KR101427209B1 - Inverter module connection structure - Google Patents

Abstract

The present invention relates to an inverter module connection structure whereby an inverter module is connected to an inverter slot in an inverter connection board. A DC input terminal and an AC output terminal protruding from a rear surface of the inverter module includes: a plurality of module bus bars protruding from the rear of the inverter module, an insulating mold member covering an upper surface of the module bus bars and exposing a lower surface of the bus bar, and an insulating support member separately placed on a lower part of the module bus bars. A DC connection terminal and an AC connection terminal of the inverter slot connected to the DC input terminal and AC output terminal of the inverter module includes a slot bus bar placed in a direction crossing the module bus bar and an elastic support piece protruding from the slot bus bar to elastically touch the lower surface of the module bus bar having the lower surface supported by the insulating support member. According to the present invention, the inverter module is easily connected to the inverter slot, a strong connection state is maintained in accordance to an elastic surface touch structure of a connection place; and by not using a bolt combination structure to the connection place, the acceptance and withdrawal of the inverter module are easy and damage to the inverter module caused by bolt combination is prevented as well. When the inverter module is not functioning, only the inverter module having malfunction is separated and fixated such that maintenance is quickly done. An electric shock is prevented during the maintenance and check of the connection board since the connection is made on the rear surface of the inverter module.

Description

[0001] INVERTER MODULE CONNECTION STRUCTURE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a connection structure between an inverter module and an inverter slot, and more particularly, to a connection structure of an inverter module having a structure in which an inverter module can be easily attached to and detached from an inverter slot.

Recently, the demand for energy has been increasing worldwide, and the energy crisis such as global warming due to continuous use of fossil fuels, depletion of fossil fuels, and high oil prices are in trouble. As a result, many efforts have been made to change the paradigm of electric power industry using renewable energy. As a result, the number of distributed power systems has increased, especially in the area of renewable energy. Further research into micro grid systems (smart grids) and smart grids (distributed grids) has been actively conducted.

Renewable energy generation facilities, such as photovoltaic power generation systems, consist of an inverter that converts DC power obtained from renewable energy sources into AC power, and equipment that supplies the output of the inverter to the grid or load. Generally, these power generation facilities accommodate a plurality of inverter modules, a battery or an ESS (Energy Storage System) is connected to the DC input terminal of the inverter module, and devices such as a filter and a transformer for supplying stable power are connected to the AC output terminal do.

1 is a front view illustrating an installation state of an inverter module in a conventional inverter connection panel. A plurality of inverter modules (10) are accommodated in the cubicle of the inverter connection section. The DC input terminal 12 and the AC output terminal 14 are exposed to the front portion of the inverter module 10 and the bus bars 16 in the horizontal direction are commonly connected to the terminals of the various inverter modules 10. [ At this time, as shown in the figure, the DC input terminal 12 and the AC output terminal 14 are connected to the bus bar 16 by bolting.

However, since the conventional inverter module 10 has a structure in which various terminals are fastened to the front surface of the inverter module 10 in a state of being housed in a cubicle as shown in the figure, a heat dissipation means is provided behind the inverter module 10, There is a problem. Generally, the power devices installed in the inverter module 10 generate heat at a high temperature, causing problems such as failure due to heat generation or failure of other components. To solve these problems, a heat dissipation fan is mounted. However, the space behind the inverter module is narrow and the heat exchange with the outside air is not smooth. In addition, a gap is generated at the assembling position of the inverter module 10 and the heat-dissipating fan, and the heat inside the inverter module 10 leaks through the gap, and the heat-dissipating efficiency deteriorates even though the heat-dissipating fan is installed.

When the failure occurs in any of the inverter modules 10 due to the common connection of the terminals to the bus bars 16 on the front surface of the inverter module 10, all the bolts of the bus bars 16 connected in common are dismantled Therefore, it is very troublesome and complicated to separate and reinstall the inverter module 10 when the inverter module 10 is to be maintained, because the failed inverter module 10 can be removed. In addition, the internal components of the inverter module 10 may be damaged due to the impact generated in the process of fastening the bolts to the respective terminals of the inverter module 10, and the inverter module 10 and the bus bar 16 may be damaged. There is a problem in that there is a high risk of an electric shock accident when performing maintenance and inspection work.

The present invention is a simple operation of inserting the inverter module into the inverter slot by positioning the input / output terminal of the inverter module on the back surface of the inverter module, making the input / output terminal and the connection terminal of the corresponding inverter slot resiliently in surface contact, Connection of the inverter module can be performed and the bolt fastening structure can be eliminated at the terminal connection site to prevent the inverter component from being damaged by the bolt fastening. Connection of the inverter module is made at the rear side of the module, And a connection structure of an inverter module that can prevent an electrical safety accident of the inverter module.

