KR20230092628A - Power Distribution Apparatus - Google Patents

Abstract

The power distribution device of the present invention includes a case including a front panel that is opened and closed; An installation panel dividing the inside of the case into a front space and a rear space; A first bus bar disposed in the left and right directions in the rear space; a second busbar disposed vertically in the rear space, one end connected to the first busbar and the other end protruding toward the front space; a third busbar that is vertically disposed in the rear space, has both ends protruding toward the front space, and has one end connected to the first busbar; and a fourth busbar disposed vertically in the rear space, one end connected to the other end of the first busbar and the other end protruding into the front space, wherein the installation panel is a portion of the busbar protruding into the front space. may be formed to be minimized, and the busbar protruding into the front space is connected to first and second circuit breakers electrically connected to external power sources and first and second terminal blocks electrically connected to external loads, respectively. Therefore, electric shock can be prevented by allowing wires to be space-efficiently introduced into the power distribution device without interfering with each other and by concealing the busbar from the front approached by a user.

Description

Power Distribution Apparatus

The present invention relates to a power distribution device, and more particularly, to a power distribution device including a busbar capable of improving space efficiency of the power distribution device.

A power distribution device is a device that distributes and supplies power applied from the outside including control devices such as various circuit breakers and relays. Power distribution devices play a role not only in general household distribution boards, but also in smart grids that use renewable energy sources and/or energy storage systems (ESS, Energy Storage System) as power sources in conjunction with general power systems. this is becoming important.

At this time, since the bus bar, which is an electric medium of the conductor, has higher transmission efficiency than a cable of the same volume, it is actively used in power distribution devices requiring high-capacity power transmission.

However, in a conventional power distribution device, busbars connecting a plurality of circuit breakers are exposed to the outside as they are when the distribution board is opened, similarly to the distribution board of Laid-Open Patent Publication No. 10-2004-0087631.

Therefore, there is a problem in that a worker is exposed to the risk of electric shock when initially installing or managing the power distribution device after installation.

Meanwhile, as the amount of power transmitted by the power distribution device increases, the thickness of the wire leading to the power distribution device needs to be increased. The thicker wire cable is difficult to curve easily due to low flexibility in a narrow space, increasing the volume of the power distribution device enclosure.

A conventional power distribution device is configured in a form in which a wire is curved and drawn, similar to Utility Model Publication No. 20-2021-0002256.

Therefore, when the number of external power sources or loads connected to the power distribution device increases or when the amount of power drawn into the power distribution device increases, the volume of the enclosure of the power distribution device increases as the wires inside the power distribution device curve. There was a growing problem.

In addition, in the conventional power distribution device, when a wireless communication device is accommodated in a power distribution device and the power distribution device is operated through a wireless communication terminal, when wireless communication is impossible due to problems such as lack of a communication network or lack of a terminal, the power distribution device There was a problem that the manipulation of was impossible.

An object to be solved by the present invention is to provide a power distribution device capable of preventing an increase in the volume of a case due to a curve of a wire entering the power distribution device.

Another problem to be solved by the present invention is to provide a power distribution device capable of protecting a user from electric shock by arranging a busbar accommodated inside the power distribution device to be concealed from a side approached by a user.

Another problem to be solved by the present invention is to provide a power distribution device capable of preventing the risk of short circuit by preventing interference of wires coming into the power distribution device.

Another problem to be solved by the present invention is to provide a power distribution device that can protect the user from the risk of electric shock and improve the convenience of use by enabling the user to operate the equipment accommodated inside the enclosure without disassembling the enclosure. there is something

Another problem to be solved by the present invention is to provide a power distribution device capable of improving usability of the power distribution device by enabling a circuit breaker to be easily expanded in response to the expansion of an external power source connected to the power distribution device. is in doing

Another problem to be solved by the present invention is to provide a power distribution device capable of improving usability of the power distribution device by allowing the power distribution device to be monitored and operated even in environmental conditions in which a wireless communication module cannot be used. .

The tasks of the present invention are not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, a power distribution device according to an embodiment of the present invention includes a case including a front panel that is opened and closed; An installation panel dividing the inside of the case into a front space and a rear space; a pair of first busbars disposed in left and right directions in a rear space; a pair of second busbars disposed vertically in the rear space, one end connected to the first busbar and the other end protruding toward the front space; a pair of third busbars disposed vertically in the rear space, having one lower end and the other upper end protruding into the front space, and having one end connected to the first busbar; and a pair of fourth busbars arranged vertically in the rear space, one end connected to the other end of the first busbar and the other end protruding toward the front space, wherein the installation panel includes a booth protruding into the front space. The portion of the bar can be formed to be minimized, and the busbars protruding into the front space are respectively first and second circuit breakers electrically connected to external power sources and first and second terminals electrically connected to external loads. Blocks can be connected.

Therefore, the shape of the busbar is configured so that the internal components of the power distribution device can be spaced apart from each other in the left and right directions even in a limited space, so that the wires connected to the internal components of the power distribution device do not interfere with each other and space-efficiently The risk of electric shock due to the busbar can be prevented by allowing the busbar to be inserted, concealing the busbar from the front approached by the user and placing it in the rear space while exposing only the minimum part to be connected to the internal components of the power distribution device to the front. there is.

The other end of the fourth busbar and one end of the third busbar of the power distribution device according to an embodiment of the present invention extend downward and can be connected to the first terminal block and the second terminal block, respectively, and the second busbar The other end and the other end of the third busbar may be bent to ride over the upper end of the main panel in a forward direction and be connected to the first circuit breaker and the second circuit breaker, respectively.

Therefore, the first circuit breaker and the second circuit breaker are disposed forward and forward from the first terminal block and the second terminal block, so that the first circuit breaker and the first terminal block are disposed adjacent to each other on a vertical line, and the second circuit breaker and the second circuit breaker are disposed adjacent to each other. 2Even if the terminal blocks are arranged adjacently on the vertical line, the wires are introduced in a straight line or close to a straight line in the power distribution device so that they do not interfere with each other, thereby preventing the risk of short circuit in the power distribution device, and the curve of the wire ( Curve) can prevent an increase in the volume of the case.

A case of a power distribution device according to an embodiment of the present invention includes a first opening hole on a lower side of which is opened to correspond to a first terminal block in a vertical direction and into which a wire is introduced; And a second opening hole opened on the lower side to correspond to the second terminal block in the vertical direction and into which the wires are introduced.

Therefore, since the wires introduced into the case of the power distribution device from the outside through the opening hole can be connected to the terminal block in a straight or near-straight form, an increase in the volume of the case due to the curve of the wire can be prevented.

In the installation panel according to an embodiment of the present invention, a portion may be opened so that the manual switches of the first relay and the second relay disposed in the rear space are exposed to the front.

Accordingly, convenience of the power distribution device is improved by allowing the user to operate the relay without disassembling the installation panel, and safety of the power distribution device can be improved by allowing the user to operate the relay without risk of electric shock.

