KR100787151B1 - Captive power distribution unit - Google Patents

Abstract

The present invention relates to a power distribution device, and in particular, connected to a bus bar and supplied with power so that power can be distributed from the pull-out terminal to the load side after one or more outgoing terminals are sequentially installed in an integrated or assembled bus bar. Thus, one or more outgoing terminals are bound to a bus booth that can be connected to a plurality of buses without binding many distribution lines to the bus, thereby preventing connection failure due to the direct connection between the wires and the occurrence of fire. The invention relates to a fastening type power distribution device that can enhance worker safety, work speed and beauty, and can evenly distribute load, thereby increasing efficiency of facility investment.

Bus Booth, Captive Pullout Terminal, Load Terminal

Description

Fastening type power distribution unit {Screw type Power distributor}

1 is a conceptual diagram of a conventional power distribution scheme,

2 is a perspective view of a power distribution device according to the present invention;

3 is an exploded perspective view of an embodiment of a power distribution device according to the present invention;

4a and 4c are exploded perspective views of another embodiment of a power distribution device according to the present invention;

5 is an exploded perspective view of yet another embodiment of a power distribution device according to the present invention;

6a and 6b are exploded perspective views of yet another embodiment of a power distribution device according to the present invention;

7 is an exploded perspective view of yet another embodiment of a power distribution device according to the present invention;

8 is an exploded perspective view of yet another embodiment of a power distribution device according to the present invention;

9a and 9b an exploded perspective view of yet another embodiment of a power distribution device according to the present invention;

10 and 11 are an exploded perspective view of yet another embodiment of a power distribution device according to the present invention.

<Explanation of symbols for the main parts of the drawings>

100: busbar terminal 200: busbar booth

300: withdrawal terminal 400: load terminal

The present invention relates to a power distribution device for distributing power applied from a bus, and more particularly, a tightening power distribution device in which a plurality of drawing terminals are fastened to a bus booth connected to a plurality of buses having respective phases and energized. It is about.

In general, in order to supply a plurality of loads with power supplied from electric poles, the supplied power must be distributed for each load.

In order to distribute the power as described above, a method of drawing a power source by directly attaching an electric wire to a bus bar is conventionally described, which will be described below with reference to FIG. 1.

The power source shown in FIG. 1 is an example of a three phase four wire, that is, three phases and four wires.

Conventionally, after exposing four wires M1, M2, M3, and M4 housed inside the bus M, a load, that is, an electrical device or the The electric power is distributed through the electric meters C1, C2, and C3 installed in the middle of the electric devices.

In other words, when the load is a motor requiring a three-phase power source, four distribution lines are respectively bound to four wires drawn from the bus bar. In addition, the meter (C2) to be connected to the other load or the load side is used in accordance with various power requirements, such as in the case of using only the other line, for example, M1 and M2 line.

However, in the case of the conventional distribution method, the lead wires M1, M2, M3, and M4 are distributed to each load, that is, an electric device or a meter, so that the amount of the distribution lines bound to the lead wires becomes large, resulting in poor contact. There is a problem that the risk of occurrence is high, thereby increasing the risk of fire.

In addition, as described above, since a plurality of distribution lines are bound to the lead wires, if the power supply of a certain electric device is changed, it is difficult to find a distribution line that is bound to the electric device and change it again.

The present invention is to solve the above-described problems, after installing a plurality of take-out terminal in the bus booth that is powered from the bus, so that the power is distributed from the take-out terminal to the load side to reduce the contact failure and thereby reduce the risk of fire In the meantime, the purpose of the present invention is to provide a fastening type power distribution device capable of improving the convenience of the operation by only replacing the corresponding drawing terminal when the power of the load is changed.

The above-described object is a device for distributing power from a single bus booth to a plurality of load sides by sequentially installing a drawing terminal in a bus booth that is energized with a bus having each phase, wherein the bus booth is embedded in an insulator while Each busbar busbar is energized, and the drawing terminal is embedded in an insulation plate, while one side is fastened to the busbar busbar and is in close contact, and the other side includes a built-in busbar connected to a load side wire for applying power to the load side. It can be achieved by a captive power distribution device.

Hereinafter, with reference to the accompanying drawings and embodiments will be described in more detail the configuration of the present invention.

According to the present invention, after the plurality of drawing terminals 300 are installed in the bus booth 200 to which power is applied from the bus, the power is distributed from the drawing terminals 300 to a plurality of loads. In this case, the power is applied to the load side by the load terminal 400 connected to the drawing terminal 300, and according to the type of the drawing terminal 300, each embodiment will be described.