Another object of the present invention is to provide a connection structure of an inverter module in which a heat dissipation unit is positioned on a front surface of the inverter module and the heat dissipation fan unit is airtightly assembled to increase the heat dissipation effect of the inverter module.

Another object of the present invention is to insert and pull out the inverter module by inserting the inverter module in a slide manner with respect to the inverter slot, and to securely fix the position of the inverter module without clearance.

The connection structure of the inverter module according to the embodiment of the present invention is characterized in that the inverter module is connected to the inverter slot in the inverter connection module. The connection structure of the inverter module includes a DC input terminal protruding from the back surface of the inverter module, The output terminal includes a plurality of module busbars each protruding rearward of the inverter module, an insulating mold member covering an upper surface of the module busbar and exposing a lower surface thereof, and an insulation support member spaced downwardly from the module busbar Wherein the DC connection terminal and the AC connection terminal of the inverter slot to which the DC input terminal and the AC output terminal of the inverter module are connected respectively have a slot bus bar arranged in a direction crossing the module bus bar, And is upwardly protruded so as to elastically contact the lower surface of the module booth bar Includes an elastic supporting piece which is supported by said insulating support member.

According to another aspect of the present invention, there is provided an inverter module connection structure, comprising: a plurality of elastic conductors having a bottom surface contacting the slot bus bar and having an elastic restoring force upward; And a fixing bracket for press-fixing on the bar.

According to still another aspect of the present invention, there is provided a connection structure of an inverter module, wherein a frame insulating member is interposed between the slot boss and a frame of the inverter slot, and an inter-phase insulating member is interposed between the slot bus bars of the AC connection terminal of the inverter slot .

In a connection structure of an inverter module according to another embodiment of the present invention, the DC input terminal and the AC output terminal of the inverter module have the same shape.

According to another embodiment of the present invention, an upper surface of the distal end portion of the insulator support member is incised so as to form an insertion guide surface for guiding insertion of the inserting support member.

According to another aspect of the present invention, there is provided a structure for connecting an inverter module, wherein guide rails are formed on both sides of an upper surface and a lower surface of the inverter module, And the inverter module is inserted / removed in a sliding manner with respect to the inverter slot.

According to another aspect of the present invention, there is provided a connection structure of an inverter module, wherein a plurality of frictional relief protrusions for relieving frictional force with the inverter module bottom surface are protruded upward from a lower surface of the inverter slot.

According to another aspect of the present invention, there is provided a connection structure of an inverter module, wherein a rear upper surface of the inverter module is sloped to form an insertion guide slant portion for guiding insertion of the inverter module into the guide groove on the upper surface of the inverter slot.

According to another aspect of the present invention, there is provided a connection structure of an inverter module, wherein a heat dissipation unit is provided on a front surface of the inverter module, a heat dissipation fan unit is airtightly assembled to the heat dissipation unit via a sealing member, The fan unit includes: a box-shaped heat radiating fan unit having a rear opening and communicating with the heat radiating portion; And a heat dissipating fan installed in the heat dissipating fan unit and discharging the heat transferred from the heat dissipating unit to the outside.

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According to the connection structure of the inverter module of the present invention, it is possible to easily connect the inverter module to the inverter slot, maintain a solid connection state according to the elastic surface contact structure of the connection point, and do not use the bolt fastening structure at the connection point This makes it easy to store and retrieve the inverter module, prevent damage to the inverter module due to the bolt fastening, and repair and disassemble the inverter module only when the inverter module fails. , Since the connection is made from the back side of the inverter module, there is an effect that an electric shock accident can be prevented at the time of the connection panel inspection and maintenance work.

According to the connection structure of the inverter module of the present invention, the heat dissipation space can be ensured in the inverter connection module in which the inverter module is housed and connected by placing the heat dissipation unit on the front surface, and the module- The heat dissipation effect of the inverter module can be maximized by airtightly assembling the heat dissipating unit to the heat dissipating unit.

According to the present invention, the guide rails are formed on the upper and lower surfaces of the inverter module, and the inverter modules are slidably inserted into and removed from the inverter slots. Thus, the inverter modules can be stored and taken out more quickly and conveniently. The weight of the inverter module can be easily inserted.

