KR100984143B1 - Multiple conductor connection apparatus and power distributor using the same - Google Patents

Abstract

The present invention relates to a multi-conductor connection device and a distribution panel using the same, and in particular, to simplify the structure of the connection device for connecting a plurality of conductors, and to minimize the volume of the multi-conductor connection to increase the space utilization of the distribution panel and distribution panel The present invention relates to an apparatus and a distribution board using the same.
To this end, the present invention
An upper plate in the form of a plate of conductors;
A lower plate formed in a plate shape of a conductor and positioned in a lower portion of the upper plate, and having a plurality of wire insertion grooves formed on an upper surface thereof; An insulating plate formed in a plate shape of an insulator and stacked on an upper portion or a lower portion of the upper plate;
The upper plate, the lower plate, and the insulating plate are repeatedly stacked at least one or more times in order, and the multi-conductor connection device is configured such that the upper plate, the lower plate, and the insulating plate are repeatedly fixed one or more times by a fixing means.
The multi-conductor connection device is fixedly mounted in the enclosures of the switchboard and the distribution panel, and is configured to be electrically connected to the upper level breakers on each of the upper and lower panels.

Description

Multiple conductor connection apparatus and power distributor using the same

The present invention relates to a multi-conductor connection device and a distribution panel using the same, and in particular, to simplify the structure of the connection device for connecting a plurality of conductors, and to minimize the volume of the multi-conductor connection to increase the space utilization of the distribution panel and distribution panel The present invention relates to an apparatus and a distribution board using the same.

In general, all electrical places are equipped with switchboards and distribution boards containing overcurrent breakers for protecting humans, livestock and power facilities by cutting off electrical connections when abnormal currents such as normal switching, leakage or overcurrent flow.

As shown in FIG. 1, the conventional switchboard and the distribution panel are installed in the front of the enclosure 1 so that the door can be opened and closed, and a base plate 2 made of steel is installed in the inner rear of the enclosure 1. It is.

In addition, a parking short circuit 3 for receiving current supplied from an upper level is provided on the upper side of the base plate 2 in the same standard as the upper level circuit breaker, and the parking short circuit 3 has a plurality of parking short circuits below. The busbars 4 are arranged side by side in the longitudinal direction, and the branch conductors 6 are connected to the busbars 4 in the transverse direction, so that the branch conductors are connected to the branch devices 5 installed on both sides of the lower side of the parking terminal 3. Both ends of 6) are connected by bolting so that the branch device 5 and the parking terminal 3 are electrically connected.

Accordingly, the parking shorter 3 is capable of supplying power to the electrical equipment connected to each branch device 5 through the busbar 4 and the branch conductor 6.

By the way, such a conventional switchboard and distribution panel is necessary when the renovation or expansion of the same type of kit is essentially necessary to take time to respond to this, and also due to the structural problem due to the arrangement of the parking short (3) Since the standard of 3) should be installed with the same standard as the upper level breaker, there is a problem that the electrical protection coordination is uncertain even in the local accident, and the power failure or failure range is extended to the switchboard or distribution panel, causing economic loss.

In addition, each element inside the switchboard and the distribution panel, that is, the parking shorter (3), busbar (4), branching device (5), branch conductor (6) is fixed to the corresponding position in the form of a fixed form of the enclosure (1) Since space utilization is very low and it is almost impossible to install another power distribution or distribution equipment, additional distribution boards and distribution boards need to be additionally installed, so there is a problem not only in terms of installation cost but also in appearance.

Therefore, in order to solve this problem, the present invention proposes a multi-conductor connection device for fixing a detachable by installing a plate made of a conductor in multiple stages, and inserting an electric wire into a hole formed in the plate so that the fixation is made. The purpose of the present invention is to provide a multi-conductor connection device and a distribution / distribution board using the same to maximize the space utilization of the enclosure by installing the multi-conductor connection device in the distribution board and the distribution board.

The present invention for achieving this object,

An upper plate in the form of a plate of conductors;

A lower plate formed in a plate shape of a conductor and positioned in a lower portion of the upper plate, and having a plurality of wire insertion grooves formed on an upper surface thereof; An insulating plate formed in a plate shape of an insulator and stacked on an upper portion or a lower portion of the upper plate;

The upper plate, the lower plate, and the insulating plate are repeatedly stacked at least one or more times in order, and the multi-conductor connection device is configured such that the upper plate, the lower plate, and the insulating plate are repeatedly fixed one or more times by a fixing means.

The multi-conductor connection device is fixedly mounted in the enclosures of the switchboard and the distribution panel, and is configured to be electrically connected to the upper level breakers on each of the upper and lower panels.