The first circuit breaker and the second circuit breaker of the power distribution device according to the embodiment of the present invention may be disposed adjacent to the outer circumference of the installation panel, respectively.

Therefore, by minimizing the area of the busbar exposed to the front space to be connected to the first and second breakers, it is possible to protect the user from electric shock.

A power distribution device according to an embodiment of the present invention includes a conductive panel to which the other end of a second bus bar is connected; and an expansion terminal including a plurality of circuit breaker insertion units protruding from the conductive panel, and a plurality of first circuit breakers corresponding to an external first power source and inserted into the circuit breaker insertion unit. .

Therefore, the usability of the power distribution device can be improved by enabling a simple response to the expansion of the first power source.

The circuit breaker insertion unit of the power distribution device according to an embodiment of the present invention may be formed in plurality so that a plurality of first circuit breakers share side surfaces adjacent to each other.

Accordingly, the space efficiency of the power distribution device can be improved by efficiently arranging the plurality of first circuit breakers without wasting space.

The power distribution device according to an embodiment of the present invention may further include a touch display displaying a menu for monitoring or manipulating the power distribution device, and the front panel may be opened to correspond to the touch display in the forward and backward directions.

Therefore, compared to the case where the power distribution device can be operated and monitored only with the wireless communication module, the intuitiveness of monitoring and operation is improved by providing the touch display, and the power distribution device can be monitored and operated even under environmental conditions in which the wireless communication module cannot be used. Thus, the usability of the power distribution device can be improved.

The power distribution device according to an embodiment of the present invention may further include a reset switch capable of resetting the power distribution device and a storage device port capable of transmitting an operation record of the power distribution device to an inserted removable storage device, , The front panel may be opened to correspond to the reset switch, the storage device port, and the first and second breakers in the forward and backward directions.

Therefore, through the opening formed in the front panel, the user can use the reset switch and the storage device port accommodated inside the case without separating the front panel, thereby improving the user's management convenience and protecting the user from electric shock. .

Details of other embodiments are included in the detailed description and drawings.

According to the power distribution device of the present invention, one or more of the following effects are provided.

The power distribution device according to an embodiment of the present invention configures the shape of a busbar so that the internal components of the power distribution device can be spaced apart from each other in the left and right directions even in a limited space, and is connected to the internal components of the power distribution device. By allowing the wires to be space-efficiently introduced without interfering with each other, and by concealing the busbar from the front where the user approaches and placing it in the rear space, only the minimum part to be connected to the internal components of the power distribution device is exposed to the front , the risk of electric shock due to the bus bar can be prevented.

In the power distribution device according to an embodiment of the present invention, the first circuit breaker and the second circuit breaker are disposed forward from the first terminal block and the second terminal block, so that the first circuit breaker and the first terminal block are on a vertical line. Even if the circuit breaker and the second terminal block are arranged adjacent to each other in the vertical direction, the wires are drawn in a straight line or close to a straight line in the power distribution device so that they do not interfere with each other, so that the short circuit in the power distribution device risk, and an increase in the volume of the case due to the curve of the wire can be prevented.

In the power distribution device according to an embodiment of the present invention, an opening hole is formed on the same line in the vertical direction with a plurality of terminal blocks arranged in the left and right directions, so that the wire entering the case of the power distribution device from the outside is straight or straight. It is possible to prevent an increase in the volume of the case due to the curve of the wire by enabling it to be connected to the terminal block in a form close to .

The power distribution device according to an embodiment of the present invention forms an opening in the installation panel so that the user can operate the relay without disassembling the installation panel, thereby improving the convenience of the power distribution device and opening the relay without the risk of electric shock. It is possible to improve the safety of the power distribution device by enabling manipulation.

The power distribution device according to an embodiment of the present invention minimizes the area of the busbar exposed to the front space in order to be connected to the first and second circuit breakers by arranging the first and second circuit breakers adjacent to the outside of the installation panel. can protect against electric shock.

The power distribution device according to an embodiment of the present invention is provided with an expansion terminal so that it can easily cope with the expansion of the first power source, thereby improving usability of the power distribution device.

Compared to the case where the power distribution device can be operated and monitored only with a wireless communication module, the power distribution device according to an embodiment of the present invention has a touch display to improve the intuitiveness of monitoring and operation, and prevents the use of a wireless communication module. It is possible to improve the usability of the power distribution device by allowing the power distribution device to be monitored and operated even under environmental conditions.

In the power distribution device according to an embodiment of the present invention, the user can use the reset switch and the storage device port accommodated inside the case through an opening formed on the front panel without separating the front panel, thereby improving user management convenience. and protect users from electric shock.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view of a power distribution device according to an embodiment of the present invention.
2 is an exploded perspective view of a power distribution device according to an embodiment of the present invention.
3 is a schematic diagram showing electrical connections of a power distribution device according to an embodiment of the present invention.
4 is a first perspective view of a bus bar to which a relay is fastened according to an embodiment of the present invention.
5 is a second perspective view of a bus bar to which a relay is fastened according to an embodiment of the present invention.
6 is a first perspective view of an installation panel according to an embodiment of the present invention.
7 is a second perspective view of an installation panel according to an embodiment of the present invention.
8 is a rear view of an installation panel according to an embodiment of the present invention.
9 is a front view of an installation panel to which busbars are fastened according to an embodiment of the present invention.
10 is a rear view of an installation panel to which busbars are fastened according to an embodiment of the present invention.
11 is a perspective view of an installation panel to which busbars, expansion terminals, and terminal blocks are fastened according to an embodiment of the present invention.
12 is a rear view of an installation panel to which busbars, expansion terminals, and terminal blocks are fastened according to an embodiment of the present invention.
13 is a perspective view of the power distribution device according to an embodiment of the present invention with a case removed.
14 is a schematic diagram showing a state in which wires are connected to a power distribution device according to an embodiment of the present invention.
15 is a front view of an expansion terminal to which a plurality of first circuit breakers are connected according to an embodiment of the present invention.
16 is a front view of an open door of the power distribution device according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings. In the drawings, in order to clearly and concisely describe the present invention, parts not related to the description are omitted, and the same reference numerals are used for the same or extremely similar parts throughout the specification.

In this application, terms such as "comprise" or "have" are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that the presence or addition of numbers, steps, operations, components, parts, or combinations thereof is not precluded.

Also, in this specification, terms such as first and second may be used to describe various elements, but these elements are not limited by these terms. These terms may only be used to distinguish one element from another.

Electricity, especially alternating current, simultaneously flows through the entire closed circuit, but for convenience, it will be described below on the premise that electricity is supplied or received sequentially between specific power sources, components, or elements.

Based on the general current flow, the 'upstream' may be referred to as 'front end', and the 'downstream' may be referred to as rear end. In addition, in the case of the 1-1 power source 100a, which will be described later, electricity can be supplied as well as supplied, but it is described as 'upstream, front, downstream, and rear' based on the case of supplying electricity. .

Hereinafter, 'converter' refers to 'electric circuit'.