1 is a diagram illustrating an installation state of an inverter module in a conventional inverter connection panel,
2 is a front perspective view of the inverter module according to the present invention,
3 is an exploded perspective view showing a mounting example of the heat dissipating fan unit in Fig. 2,
4 is a rear perspective view of the inverter module according to the present invention,
5 is a perspective view illustrating a structure of an inverter connection board according to the present invention,
6 is a perspective view illustrating the configuration of the flange member in the present invention,
FIGS. 7 and 8 are cross-sectional views showing a state where the inverter module and the inverter slot are connected to each other, and FIG.
9 is a perspective view showing a slide mounting structure of an inverter module according to the present invention.

Hereinafter, specific embodiments according to the present invention will be described with reference to the accompanying drawings. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Parts having similar configurations and operations throughout the specification are denoted by the same reference numerals. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

In the following description of the embodiments, redundant descriptions and explanations of techniques obvious to those skilled in the art are omitted. Also, in the following description, when a section is referred to as "comprising " another element, it means that it may further include other elements in addition to the described element unless otherwise specifically stated.

 Also, the terms "to", "to", "to", and "modules" in the specification mean units for processing at least one function or operation, and may be implemented by hardware or software or a combination of hardware and software . In addition, when a part is electrically connected to another part, it includes not only a case directly connected but also a case where the other parts are connected to each other in the middle.

The inverter module 100 of the present invention is a device for receiving a DC power source input of a renewable energy generation facility and an ESS, converting the AC power into AC power, and supplying AC power to a load and / or a system side. The connection structure of the inverter module 100 described below is such that the modularized inverter module 100 is inserted into the inverter slot 300 such as the inverter connection half and the DC input terminal and the AC output terminal are connected to the corresponding To a connection terminal to be connected.

2 is a front perspective view of an inverter module according to the present invention. Referring to FIG. 2, a handle 112 for receiving and withdrawing the inverter module 100 is installed at the upper and lower ends of the front surface of the inverter module 100. Although not shown, an inverter device is installed in the housing of the inverter module 100, and a heat radiating part 114 is provided on the front surface of the inverter device 100 to discharge heat from the inverter device to the outside. In addition, various connectors 116 for connecting with the monitoring device and the like are provided at the lower end of the front surface of the inverter module 100.

Referring to FIG. 3, a modular heat dissipation fan unit 200 is assembled to a heat dissipation unit 114 on the front surface of the inverter module 100. The radiating fan unit 200 has a structure in which the radiating fan 212 is exposed to the front surface of the unit box 210, and the rear is opened. As shown in the figure, the heat dissipating fan unit 200 is preferably airtightly assembled to the heat dissipating unit 114 via a sealing member 220. According to such a structure, heat can be prevented from leaking from the assembled portion of the heat-dissipating fan unit 200, and heat can be intensively discharged by the heat-dissipating fan unit 200, thereby enabling effective heat dissipation.

4 is a rear perspective view of the inverter module according to the present invention. Referring to FIG. 4, a plurality of heat dissipation holes 126 are formed on the upper surface of the inverter module 100. Guide rails 122 and 132 are formed on both sides of the upper and lower surfaces of the inverter module 100, respectively. The guide rails 122 and 132 are slidably engaged with guide grooves formed in the inverter slots 300 as described later to provide convenience in storing and drawing out the inverter module 100.

As shown, the rear upper surface of the inverter module 100 is obliquely cut to form an insertion guide slope 124. The insertion inducing slope portion 124 allows the lower end portion of the inverter module 100 to be accommodated in a state in which the lower end portion of the inverter module 100 extends over the lower surface of the inverter slot 300 when the inverter module 100 having a large weight is accommodated in the inverter slot 300 Thereby providing ease of storage operation.

4, the DC input terminal 140 and the AC output terminal 150 protrude from the rear of the inverter module 100. As shown in FIG. The DC input terminal 140 has a structure in which the module bus bar 144 is press-fitted and fixed in the insulating mold member 142. As shown, an upper surface of the module bus bar 144 is covered by an insulation module member 142, and a lower surface of the module bus bar 144 is exposed. An insulating support member 146 is disposed below the module bus bar 144. Similarly to the DC input terminal 140, the AC output terminal 150 is covered with the module bus bar 154 on the insulating mold member 152, and the lower surface of the module bus bar 154 is exposed. The insulation support member 146 is protruded from the lower surface of the module bus bar 154.

The DC input terminal 140 and the AC output terminal 150 may be formed in different shapes, but preferably have the same shape as shown. The DC input terminal 140 and the AC output terminal 150 can be exchanged when the inverter module 100 is assembled by configuring the terminals having different functions in the same shape as described above. You can increase your sex.