The multi-conductor connection device of the present invention configured as described above has a structure capable of maximally connecting a plurality of cables having various diameters to a small volume when multiple connections are made, thereby maximizing the space utilization of the enclosure when applied to switchboards and distribution panels. You can.

In other words, when the multi-conductor connection device of the present invention is placed in the existing parking short-circuit position, it can be connected by a branch device and an electric wire at the bottom, so that a busbar and a branch conductor of a standard form are not needed, Wiring by wires is possible, and the cost of busbars and branch conductors is eliminated.

Of course, it is not necessarily installed at the location of the existing parking short circuit, but it can be mounted at any position inside the enclosure and connected to the branch device by wiring, so that it is possible to change and fix it to various positions instead of the fixed position, thereby making space utilization. This is to be maximized.

In addition, by minimizing the connection point of the wire to one point in the multi-conductor connection device, it is effective to monitor the normality of the electrical connection point at a glance.

1 is a view showing the structure of a conventional switchboard and distribution panel.
Figure 2 is an exploded perspective view of the multi-conductor connection device of the present invention.
3 is a combined view of FIG.
4 is an exploded view of a wiring connector;
Figure 5 is a view for explaining the shape and position of the upper plate and the lower plate, and the latch.
6 is a diagram for explaining a state in which wires are connected.
7 is a view showing another form of the latch.

The present invention will be described with reference to the accompanying drawings.

As shown in FIG. 2, the multi-conductor connection device of the present invention includes a housing 100, a wiring connector 200, a support bar 400, and a cover 500.

The housing 100 is formed with the side support plates 110 and 120 standing up on both sides of the bottom of the plate shape, so that the receiving space 130 for receiving the wiring connector 200 therebetween is formed, and the side support plates 110 and 120 of the Both edges are bent inward to prevent the wiring connector 200 accommodated in the accommodation space 130 from being separated from the front and the rear.

In addition, a support bar fastening hole 101 for fixing and installing the wiring connector 200 is formed at the bottom of the housing 100, and a bolt for fastening the cover 500 to the upper surface of the side support plates 110 and 120. The fastening holes 111 and 121 are formed, respectively, and the lower outer side protrudes, and the mounting hole 102 is formed in the protruding portion thereof, so that the fastening holes 111 and 121 are fixed to the specific mechanism by bolts or the like.

The wiring connector 200 has a form in which a plurality of plates are stacked, which will be described in detail with reference to FIG. 4.

The wiring connector 200 is largely composed of the upper plate 210, the lower plate 220, and the insulating plate 230, the upper plate 210 is in the form of a plate made of a conductor, the support bar 400 on the edge Support bar insertion hole 211 for inserting through the through is formed.

The lower plate 220 is stacked below the upper plate 210, and a plurality of wire insertion grooves 221 are formed from a direction exposed to the front surface of the housing 100 to the rear, and at this time, an upper side of the wire insertion groove 221. Is formed in an open state.

The wire insertion groove 221 may have various sizes as shown in FIG. 4 depending on the thickness of the wire inserted therein.

In addition, the lower plate 220 is formed with a support bar insertion hole 222 penetrated at the same position as the support bar insertion hole 211 of the upper plate 210.

In addition, the lower surface of the upper plate 210 is formed in each of the groove-shaped latch mounting space 212 is formed in a position corresponding to the wire insertion groove 221 of the lower plate 220, this latch mounting space 212 ), As shown in Figure 5 is equipped with a latch 240 to prevent the reverse drawing after the insertion of the wire.

An insulating plate 230 made of an insulator is stacked below the lower plate 220. Protruding jaws 231 and 232 protruding upward are formed at both sides of the lower plate 220 to stack the upper plate 210 and the lower plate 220. It is to be stably supported, this also has a support bar insertion hole 233 is formed.

The upper plate 210, the lower plate 220, and the insulating plate 230 is repeatedly stacked at least once or more times, and the stacked height is different depending on the number of wires to be inserted, and according to the thickness of the wires The size of the insertion groove 221 may vary.

The stacked wiring connector 200 is accommodated and mounted in the housing space 130 inside the housing 100, and the support bar 400 having a long bolt shape is inserted through each of the support bar insertion holes 211, 222, and 233 so that the housing ( 100 is fastened to the support bar fastening hole 101 of the bottom by the wiring connector 200 is fixed to the inside of the housing 100 is installed.

At this time, in order to prevent the upper and lower plates stacked by the insulating plates to be electrically insulated from each other by being electrically connected by the support bar 400, an insulating ring 300 is inserted into the support bar insertion holes of the upper and lower plates. ) To ensure insulation.

To this end, the support bar insertion holes of the upper plate and the lower plate should be formed larger than the support bar insertion hole of the insulating plate so that the insulating ring 300 is fitted.