Hereinafter, according to the azimuth table shown in the drawing, the 'U' direction is up or up, the 'D' direction is down or down, the 'F' direction is forward, the 'R' direction is rear or rear, and the 'Ri' direction is right. Room or right side, 'Le' direction can be referred to as left room or left side. However, directions for directions may be referred to differently according to standards.

Hereinafter, 'to be connected' may include not only a direct connection but also an indirect connection.

Hereinafter, it is natural that all electrical components can be formed as a pair to form a closed circuit through which current flows.

Hereinafter, for example, it is natural that drawing number '2' may include '2a', '2b', '2c', '2d', '2e', '2f', and '2g'. For example, it goes without saying that '2b' may include '2ba', '2bb', '2bc', '2bd', '2be', '2bf', and '2bg'.

Hereinafter, with reference to FIGS. 1 and 2, the case 2 and internal configuration of the power distribution device 1 will be schematically described.

The case 2 includes a door 2a, a front panel 2b, a rear panel 2c formed to face the front panel 2b, and a connection between the front panel 2b and the left end of the rear panel 2c. Left side panel (2f), right side panel (2g) connecting the right ends of the front panel (2b) and rear panel (2c), top panel (2d) connecting the upper ends of the front panel (2b) and rear panel (2c) ), and a bottom panel 2e connecting the lower ends of the front panel 2b and the rear panel 2c.

The door 2a is connected to the front end of the side panel by a hinge and can be opened and closed by rotating. The door 2a may be disposed in front of the front panel 2b. The door 2a may be disposed to face the front panel 2b in the front-back direction.

Case 2, the wireless communication module 3 can be coupled to one side. For example, the wireless communication module 3 may be coupled to the left side panel 2f.

A wireless communication circuit board (not shown) may be provided inside the wireless communication module 3 .

The wireless communication module 3 is connected to the communication network outside the control unit 4 and the power distribution device 1, transmits monitoring information about the power distribution device 1 to the user's wireless communication terminal, and distributes the user's power. The device 1 may receive an operation command and transmit it to the control unit 4 .

The case 2 may form at least one opening hole through which wires are introduced. The opening hole formed in the case 2 will be described later with reference to FIG. 14 .

The front panel 2b may be formed to be opened and closed. For example, it can be fastened to the front panel first fastening part 2bf and the front panel second fastening part 2bg formed in the case 2, and can be detached again. For example, the front panel first fastening part 2bf may be a structure for bolt fastening. For example, the front panel second fastening part 2bg may have a structure for hook fastening. (See Fig. 16)

A detailed description of the shape of the front panel 2b will be described later with reference to FIG. 16 .

The installation panel 20 is arranged inside the case 2 to face the front panel 2b so as to divide the inside of the case 2 into a front space and a rear space.

That is, the rear space may be defined as a rear portion of the installation panel 20 in the inner space of the case 2 . In addition, the front space may be defined as a front portion of the installation panel 20 in the inner space of the case 2 .

The installation panel 20 may be fastened to and fixed to the case 2 . A detailed description of the installation panel 20 and other components fastened to the installation panel 20 will be described later.

The power distribution device 1 may further include a touch display 80 that displays a menu for monitoring or manipulating the power distribution device 1 .

The touch display 80 may be electrically connected to the main PCB 4a.

The touch display 80 may visually display an operation record and an operation state of the power distribution device 1 . For example, the touch display 80 may display the amount of power supplied from the first power source and the second power source, and the amount of power supplied to the normal load and the emergency load.

The touch display 80 allows the user to manipulate the initial setting and operating method of the power distribution device 1 through touch manipulation. For example, the user may manipulate the touch display 80 to set the amount of power to be supplied from each of the 1-1st power source, 1-2nd power source, and 2nd power source to vary according to time zone.

The touch display 80 is engaged with the display bracket 81 so that the screen faces forward.

The display bracket 81 may be fastened to the PCB bracket 5.

The PCB bracket 5 may be fastened to the installation panel 20 . For example, the PCB bracket 5 may be fastened across the fifth area 20aa and the sixth area 20ab of the upper panel 20a, which will be described later.

Therefore, compared to the case where the power distribution device 1 can be operated and monitored only with the wireless communication module 3, the intuitiveness of monitoring and operation is improved by providing the touch display 80, and the wireless communication module 3 is used. It is possible to improve the usability of the power distribution device 1 by allowing the power distribution device 1 to be monitored and operated even under environmental conditions that cannot be avoided.

The controller 4 may be implemented in the main PCB 4a and/or the sub PCB 4b. The controller 4 may refer to the main PCB 4a and/or the sub PCB 4b.

The control unit 4 includes components in the power distribution device 1 (eg, the first to third CT sensors 40c, the first and second relays, the first and second breakers, the wireless communication module 3, It may be electrically connected to the electric meter 104, the touch display 80, the reset switch 70, and the storage device port 71.

The control unit 4 controls the detected values of the first to third CT sensors 40c, the user's power distribution device 1 operation setting, the power supply status of the power source, and the power supply unit cost of the second power source 101. , the first circuit breaker 30, the second circuit breaker 31, the first relay 10, and the second relay 11 can be controlled to be opened or closed, respectively, according to the required power state of the load.

The main PCB (4a), as a printed circuit board, may be disposed and fastened between the display bracket (81) and the PCB bracket (5).

The sub-PCB 4b is a printed circuit board and may be fastened to the rear of the installation panel 20 . For example, the sub-PCB 4b may be fastened to the rear of the fifth region 20aa of the upper panel 20a, which will be described later. (See FIG. 12 ) The sub PCB 4b may be electrically connected to the main PCB 4a.

Hereinafter, electrical connections of the power distribution device 1 will be described with reference to FIG. 3 .

The number of first power sources 100 may be plural.

For example, the first power source 100 may include a 1-1 power source 100a and a 1-2 power source 100b.

For example, the 1-1 power source 100a may be an energy storage system (ESS).

At this time, the 1-1st power source 100a may be discharged while supplying electricity to the power distribution device 1, or may be charged by receiving electricity from the power distribution device 1.

The 1-2 power source 100b may be a renewable energy source. For example, the first-second power source 100b may be a photovoltaic (PV) module.

The 1-2 power source 100b may supply electricity to the power distribution device 1 .

The second power source 101 may be a general power system (eg, KEPCO).

The electricity meter 104 is disposed at the rear end of the second power source 101 and can measure the amount of power supplied from the second power source 101 . For example, the electricity meter 104 may be external to the power distribution device 1 .

The commercial load 102 is a load of a commercial facility that receives electricity in a general case other than an emergency such as a power outage. For example, the commercial load 102 may include indoor appliances.

The emergency load 103 is a load of an emergency facility that receives electricity in an emergency such as a power outage. For example, the emergency load 103 may include an indoor refrigerator and a light.

The first circuit breaker 30 may open and close a circuit connected to the first power source 100 .

The first circuit breaker 30 may be formed in plural numbers. For example, the first circuit breaker 30 may include a 1-1 circuit breaker 30a and a 1-2 circuit breaker 30b.