However, when the busbar booth 200 is described first, the busbar booth 200 includes an insulator 210 having a plurality of busbar booths 220 that receive power from each phase applied through the busbar. do.

The number of busbar booths 220 is determined according to the power supplied, and in FIG. 3A, three-phase, four-wire, that is, three-phase and four-wire power sources are described. 220 is shown.

In this case, the copper band refers to a rod shape made of copper, and in the present invention, copper having excellent conductivity is used. However, even when using a material having excellent conductivity as the material other than the copper, such as aluminum, of course, it belongs to the scope of the present invention.

The drawing-out terminal 300 and the load terminal 400 as described below are provided in the bus booth 200 having the structure as described above.

However, in order to apply power to the busbar busbar 220 of the busbar booth 200 as described above, it is also possible to directly contact the busbar 110, but preferably, as shown in FIG. 2, the busbar terminal ( It is helpful for safety to apply power in 100).

Similar to the bus booth 200, the bus terminal 100 includes a bus bar ties 120 embedded in the insulator 130 and connected to the bus bus 110. At this time, it is also preferable to block the outside by adding a joint 140 to surround the connecting portion of the bus bar dongdae 120 and the bus bar 110.

By this configuration, power is applied from the bus bar 110 to the bus bar 120, and the connector C is used to transfer the power to the bus booth 200.

The connector (C) is for connecting the bus terminal 100 and the bus booth 200, and is closely attached to the bus bus bar 120 and the bus bus bar 220 at the same time to transmit power. It consists of a connection terminal C1 and the board-shaped insulating plate C2 to which the said connection terminal C2 is fixed. At this time, it may be tightened by a fastening means such as a bolt in order to be in close contact.

By this configuration, power is transmitted from the bus bar 110 to the bus booth 200.

Hereinafter, the withdrawal terminal 300 may be attached to the bus booth 200 having the above-described configuration so that power can be distributed to the load side. Hereinafter, each embodiment will be described according to the type of the withdrawal terminal 300. Let's do it.

Example 1

In this embodiment, as shown in Figure 3 will be described with respect to the drawing terminal 310 is directly coupled to the bus booth 200 and directly connected to the wire for applying power to the load side.

The withdrawal terminal 310 has a shape in which a plurality of built-in copper bars 312 are installed on the insulating plate 311, one side of which is in close contact with the busbar busbars 220, and the other side of which is directly connected to the load-side wire 314. . In this case, the method of connecting the built-in shaft 312 and the load-side wire 314 may be a bolt tightening type, or may be integrally formed by crimping the built-in shaft 312 and the load-side wire 314.

By this configuration, the power of each phase can be drawn out from the bus booth 200. At this time, through the through-hole (not shown) to form the through-hole (312) and the busbar busbar 220 in the built-in busbar 312 in order to closely contact the withdrawal terminal 310 to the busbar busbar 220 Fastening means (B) to be tightened It is preferable to tighten using a bolt, for example.

On the other hand, it is also preferable to add a hanger 313 composed of a fixing part 313a and a locking pin 313b fixed by the fixing part 313a on the insulating plate 311. This is not only easy to remove the withdrawal terminal 310 installed by the hanger 313, but also by installing the adjacent withdrawal terminal can hang and insert the insulating plate of the withdrawal terminal to be installed on the hanger 313 Because it is convenient. The hanger 313 of this configuration can be applied to all of the withdrawal terminal to be described later, detailed description thereof will be omitted.

Example 2

In the present embodiment, the withdrawal terminal 320 coupled to the bus booth 200 and applying power to the load side using the load terminal will be described with reference to FIG. 4A.

The withdrawal terminal 320 has a plurality of built-in dongdae 322 in the insulating plate 321. One side of the built-in shaft 322 is in close contact with the busbar booth 220, the other side of the built-in shaft 322 is connected to the load terminal 420.

In other words, one side of each of the built-in copper bars 322 is combined with the busbar booth 220 to draw power from each phase, and then draw power to the load. At this time, the through-hole 324a is formed at one side of the built-in shaft 322, and at the same time, a fixing hole (without reference numeral) is formed in the bus booth shaft 220, and then passes through the through-hole 324a and the fixing hole. Fastening means (B) For example, tightening using a bolt can be more firmly in close contact.

