit 110a provided with internal components related to AC power conversion; And
And a frame unit 110b for DC power in which internal parts related to direct current power (DC) conversion are provided,
The AC power frame unit (110a)
An AC power front frame 120a forming a front surface of the AC power frame unit 110a;
An AC power rear frame 130a forming a rear surface of the AC power frame unit 110a;
A top frame 140a for AC power forming an upper surface of the AC power frame unit 110a;
An AC power bottom frame 150a forming a bottom surface of the AC power frame unit 110a; And
And an AC power sidewall frame (160a) forming a side surface of the AC power frame unit (110a).
delete delete The method according to claim 1,
The AC front frame 120a is formed with first and second AC front frame openings H1 and H2 which are opened in the same size and arranged in the left and right direction,
The rear frame 130a for AC power includes first and second rear frame openings H3 and H4 which are opened in different sizes and arranged in the vertical direction,
And a top frame opening (H5) for AC power is formed in the AC power tower frame (140a).
5. The method of claim 4,
Wherein the top frame opening part (140b) is disposed in a position eccentric to one side of the center area of the AC power top frame (140a).
6. The method of claim 5,
The DC power frame unit (110b)
A DC power front frame 120b forming a front surface of the DC power frame unit 110b;
A DC power rear frame 130b forming the rear surface of the DC power frame unit 110b;
A DC power top frame 140b forming an upper surface of the DC power frame unit 110b;
A DC power bottom frame 150b forming a bottom surface of the DC power frame unit 110b; And
And a sidewall frame (160b) for DC power forming a side surface of the DC power frame unit (110b).
The method according to claim 6,
First and second DC power front frame openings H6 and H7, which are opened in different sizes and arranged in the left and right direction, are formed in the DC power front frame 120b,
First and second direct-current power rear frame openings H8 and H9 are formed in the direct-current power rear frame 130b in different sizes and arranged in the vertical direction,
And a top frame opening (H10) for direct current power is formed in the top frame for direct current power (140b).
8. The method of claim 7,
Wherein the top frame opening part (140b) is disposed in a position eccentric to one side in the center area of the DC power top frame (140b).
The method according to claim 1,
And a plurality of connection firs C1 and C2 for connecting the loop frame assembly 170 are coupled to the AC power frame unit 110a and the DC power frame unit 110b. (100).
The method according to claim 1,
The loop frame assembly (170)
An AC power loop frame 170a coupled to an upper portion of the AC power frame unit 110a; And
And a loop frame (170b) for DC power coupled to an upper portion of the DC power frame unit (110b).
11. The method of claim 10,
Both of the AC power loop frame 170a and the DC power loop frame 170b,
Roof plates (171a, 171b) of a plate-like body forming an upper surface; And
And a plurality of skirts 172a and 172b extending from the circumferential surfaces of the roof plates 171a and 171b toward the main frame assembly 110,
Wherein the plurality of skirts (172a, 172b) are formed with openings (173a, 173b) of long holes.
8. The method of claim 7,
The door assembly 180 includes a plurality of first and second AC power front frame openings H1 and H2 and a plurality of first and second DC power front frame openings H6 and H7, Of the unit doors (181 to 184) for the inverter.
8. The method of claim 7,
The rear cover assembly 190 includes a unit rear portion that is sequentially assembled to the first and second rear electric power rear frame openings H3 and H4 and the first and second direct electric power rear frame openings H8 and H9, And a cover (191 to 194).
The method according to claim 1,
The base frame assembly 175 includes:
A pair of base walls 175b spaced apart from one another and arranged side by side and having a plurality of protrusions 175a formed on the surface thereof;
A pair of side reinforcement walls 175c coupled to the inner walls of the pair of base walls 175b to reinforce the pair of base walls 175b;
A center reinforcement wall 175d arranged in parallel with the side reinforcement wall 175c in a central region of the pair of side reinforcement walls 175c;
A pair of end walls (175e) assembled and reinforced at the ends of the pair of base walls (175b) in a direction crossing the base wall (175b); And
And a plurality of intersecting reinforcing walls 175f arranged in a plurality of spaces between the pair of end walls 175e to reinforce the pair of side reinforcing walls 175c and the center reinforcing walls 175d. (100). ≪ / RTI >

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