The 1-1 circuit breaker 30a may open and close a circuit connected to the 1-1 power source 100a.

The 1-1 circuit breaker 30a may allow electricity supplied from the 1-1 power source 100a to be supplied to the commercial load 102 . At this time, electricity supplied to the commercial load 102 may be blocked by the first relay 10 .

The 1-1 circuit breaker 30a may allow electricity supplied from the 1-1 power source 100a to be supplied to the emergency load 103 . At this time, electricity supplied to the emergency load 103 may be cut off by the second relay 11.

The 1-1 circuit breaker 30a may allow electricity supplied from the 1-2 power source 100b and/or the second power source 101 to be supplied to the 1-1 power source 100a. At this time, electricity supplied from the 1-2 power source 100b may be cut off by the 1-2 circuit breaker 30b. At this time, electricity supplied from the second power source 101 may be cut off by the second circuit breaker 31 or the second relay 11 .

When the 1-1 circuit breaker 30a receives electricity from the 1-1 power source 100a, the 1-1 power source 100a may be discharged.

When the 1-1 circuit breaker 30a supplies electricity to the 1-1 power source 100a, the 1-1 power source 100a can be charged.

The 1-2 breaker 30b may open and close the circuit connected to the 1-2 power source 100b.

The 1-2 circuit breaker 30b may allow electricity supplied from the 1-2 power source 100b to be supplied to the 1-1 power source 100a. At this time, electricity supplied to the 1-1 power source 100a may be cut off by the 1-1 circuit breaker 30a.

The 1-2 breaker 30b can supply electricity supplied from the 1-2 power source 100b to the commercial load 102 . At this time, electricity supplied to the commercial load 102 may be blocked by the first relay 10 .

The 1-2 breaker 30b can supply electricity supplied from the 1-2 power source 100b to the emergency load 103 . At this time, electricity supplied to the emergency load 103 may be cut off by the second relay 11.

The second circuit breaker 31 may open and close a circuit connected to the second power source 101 .

The second circuit breaker 31 may allow electricity supplied from the second power source 101 to be supplied to the emergency load 103 .

The second circuit breaker 31 may allow electricity supplied from the second power source 101 to be supplied to the commercial load 102 . At this time, electricity supplied to the second power source 101 may be blocked by the second relay 11 or the first relay 10 .

The second circuit breaker 31 may allow electricity supplied from the second power source 101 to be supplied to the 1-1 power source 100a. At this time, electricity supplied to the 1-1 power source 100a may be cut off by the second relay 11 or the 1-1 circuit breaker 30a.

Other circuit breakers will be described later with reference to FIG. 13 .

The first relay 10 can open and close the electric path at the position where it is placed.

The first relay 10 may be disposed downstream of a branching point of a circuit connected to the emergency load 103, among circuits connecting the first circuit breaker 30 and the commercial load 102.

The second relay 11 can open and close the electric path at the position where it is placed.

The second relay 11, among the converters connecting the first circuit breaker 30 and the emergency load 103, the point where the converter connected to the commercial load 102 branches and the converter connected to the second circuit breaker 31 may be disposed between the branching points.

A description of other relays will be described later with reference to FIG. 4 .

The power distribution device 1 may include a CT sensor (Current Transformer), which is an overcurrent detection sensor for detecting a current equal to or greater than the maximum allowable current of a bus bar or converter.

The CT sensors may be arranged in a pair corresponding to a pair of busbars constituting the converter. The CT sensor may include first to third CT sensors 40c.

The first CT sensor 40a can measure electricity flowing through the converter at the location where it is placed.

The first CT sensor 40a may be disposed upstream of a branching point of a converter connected to the emergency load 103, among converters connecting the first circuit breaker 30 and the commercial load 102. That is, the first CT sensor 40a may be disposed on the second bus bar 7.

The second CT sensor 40b can measure the electricity flowing through the converter at the location where it is placed.

The second CT sensor 40b may be disposed upstream of a branching point of a converter connected to the commercial load 102 among converters connecting the second circuit breaker 31 and the emergency load 103 . That is, the second CT sensor 40b may be disposed on the third bus bar 8. (See Fig. 12)

The third CT sensor 40c can measure the electricity flowing through the converter at the location where it is placed.

The third CT sensor 40c may be disposed on a circuit connecting the 1-2 power source 100b and the 1-2 circuit breaker 30b.

Hereinafter, the shape and electrical connection of the busbar will be described with reference to FIGS. 4 and 5 .

Busbars may be configured as a pair to form a circuit (electric circuit). That is, the busbar can form a converter. Hereinafter, even if there is no separate mention, each bus bar may be described on the premise that it is a pair.

The busbar may be a bar-shaped conductive metal member having a length greater than a width. A pair of busbars may include bar-shaped metal members arranged parallel to each other.

Since the connection of the busbars requires surface contact, the connection between the busbars can be bent as needed.

The connection between the busbars, the connection between the contact bar and the busbar, and the connection between the busbar and other parts of the power distribution device 1 may mean that bolts are fastened through bolt holes formed in the surface contact parts.

The first busbar 6 may be disposed in the left and right directions in the rear space. The first busbar 6 may be formed as a pair.

The first bus bar 6 may be disposed adjacent to the rear surface of the installation panel 20 .

The second busbar 7 may be vertically disposed in the rear space. The second busbar 7 may be formed as a pair.

One end 7a of the second busbar may be connected to the first busbar 6 . At this time, the second bus bar 7 may be formed to extend upward from the first bus bar 6 . That is, the second busbar 7 may be formed to extend upward from one end connected to the first busbar 6 .

The other end 7b of the second busbar may protrude into the front space. For example, the other end 7b of the second busbar may protrude into the front space through the installation panel 20 .

Alternatively, for example, the other end 7b of the second busbar may be bent to go over the outer periphery of the installation panel 20 and protrude into the front space.

At this time, when the second busbar 7 is formed extending upward from the first busbar 6, the other end 7b of the second busbar crosses the upper end of the installation panel 20 in the forward direction. It can be bent and projected into the front space.

The other end 7b of the second busbar may be connected to a first circuit breaker 30 to be described later.

The third busbar 8 may be vertically disposed in the rear space. The third busbar 8 may be formed as a pair.

In the third busbar 8, one end of the lower side and the other end of the upper side may protrude into the front space.

For example, one end 8a of the third busbar may pass through the installation panel 20 and protrude into the front space. For example, one end 8a of the third busbar extends downward while penetrating the bent portion 20d of the installation panel 20 to be described later, and may protrude into the front space. At this time, one end 8a of the third busbar may extend downward and be connected to the second terminal block 50b.

For example, the other end 8b of the third busbar may pass through the installation panel 20 and protrude into the front space. Alternatively, for example, the other end 8b of the third busbar may be bent to pass over the upper end of the installation panel 20 in the forward direction and protrude into the front space.

The other end 8b of the third busbar may be connected to a second circuit breaker 31 to be described later.