5 is a perspective view illustrating the structure of an inverter connection panel according to the present invention. Referring to FIG. 5, the inverter slot 300 includes a DC connecting part 310 and an AC connecting part 330 for connecting terminals of the inverter module 100. The DC connecting part 310 and the AC connecting part 330 are respectively connected to the DC input terminal 140 of the inverter module 100 and the module booth bars 144 and 154 of the AC output terminal 150, Bars 322 and 342, respectively.

The DC connection unit 310 includes a slot bus bar 322 for connection of two DC input terminals 140 and a module bus bar 144 of the DC input terminal 140 on the top of each slot bus bar 322. [ And an elastic piece 324 elastically contacted with the elastic piece 324. A frame insulating member 302 is interposed between the two slot bus bars 322 and the frame of the inverter slot 300 to prevent current from being conducted to the frame side. The upper surface of the tibia piece 324 is elastically contacted with the module bus bar 144 of the corresponding DC input terminal 140 and the lower surface thereof is connected to the lower side of the module bus bar 144 by the insulating support member 146 .

6 is a perspective view illustrating a configuration of the elastic piece. Referring to Fig. 6, the elastic piece 324 is composed of a fixed bracket 326 and a plurality of elastic conductors 327. Fig. The elastic conductor 327 is brought into contact with the lower surface of the slot booth bar 322 and has elastic restoring force upward. In the illustrated example, the elastic conductor 327 is in the form of an upwardly bent pin. The fixed bracket 326 is coupled by bolts 328 onto the slotted bus bar 322 and presses both edges of the elastic conductor 327 onto the slotted bus bar 322.

5, the AC connecting part 330 includes a slot booth bar 342 for connecting three AC output terminals 150 and a module booth 342 of the AC output terminal 150 on the slot booth bar 342. [ And an elastic piece 344 elastically contacted with the bottom surface of the bar 154. Further, the frame insulating member 302 is interposed between the slot booth bar 342 and the frame in the same manner as the DC connecting board 310. However, unlike the DC connection board 310, an interphase insulating member 304 is interposed between the slot bus bars 342 to prevent the high voltage from being induced into the other phases. The tongue piece 344 of the AC connecting part 330 also has the same structure as the tongue piece 324 of the DC connecting part 310.

7 and 8 are cross-sectional views showing a state in which the inverter module and the inverter slot are coupled to each other, in which the AC output terminal 150 of the inverter module 100 is connected to the AC connection board 330 of the inverter slot 300 . 7, the upper surface of the slot bus bar 154 is insulated by the insulating mold member 152, and the lower surface is exposed. An insulative support member 156 is spaced apart below the slot bus bar 154 and an upper surface of the distal end of the insulative support member 156 is obliquely cut to form an insertion guide surface 158. Although not shown in Fig. 7, the inserting support member 146 of the DC input terminal 140 is also formed with an insertion guiding surface similarly cut out.

A slot booth bar 342 and a tongue piece 344 are formed in the AC connection part 330 of the inverter slot 300 corresponding to the respective AC output terminals 150. 7 and 8, the frame insulating member and the interphase insulating member are not shown.

7, the distance between the module bus bar 154 and the insulating support member 156 corresponds to the thickness of the fixing bracket 346 mounted on the slot booth bar 342. As shown in Fig. The elastic conductor 347 of the elastic piece 344 has a structure protruding upward.

When the inverter module 100 is housed in the inverter slot 300, insertion of the fixing bracket 346 is induced along the insertion guide surface 158 of the insulator support member 156, The elastic conductor 347 is pressed by the lower surface. When the inverter module 100 is completely housed, the module bus bar 154 and the slot bus bar 342 are electrically connected by an elastic restoring force of the elastic conductor 347 upward as shown in Fig. Since the lower surface of the elastic piece 344 is supported by the insulating support member 156, the electrical connection between the module bus bar 154 and the slot bus bar 342 is in a stable state.

In other words, according to the inverter connection half structure of the present invention, the input / output terminals of the inverter module 100 and the connection terminals of the inverter slot 300 are resiliently in surface contact, and the connection can be firmly maintained. Since the inverter module 100 is connected only by the operation of housing the inverter module 100 in the inverter slot 300, the installation work of the inverter module 100 is very simple and quick maintenance is possible.