The cover 500 is covered with an upper portion of the housing 100, and the bolt 510 is coupled to the bolt fastening holes 111 and 121 of the housing 100 by passing through the cover 500, thereby coupling is performed as illustrated in FIG. 3.

Further, by supplying power to each of the upper or lower plates separated by the insulating plate, separate power is supplied to the upper and lower plates stacked on the upper side and the upper and lower plates stacked on the lower side of the insulating plate. May selectively supply power with different power sizes.

In addition, the supply of power is electrically connected to each other by connecting electric wires between the stacked upper and lower plates, or bolting the electric wires to any one of the upper and lower plates.

On the other hand, the fasteners 240 mounted on the fastener mounting space 212 of the upper plate 210 is formed of a leaf spring having an elasticity as shown in Figure 5, the shape has a semi-circular shape so that the semicircle portion It is inserted into the latch mounting space 212, and the rear side thereof is flat so that it is fixed to the top plate 210 as shown in Fig. 6 (a).

Therefore, the front end of the locking hole 240, that is, the semi-circular end portion protrudes downward of the upper plate 210 to protrude upward of the wire insertion groove 221 of the lower plate 220.

Therefore, when the multi-conductor, that is, the electric wire C is inserted from the front of the electric wire insertion groove 221, the semi-circular front of the locking hole 240 is elastically bent to the rear as shown in FIG. At the time of the reverse drawing of C), the latching hole 240 is bited to the upper side of the wire C, thereby preventing the detachment.

7 is a view showing another form of the latch 240, by having a similar shape to the right triangle can perform the operation of the latch described above, it can be modified in various forms as well as this form.

The state in which the multi-conductor connection device of the present invention is applied to a distribution box and a distribution box will be described.

Referring to the case where the multi-conductor connecting device of the present invention is mounted at the position of the parking shorter 3 as shown in FIG. 1, the bottom portion of the housing 100 contacts the parking shorter 3 position of the base plate 2. And then bolted through the mounting hole 102 to secure the multi-conductor connecting device.

At this time, the front of the housing 100 is preferably mounted to the lower side, and the power supplied through the wires from the circuit breaker of the upper level is separated into each insulating plate bolted to the rear of the plurality of upper or lower plates stacked Electrically connected by a variety of methods, such as, the front of the housing 100 is installed in the downward direction, so that one end of the electric wire from the bottom into the wire insertion groove and the other end is connected to the branch device (5) electrically Will be connected.

As a result, even if there is no bus bar 4 and branch conductor 6 shaped as in the related art, power of the upper level breaker is branched and supplied to each branch device 5 by an electric wire.

Of course, the multi-conductor connection device can be easily mounted by moving to the side as well as the location of the parking short (3), and the other switchboard and distribution board equipment may be installed at the location of the existing parking short.

100 housing 200 wiring connection port
210: top plate 212: hanger mounting space
220: lower plate 221: wire insertion groove
230: insulation plate 240: latch
300: insulation ring 400: support bar
500: cover

Claims (4)

An upper plate in the form of a plate of conductors;
A lower plate formed in a plate shape of a conductor and positioned in a lower portion of the upper plate, and having a plurality of wire insertion grooves formed on an upper surface thereof;
An insulating plate formed in a plate shape of an insulator and stacked on an upper portion or a lower portion of the upper plate;
And the upper plate, the lower plate, and the insulating plate are stacked in this order, and the stacked upper plate, the lower plate, and the insulating plate are integrally fixed by fixing means.
According to claim 1, wherein the lower surface of the upper plate corresponding to the position where the wire insertion groove of the lower plate is formed, the locking hole mounting space is formed, the locking hole mounting space to prevent the separation of the wire inserted into the wire insertion groove of the lower plate Multi-conductor connection device characterized in that the latch is mounted to.
The multi-conductor connection device according to claim 1, further comprising a housing in which the stacked upper plate, lower plate, and insulating plate are accommodated, wherein the front part of the housing is open so that the portion where the wire insertion groove is formed is exposed to the outside.
An upper plate in the form of a plate of conductors;
A lower plate formed in a plate shape of a conductor and positioned in a lower portion of the upper plate, and having a plurality of wire insertion grooves formed on an upper surface thereof;
An insulating plate formed in a plate shape of an insulator and stacked on an upper portion or a lower portion of the upper plate;
The upper plate, the lower plate, and the insulating plate are stacked in order, and the stacked upper plate, the lower plate, and the insulating plate are configured to have a multi-conductor connecting device to be fixed integrally by fixing means.
The multi-conductor connection device is fixedly mounted in the enclosure of the distribution panel and the distribution panel, each upper panel or the lower panel distribution and distribution panel using a multi-conductor connection device, characterized in that configured to be electrically connected to the breaker of the upper level.

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