One end 6a of the first busbar may be connected to the third busbar 8 .

The fourth busbar 9 may be vertically disposed in the rear space. The fourth busbar 9 may be formed as a pair.

One end 9a of the fourth busbar may be connected to the other end 6b of the first busbar.

At this time, the fourth busbar 9 may be formed extending downward from the first busbar 6 . That is, the fourth busbar 9 may be formed extending downward from one end connected to the first busbar 6 .

At this time, in order to avoid interference between the pair of fourth busbars 9, one of the pair of fourth busbars 9 may be inclined laterally and extend downward.

The other end 9b of the fourth busbar may protrude into the front space.

For example, the other end 9b of the fourth busbar may pass through the installation panel 20 and protrude into the front space. For example, when the fourth busbar 9 is formed extending downward from the first busbar 6, the other end 9b of the fourth busbar is a bent portion of the installation panel 20 to be described later ( 20d), it may extend downward and protrude into the front space. At this time, the other end 9b of the fourth busbar may extend downward and be connected to the first terminal block 50a.

The first relay 10 is disposed between the point where the other end 6b of the first busbar and the second busbar 7 are connected in the first busbar 6, and can open and close the circuit.

The first relay 10 may include a first manual switch 10e through which a user may arbitrarily turn on or off the relay.

The second relay 11 is disposed between a point where one end 6a of the first busbar and the second busbar 7 are connected in the first busbar 6, and can open and close the circuit.

The second relay 11 may include a second manual switch 11e through which a user may arbitrarily turn on or off the relay.

The first and second relays may be 4-contact type relays except for a separate auxiliary circuit for operating or closing the relay.

At this time, the portion forming the contact of the first relay 10 may be referred to as the 1-1 contact bar 10a to the 1-4 contact bar 10d. In addition, the portion forming the contact of the second relay 11 may be referred to as a 2-1 contact bar 11a to a 2-4 contact bar 11d.

The contact bar may be a bus bar that is integrally formed with the relay and protrudes from the contact inside the relay.

At this time, the first bus bar 6 may have a concept including a plurality of bus bars connected to the contact bars of the first and second relays.

That is, the first busbar 6 may include the 1-1 busbar 61, the 1-2 busbar 62, and the 1-3 busbar 63.

The 1-1 busbar 61 may connect the first relay 10 and the second relay 11.

One end 61a of the 1-1 bus bar may be connected to the 1-1 contact bar 10a and the 1-2 contact bar 10b.

The other end 61b of the 1-1 busbar may be connected to the 2-1 contact bar 11a and the 2-2 contact bar 11b.

One end 7a of the second busbar may be connected to the 1-1 busbar 61 .

The other end 6b of the first bus bar may refer to the first to third contact bars 10c and the first to fourth contact bars 10d of the first relay 10 .

At this time, one end 9a of the fourth bus bar may be connected to the 1-3 contact bar 10c and the 1-4 contact bar 10d.

The 1-2 busbar 62 and the 1-3 busbar 63 may connect the second relay 11 and the third busbar 8.

One end 62a of the 1-2 busbar may be connected to the 2-3 contact bar 11c and the 2-4 contact bar 11d.

The other end 62b of busbar 1-2 may be connected to one end 63a of busbar 1-3.

The other end 63b of the 1-3 busbar may be connected to the third busbar 8.

Having the 1-2 busbar 62 and the 1-3 busbar 63 separately means that the surface formed by the contact bar of the second relay 11 and the surface formed by the third bus bar 8 are If not parallel, the 1st-2nd busbar 62 and/or the 1st-3rd busbar 63 in the necessary direction to connect the 2nd relay 11 and the 3rd busbar 8 through surface contact. ) may be to be bent, respectively.

In this case, one end 6a of the first busbar may refer to the other end 63b of the 1-3 busbars.

Hereinafter, the shape of the installation panel 20 and the arrangement of busbars will be described with reference to FIGS. 6 to 10 .

The installation panel 20 may be divided into a main panel 20b, a bent portion 20d, a low panel 20c, and an upper panel 20a.

In the main panel, the first busbar 6 to the fourth busbar 9 are disposed at the rear, and the other end 7b of the second busbar and the other end 8b of the third busbar are disposed at the upper end. can

A part of the main panel 20b may be opened so that the manual switches of the first relay 10 and the second relay 11 are exposed forward.

The main panel 20b may be divided into a first area 20ba to a fourth area 20bd corresponding to busbars and relays disposed behind the main panel 20b.

A part of the first bus bar 6 and a third bus bar 8 may be disposed in the rear of the first area 20ba. The vertical length of the first region 20ba may be smaller than the vertical length of the third busbar 8 so that both ends of the third busbar 8 are exposed to the front space.

At this time, the other end 8b of the third bus bar may be disposed at the upper end of the first region 20ba and protrudes into the front space by being bent so as to cross the upper end of the first region 20ba from the rear space.

At this time, one end 8a of the third bus bar may be disposed below the first region 20ba, extending downward from the rear space and protruding toward the front space.

The left-right length of the first area 20ba may be greater than the left-right length of the third busbar 8 so that portions other than both ends of the third busbar 8 are not exposed to the front space.

The second region 20bb is formed extending from one end of the first region 20ba in one direction, and a portion of the first bus bar 6 and the second relay 11 may be disposed at the rear. The horizontal and vertical lengths of the second area 20bb may be greater than the horizontal and vertical lengths of the second relay 11 so that the second relay 11 is not exposed to the front space.

In the second area 20bb, the 2-2 opening 20bf corresponding to the second manual switch 11e in the front-back direction is provided so that the second manual switch 11e of the second relay 11 is exposed forward. can be formed

The third area 20bc is formed extending in one direction from one end of the second area 20bb, and a part of the first bus bar 6 and the second bus bar 7 may be disposed at the rear. .

The vertical length of the third area 20bc may be smaller than the vertical length of the second busbar 7 so that the other end 7b of the second busbar is exposed to the front space.

At this time, the other end 7b of the second bus bar may be disposed at the upper end of the third region 20bc, bent so as to ride over the upper end of the third region 20bc from the rear space in the forward direction and protrude into the front space. .

The left-right length of the third region 20bc may be greater than the left-right length of the second busbar 7 so that portions other than the other end 7b of the second busbar are not exposed to the front space.

The fourth region 20bd is formed extending from one end of the third region 20bc in one direction, and a part of the first bus bar 6, the first relay 10, and the fourth bus bar are rearward. (9) can be placed.

The vertical length of the fourth area 20bd may be smaller than the vertical length of the fourth busbar 9 so that the other end 9b of the fourth busbar is exposed to the front space.

At this time, the other end 7b of the second bus bar may be disposed below the fourth region 20bd, extending downward from the rear space and protruding toward the front space.

The left-right length of the fourth region 20bd is such that the fourth busbar 9 and the first relay ( 10) in the left-right direction.

In the fourth region 20bd, the 2-1 opening 20be corresponding to the first manual switch 10e in the front-back direction is provided so that the first manual switch 10e of the first relay 10 is exposed forward. can be formed

Lower ends of the first area 20ba to the fourth area 20bd may be arranged on the same line.