9 is a perspective view showing a slide mounting structure of an inverter module according to the present invention, in which the top and bottom structures inside the inverter slot 300 are shown separately. 9, an upper block 350 and a lower block 360 are provided on the upper and lower surfaces of the inverter slot 300, respectively. The upper block 350 and the lower block 360 are separated from each other, Guide grooves are formed on both sides. The guide rail 122 located at the upper end of the inverter module 100 is slidably received in the form of receiving the upper block 350 and the guide rail 132 located at the lower end of the inverter module 100 is inserted into the lower And is slidably coupled to receive the block 360.

Here, as shown in the figure, a plurality of friction relief protrusions 362 protrudes upward from the upper surface of the lower block 360 of the inverter slot 300. Therefore, when the inverter module 100 is slidably engaged with or separated from the inverter slot 300, the frictional force between the bottom surface of the inverter module 100 and the lower surface of the inverter slot 300 is greatly reduced, and the slide operation is performed smoothly .

The invention described above is susceptible to various modifications within the scope not impairing the basic idea. In other words, all of the above embodiments should be interpreted by way of example and not by way of limitation. Therefore, the scope of protection of the present invention should be determined in accordance with the appended claims rather than the above-described embodiments, and should be construed as falling within the scope of the present invention when the constituent elements defined in the appended claims are replaced by equivalents.

100: Inverter module 112: Handle
114: heat sink 116: connector
122: guide rail 124: insertion guide slope part
126: air circulation hole 132: guide rail
140: DC input terminal 142: Insulation mold member
144: Module bus bar 146: Insulation support member
150: AC output terminal 152: Insulation mold member
154: Module bus bar 156: Insulation support member
158: insertion guide surface 200: heat radiating fan unit
210: a unit box 212: a heat-
220: sealing member 300: inverter slot
302: frame insulating member 304: interphase insulating member
310: DC connection board 322: Slot bus bar
324: tongue piece 326: fixed bracket
327: Elastic conductor 328: Bolt
330: AC connection board 342: Slot bus bar
344: tongue piece 346: fixed bracket
347: elastic conductor 350: upper block
360:

Claims (11)

In a connection structure of an inverter module in which an inverter module is connected to an inverter slot in an inverter connection half,
A DC input terminal and an AC output terminal protruding from a back surface of the inverter module,
A plurality of module bosses protruding rearward of the inverter module, an insulating mold member covering an upper surface of the module busbar and exposing a lower surface thereof, and an insulation supporting member spaced downwardly from the module busbar,
The DC connection terminal and the AC connection terminal of the inverter slot to which the DC input terminal and the AC output terminal of the inverter module are respectively connected,
Each of which includes a slot boss disposed in a direction intersecting with the module bus bar, an upwardly protruding portion protruding upwardly to elastically contact the lower surface of the module bus bar on the slot booth bar, and a lower surface thereof supported by the insulating support member doing
Connection structure of inverter module.
The method according to claim 1,
A plurality of elastic conductors having a lower surface contacting the slot booth bar and having an elastic restoring force upwardly and a fixing bracket pressingly fixing the plurality of elastic conductors onto the slot booth bar, rescue.
3. The method according to claim 1 or 2,
Wherein a frame insulating member is interposed between the slot boss and the frame of the inverter slot, and an inter-phase insulating member is interposed between the slot bus bar of the AC connection terminal of the inverter slot.
The method according to claim 1,
Wherein a DC input terminal and an AC output terminal of the inverter module have the same shape.
The method according to claim 1,
Wherein an upper surface of the distal end portion of the insulator support member is obliquely cut to form an insertion guide surface for guiding insertion of the inserting support member to the lower surface of the elastic member.
The method according to claim 1,
Wherein guide grooves are formed on upper and lower surfaces of the inverter slots to guide insertion of the guide rails, respectively, and the inverter module is provided with guide grooves on the inverter slots Connection Structure of Inverter Module Slide Type.
The method according to claim 6,
And a plurality of frictional relief protrusions upwardly protruding from the lower surface of the inverter slot for relieving the frictional force with the lower surface of the inverter module.
8. The method according to claim 6 or 7,
Wherein a rear upper surface of the inverter module is obliquely cut to form an insertion guide slant portion for guiding insertion of the inverter module into the guide groove on the upper surface of the inverter slot.
The method according to claim 1,
The inverter module includes a heat dissipating unit that is open at the front surface thereof. The heat dissipating fan unit is airtightly assembled to the heat dissipating unit via a sealing member,
The heat radiating fan unit includes:
A box-shaped radiating fan unit having a rear opening and communicating with the radiator; And
A heat dissipating fan unit installed in the heat dissipating fan unit and discharging the heat transferred from the heat dissipating unit to the outside,
The connection structure of the inverter module. delete delete

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