The bent portion 20d may be formed to extend rearward from the lower end of the main panel 20b.

The bent portion 20d may include a 3-1 opening 20da through which one end 8a of the third busbar passes. For example, one end 8a of the third busbar extending downward from the rear of the first area 20ba may protrude into the front space through the 3-1 opening 20da.

The bent portion 20d may include a 3-2 opening 20db through which the other end 9b of the fourth busbar passes. For example, the other end 9b of the fourth busbar extending downward from the rear of the fourth area 20bd may protrude into the front space through the 3-2 opening 20db.

The bent portion 20d may include a 3-3 opening 20dc through which a neutral wire (not shown) to be connected to the fourth terminal block 50d passes.

The low panel 20c may be formed to extend downward from the rear end of the bent portion 20d.

The low panel 20c may include a barrier rib 20ca formed by protruding forward from a panel extending downward.

The partition wall 20ca is a wall having a length in the vertical direction, and forms a side wall of a space in which terminal blocks are disposed to block electrical connections between adjacent terminal blocks. The barrier ribs 20ca may be formed in plurality so as to be spaced apart from each other in the left and right directions.

Accordingly, the low panel 20c has a first terminal block 50a and a second terminal block (connecting the other end 9b of the fourth busbar and one end 8a of the third busbar with wires coming from the outside) 50b) may form a space to be disposed.

In addition, the low panel 20c may form a space where the third terminal block 50c and the fourth terminal block 50d to which the neutral wire is connected are disposed.

The upper panel 20a may be formed to extend upward from a portion of an upper end of the main panel 20b.

The upper panel 20a may include a fifth area 20aa and a sixth area 20ab.

The fifth region 20aa may be formed to extend upward from upper ends of the first region 20ba and the second region 20bb of the main panel 20b.

In the fifth region 20aa, a first opening 20ac may be formed above the first region 20ba. The first opening 20ac may allow the other end 8b of the third busbar to pass through the rear space and protrude toward the front space.

A sub-PCB 4b may be fastened behind the fifth region 20aa. The fifth region 20aa may have a shape corresponding to the sub-PCB 4b.

The upper panel 20a is not formed upward from the upper end of the third region 20bc, so that the upper end of the third region 20bc can be opened. Accordingly, the other end 7b of the second busbar may pass through the rear space and protrude toward the front space.

The sixth region 20ab may be formed to extend upward from an upper end of the fourth region 20bd.

In front of the fifth area 20aa and the sixth area 20ab, the PCB bracket 5, the main PCB 4a, the display bracket 81, and the touch display 80 are sequentially arranged from rear to front and fastened. It can be.

The circumferential panel 20e may be formed to extend rearward from a part of the periphery of the main panel 20b and the upper panel 20a.

The installation panel fastening portion 20ea extends from the circumferential panel 20e and makes surface contact with the rear surface of the case 2 so that the installation panel 20 can be fastened to the case 2 by bolts.

The circumferential panel 20e may transmit force so that the fastened installation panel 20 is supported by the case 2 .

The peripheral panel 20e may have a concept including a bent portion 20d.

Hereinafter, with reference to FIGS. 11, 12, and 15, the expansion terminal 90 and the terminal block connected to the power distribution device 1 will be described.

The power distribution device 1 may further include an expansion terminal 90 .

The expansion terminal 90 is connected to the second bus bar 7 and the first circuit breaker 30, so that the second bus bar 7 and the first circuit breaker 30 can be connected. The expansion terminal 90 may allow a plurality of first circuit breakers 30 to be connected in parallel with the second bus bar 7 .

The expansion terminal 90 may include a base panel 90a, a conductive panel 90b, a circuit breaker insertion unit 90c, and a fixer.

The base panel 90a forms a front surface to which the conductive panel 90b can be fastened. The base panel 90a may be fastened to the installation panel 20 . For example, the base panel 90a may be fastened to the third region 20bc of the main panel 20b.

The other end 7b of the second bus bar may be connected to the conductive panel 90b. The second busbar 7 may be fastened to the conductive panel 90b with bolts. The conductive panels 90b may be formed as a pair to correspond to the pair of second busbars 7 .

The conductive panel 90b is made of a conductive material and can electrically connect the plurality of first circuit breakers 30 to the second bus bar 7 .

The conductive panel 90b and the other end 7b of the second busbar may be bolted together by the second busbar fastening part 90e.

The circuit breaker insertion portion 90c may protrude forward from the conductive panel 90b. The first circuit breaker 30 may be inserted into the circuit breaker insertion portion 90c.

Meanwhile, the number of first power sources 100 may be plural. At this time, the first circuit breaker 30 may be provided in plurality corresponding to the plurality of first power sources 100 .

A plurality of circuit breaker inserts 90c may be formed so that the plurality of first circuit breakers 30 share side surfaces adjacent to each other. (See Fig. 15)

For example, the plurality of circuit breaker insertion portions 90c may be formed at the central portion of the conductive panel 90b in the left and right directions and spaced apart vertically from each other.

For example, the lower surface of the 1-1 circuit breaker 30a may come into contact with the upper surface of the 1-2 circuit breaker 30b. For example, the lower surface of the 1-2 circuit breaker 30b may come into contact with the upper surface of the 1-3 circuit breaker 30c. For example, the left side of the 1-3 circuit breaker 30c and the right side of the 1-4 circuit breaker 30d may be in contact with each other.

Accordingly, space efficiency of the power distribution device 1 can be improved by allowing the plurality of first circuit breakers 30 to be inserted without wasting space.

The fixer may fix the conductive panel 90b to the base panel 90a. The fixer may support the conductive panel 90b while being formed along the circuit breaker insertion portion 90c to prevent the conductive panel 90b from being separated from the base panel 90a.

Therefore, by providing the expansion terminal 90, it is possible to easily cope with the expansion of power sources, thereby improving the usability of the power distribution device 1.

The power distribution device 1 may include a terminal block that connects an electric wire coming from the outside to a circuit inside the power distribution device 1 . The terminal block may have a structure in which a groove into which an electric wire is inserted is formed on one side and a converter inside the power distribution device 1 can be connected to the other side. The terminal block may be in the form of a generally commercially available product.

The terminal block may include the first terminal block 50a to the fourth terminal block 50d.

The first terminal block 50a is disposed on the low panel 20c and connected to the other end 9b of the fourth busbar, and may be electrically connected to the external commercial load 102. For example, the first terminal block 50a may be disposed in a gap formed by the barrier rib 20ca of the low panel 20c. For example, the other end 9b of the fourth busbar protruding downward through the 3-2 opening 20db of the bent portion 20d may be connected to the rear surface of the first terminal block 50a. For example, a wire connected to the external commercial load 102 may be inserted into the front surface of the first terminal block 50a.

The second terminal block 50b is disposed on the low panel 20c and connected to one end 8a of the third bus bar, and may be electrically connected to an external emergency load 103. For example, the second terminal block 50b may be disposed in a gap formed by the barrier rib 20ca of the low panel 20c. For example, one end 8a of the third bus bar protruding downward through the 3-1 opening 20da of the bent portion 20d may be connected to the rear surface of the second terminal block 50b. For example, a wire connected to an external emergency load 103 may be inserted into the front of the second terminal block 50b.

The third terminal block 50c is disposed on the low panel 20c and is connected to a neutral wire (not shown) inside the power distribution device 1, and is connected to the external commercial load 102 and the second power source 101. A connecting neutral wire may be inserted.

The fourth terminal block 50d is disposed on the low panel 20c and is connected to the neutral wire (not shown) inside the power distribution device 1, and the external emergency load 103 and the 1-1 power source 100a ) and a neutral wire connected to it can be inserted.

Hereinafter, a circuit breaker connected to the power distribution device 1 will be described with reference to FIGS. 13 and 14 .

The power distribution device 1 may include a first circuit breaker 30 and a second circuit breaker 31 .

The first circuit breaker 30 may be disposed on the main panel 20b, connected to the other end 7b of the second busbar, and electrically connected to the external first power source 100.

For example, the first circuit breaker 30 may be disposed in the third area 20bc of the main panel 20b. For example, the first circuit breaker 30 may be connected to the other end 7b of the second busbar that protrudes into the front space by being bent to go over the upper end of the third area 20bc of the main panel 20b.

For example, the first circuit breaker 30 is inserted into the breaker insertion portion 90c of the expansion terminal 90 disposed in the third area 20bc, and the other end 7b of the second bus bar is inserted into the expansion terminal 90. ), the first circuit breaker 30 and the other end 7b of the second busbar can be connected. The first circuit breaker 30 inserted into the circuit breaker insertion part 90c may have a wire insertion part into which a wire connected to the first power source 100 is inserted.

The first circuit breaker 30 may have a manual switch on the front side, which can be turned on or off at will by the user.

The first circuit breaker 30 may be disposed adjacent to an upper end of the main panel 20b. For example, the first circuit breaker 30 may be disposed adjacent to an upper end of the third region 20bc.

Therefore, the front exposure area of the other end 7b of the second busbar exposed to the front space to be connected to the first circuit breaker 30 is minimized, thereby protecting the user from the risk of electric shock.

The second circuit breaker 31 may be disposed on the main panel 20b, connected to the other end 8b of the third bus bar, and electrically connected to the second external power source 101.

For example, the second circuit breaker 31 may be disposed in the first area 20ba of the main panel 20b. For example, the second circuit breaker 31 may be connected to the other end 8b of the third busbar, which is bent over the upper end of the first area 20ba of the main panel 20b and protrudes into the front space. The second circuit breaker 31 disposed on the main panel 20b may have a wire insertion portion into which a wire connected to the second power source 101 is inserted at the lower side.

The second circuit breaker 31 may have a manual switch on the front side, which can be turned on and off at will by the user.

The second circuit breaker 31 may be disposed adjacent to an upper end of the main panel 20b. For example, the second circuit breaker 31 may be disposed adjacent to an upper end of the first area 20ba.

Therefore, the front exposed area of the other end 8b of the third busbar exposed to the front space to be connected to the second circuit breaker 31 is minimized, thereby protecting the user from the risk of electric shock.

Hereinafter, referring to FIG. 14 , a state in which wires are connected to the opening hole of the case 2 and the power distribution device 1 will be described.

The case 2 may include a first opening hole 2ha on the lower side which is opened to correspond to the first terminal block 50a in the vertical direction and into which wires are introduced. For example, the first opening hole 2ha may be located on the same line as the first terminal block 50a on the lower panel 2e of the case 2 in the vertical direction.

The case 2 may include a second opening hole 2hb opened to correspond to the second terminal block 50b in the vertical direction on the lower side and into which a wire is introduced. For example, the second opening hole 2hb may be located on the same line as the second terminal block 50b on the lower panel 2e of the case 2 in the vertical direction.

The case 2 may include a third opening hole 2hc opened to allow wires to enter the side surface. For example, the third opening hole 2hc may be formed in the right side panel 2g of the case 2 .

The case 2 may include a fourth opening hole 2hd on the lower side which is opened to correspond to the third terminal block 50c in the vertical direction and into which wires are introduced. For example, the fourth opening hole 2hd may be located on the same line in the vertical direction with the third terminal block 50c on the lower panel 2e of the case 2 .

The case 2 may include a fifth opening hole 2he on the lower side which is opened to correspond to the fourth terminal block 50d in the vertical direction and into which wires are introduced. For example, the fifth opening hole 2he may be located on the same line as the fourth terminal block 50d on the lower panel 2e of the case 2 in the vertical direction.

The case 2 may include a sixth opening hole 2hf opened to allow wires to enter the side surface. For example, the sixth opening hole 2hf may be formed in the left side panel 2f of the case 2 . (See Fig. 2)

The opening hole is generally closed by a separate injection molding material, and the installer can easily remove the injection molding material to be opened when necessary.

Wires connecting the first terminal block 50a and the commercial load 102 may be introduced through the first opening hole 2ha.

An electric wire connecting the third terminal block 50c and the commercial load 102 may be introduced through the fourth opening hole 2hd. A wire connecting the third terminal block 50c and the second power source 101 may be introduced through the fourth opening hole 2hd.

An electric wire connecting the fourth terminal block 50d and the 1-1 power source 100a may be introduced through the fifth opening hole 2he. An electric wire connecting the fourth terminal block 50d and the emergency load 103 may be introduced through the fifth opening hole 2he.

A wire connected to the third terminal block 50c and the fourth terminal block 50d may be an electrical neutral wire. At this time, it is natural that the neutral wire of another electric wire drawn into the power distribution device 1 can be connected to the third terminal block 50c and the fourth terminal block 50d.

An electric wire connecting the second terminal block 50b and the emergency load 103 may be introduced through the second opening hole 2hb. An electric wire connecting the second terminal block 50b and the second power source 101 may be introduced through the second opening hole 2hb.

An electric wire connecting the 1-1 circuit breaker 30a and the 1-1 power source 100a may be introduced through the third opening hole 2hc. However, the opening hole through which the wire connecting the 1-1 circuit breaker 30a and the 1-1 power source 100a is introduced into the power distribution device 1 may be disposed in the installation space of the power distribution device 1. It may be appropriately changed according to the location of the 1-1st power source 100a.

Therefore, by properly arranging the parts to which the wires are connected in the power distribution device (1) and designing the busbar to enable this arrangement, the wire coming from the outside is straight or close to a straight line inside the power distribution device (1). By being able to be arranged, inefficient space occupied when the electric wire is curved can be reduced and the volume of the power distribution device 1 can be reduced.

Meanwhile, the connection state of the wires outside the power distribution device 1 may vary depending on the condition of the installation space or the wiring environment, regardless of what is shown in FIG. 14 .

Hereinafter, the shape of the front panel 2b will be described with reference to FIG. 16 .

The front panel 2b may include a 4-1 opening 2ba opened to correspond to the first circuit breaker 30 in the forward and backward directions. A plurality of the 4-1 openings 2ba may be formed corresponding to the plurality of first circuit breakers 30 provided.

The front panel 2b may include a 4-2 opening 2bb opened to correspond to the second circuit breaker 31 in the forward and backward directions.

The front panel 2b may include a 4-3 opening 2bc opened to correspond to the aforementioned touch display 80 in the forward and backward directions.

The power distribution device 1 may further include a reset switch 70 that allows the power distribution device 1 to be reset. The reset switch 70 may be electrically connected to the main PCB 4a.

The front panel 2b may include a 4-4 opening 2bd opened to correspond to the reset switch 70 in the forward and backward directions.

The power distribution device 1 may further include a storage device port 71 capable of transmitting an operation record of the power distribution device 1 to an inserted removable storage device. The storage device port 71 may be electrically connected to the main PCB 4a. The storage device port 71 may be a general USB port.

The front panel 2b may include fourth to fifth openings 2be opened to correspond to the storage port 71 in the forward and backward directions.

The 4-4th opening 2bd and the 4-5th opening 2be may be integrally formed.

Therefore, through the opening formed in the front panel 2b, the user can manipulate the parts accommodated inside the case 2 without separating the front panel 2b, thereby improving the user's management convenience and preventing electric shock. can

The accompanying drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed in this specification is not limited by the accompanying drawings, and all changes and equivalents included in the spirit and technical scope of the present invention It should be understood to include water or substitutes.

Similarly, in the present embodiment, only the case where the wires are aligned with the lower surface of the case 2 and drawn in a form close to a straight line has been described, but the present invention is the direction in which the wires are drawn in or the position of the internal structure within the range where the wires are not curved. It should be understood as including all cases where is changed.

Similarly, in this embodiment, since the operator or user is classified into the front space and the rear space on the premise of accessing the front panel side of the case, if the opening panel and the operator's access direction are different, the installation panel arrangement and It is natural that the same technical idea can be implemented by changing the arrangement of the busbars.

In addition, although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Of course, various modifications are possible by those skilled in the art, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

power distribution unit 1 case 2
Wireless communication module 3 Control unit 4
1st bus bar 6 2nd bus bar 7
Bus bar 3 8 Bus bar 4 9
1st relay 10 2nd relay 11
Installation panel 20 1st circuit breaker 30
2nd circuit breaker 31 CT sensor 40
Terminal Block 50 Reset Switch 70
Storage Port 71 Touch Display 80
Display Bracket 81 Expansion Terminal 90
First power source 100 Second power source 101
Normal load 102 Emergency load 103
electricity meter 104

Claims (15)

A case including a front panel that is opened and closed;
an installation panel disposed inside the case to face the front panel and dividing the inside of the case into a front space and a rear space;
a pair of first bus bars disposed in the left and right directions in the rear space;
a pair of second busbars disposed vertically in the rear space, one end connected to the first busbar and the other end protruding into the front space;
5 a pair of third busbars disposed vertically in the rear space, having one lower end and the other upper end protruding into the front space, and having one end connected to the first busbar; and
and a pair of fourth busbars disposed vertically in the rear space, one end connected to the other end of the first busbar and the other end protruding into the front space. According to claim 1,
The second bus bar,
It is formed extending upward from the first bus bar,
The fourth bus bar,
A power distribution device extending downward from the first bus bar. According to claim 2,
The installation panel,
a main panel on which the first to fourth busbars are disposed at a rear side, and the other ends of the second busbar and the third busbar are disposed at an upper end; and
a bent portion extending rearward from the lower end of the main panel and including an opening through which the other end of the fourth bus bar and one end of the third bus bar pass;
A space in which a terminal block having a partition wall extending downward from the rear end of the bent portion and protruding forward is provided and connects the other end of the fourth busbar and one end of the third busbar with electric wires coming in from the outside. A power distribution device comprising a; low panel forming a. According to claim 3,
a first circuit breaker disposed on the main panel, connected to the other end of the second bus bar, and electrically connected to an external first power source;
a second circuit breaker disposed on the main panel, connected to the other end of the third bus bar, and electrically connected to an external second power source;
a first terminal block disposed on the low panel, connected to the other end of the fourth bus bar, and electrically connected to an external commercial load; and
The power distribution device further includes a second terminal block disposed on the low panel, connected to one end of the third bus bar, and electrically connected to an external emergency load. According to claim 4,
The case is
a first opening hole on the lower side of which is opened to correspond to the first terminal block in a vertical direction and into which a wire is introduced; and
The power distribution device further comprising a second opening hole opened to correspond to the second terminal block in the vertical direction on the lower side and into which a wire is introduced. According to claim 4,
a first relay disposed between a point where the other end of the first busbar and the second busbar are connected in the first busbar, and opening and closing a circuit; and
The power distribution device further includes a second relay disposed between a point where one end of the first busbar and the second busbar are connected in the first busbar, and opens and closes an electric path. According to claim 6,
The main panel is
A power distribution device in which a part is opened so that the manual switches of the first relay and the second relay are exposed forward. According to claim 4,
The first circuit breaker and the second circuit breaker,
A power distribution device disposed adjacent to an upper end of each of the main panels. According to claim 4,
The front panel,
A power distribution device that is opened to correspond to the first circuit breaker and the second circuit breaker in the forward and backward directions. According to claim 4,
The power distribution device,
a conductive panel to which the other end of the second bus bar is connected; and
Further comprising an expansion terminal including a circuit breaker insertion portion protruding from the conductive panel,
The first circuit breaker,
A power distribution device inserted into the circuit breaker insertion part. According to claim 10,
The first power source,
plural,
The first circuit breaker,
It is provided in a plurality corresponding to the plurality of first power sources,
The circuit breaker insertion part,
The power distribution device in which the plurality of first circuit breakers are formed in plurality so as to share side surfaces adjacent to each other. According to claim 1,
The power distribution device,
Further comprising a touch display displaying a menu for monitoring or manipulating the power distribution device,
The front panel,
A power distribution device that is opened to correspond to the touch display in the forward and backward directions. According to claim 1,
The power distribution device,
Further comprising a reset switch capable of resetting the power distribution device,
The front panel,
A power distribution device that is opened to correspond to the reset switch in the forward and backward directions. According to claim 1,
The power distribution device,
Further comprising a storage device port capable of transmitting the operation record of the power distribution device to an inserted removable storage device,
The front panel,
A power distribution device that is opened to correspond to the storage device port in the forward and backward directions. According to claim 4,
The other end of the fourth busbar and one end of the third busbar,
It extends downward and is connected to the first terminal block and the second terminal block, respectively,
The other end of the second busbar and the other end of the third busbar,
A power distribution device that is bent to ride over the upper end of the main panel in a forward direction and is connected to the first circuit breaker and the second circuit breaker, respectively.

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