If a plurality of such drawing terminals 320 are installed in the bus booth 200, the power supply can be drawn out from one bus booth 200 to a plurality of load sides, and the combination thereof is also stable, thereby preventing contact failure as in the prior art. Fire can be prevented by

In addition, if the type of power required by the load is changed, for example, even if the load is changed by using a three-phase power source and using a single-phase power source, only the drawing terminal may be changed to increase the convenience of work. There is also an effect.

Meanwhile, the load terminal 420 is used together with the drawing terminal 320 to supply power to the load side.

The load terminal 420 includes a load strip 422 to which the built-in strip 322 of the lead terminal 320 is tightly coupled, and an insulator 423 to which the load strip 422 is built. At this time, the power is applied to the load by the wire 421 connected to the load shaft 422 to the load side.

On the other hand, the built-in shaft 322 of the lead-out terminal 320 and the load shaft 422 of the load terminal 420 are in close contact with each other when power is applied to form a through hole 324b in the built-in shaft 322 side. In addition, the through hole 422a is also formed in the load shaft 422 of the load terminal 420, and then tightening the fixing means B, for example, a bolt, which penetrates the through holes 324b and 422a, provides a contact force. It is advantageous to improve electricity supply.

In this case, as shown in FIG. 4B, one side of the built-in shaft 322 is formed to protrude, while the load shaft 422 of the load terminal 420 is formed as a female, and then the built-in shaft 322 is formed. It is also possible to insert it into the load shaft 422.

In addition, as shown in FIG. 4C, the load-side wire 421 and the load shaft 422 may be integrally formed, and a wire cover D surrounding the load-side wire 421 may be added to the load-side wire. It is also possible to modularize 421.

In this case, it is preferable that the wire 421 uses a braided wire having good bendability. This configuration is applicable to all of the load terminal to be described later, detailed description thereof will be omitted.

Example 3

The withdrawal terminal 350 of the third embodiment is capable of withdrawing power in both directions and will be described below with reference to FIG. 5.

As shown in FIG. 5, the withdrawal terminal 350 of the present embodiment is embedded in the insulating plate 351 and is fastened to the busbar busbar 220 to be in close contact, and both ends thereof are connected to the load terminal 450. It includes a built-in belt 352.

Meanwhile, the load terminal 450 is embedded in the insulator 453 and is connected to both ends of the built-in shaft 352 and is connected to the load shaft 452 and the load shaft 452 to transfer power to the load side. The load side wire 451 is included.

The load terminal 450 having such a configuration can draw power to both sides.

Meanwhile, as illustrated in FIG. 5, the power may be drawn out in two stages by the two-stage extraction terminal 360 positioned on the extraction terminal 350.

That is, the two-stage withdrawal terminal 360 is built in the insulating plate 361, one side is in close contact with the built-in dongdae 352, the other side is composed of a two-stage withdrawal dongdae 362 is energized As described above, the power is drawn out in two stages.

In this case, it is preferable to tighten the drawing terminal 350 and the bus booth 200 using a fastening means (B), for example, a bolt, which is the same in the case of the drawing terminal 350 and the two-stage drawing terminal 360. Do.

Example 4

The fourth embodiment relates to the withdrawal terminal 370 capable of withdrawing the single-phase power from the bus booth 200 having the power of each phase, for example, three-phase, and will be described with reference to FIG. 6A.

In the basic configuration of the drawing terminal 370, a plurality of built-in shafts 372 are embedded in the insulating plate 371 similarly to the above-described embodiment. One side of the built-in shaft 372 is in close contact with the busbar booth 220, the other side is connected to the lead terminal assembly (A).

The lead-out terminal assembly (A) is composed of a single-phase belt 374 built in the insulator 373 and connected to the other side of the built-in shaft 372 and a neutral shaft 375 formed between the single-phase shaft 374. .

That is, the single-phase coil 374 is composed of an N-phase coil 374a, an A-phase coil 374b, a B-phase coil 374c, and a C-phase coil 374d having power of each phase.

In this case, the neutral band 375 is formed between the single phase band 374 and is not connected to the draw band 372 of the drawing terminal 370, but rather is energized with the N phase band 374a to supply a neutral power source. Have.

At this time, in order to energize the N-phase dongdae 374a and the neutral dongdae 375, the neutral dongdae 375 passes through the lower surface of the insulator 373 below the N-phase dongdae 375 and the N-phase dongdae 375a. ) And the lower portion of the N-phase single phase shaft 374a may be provided with a neutral connecting shaft 376.

A single phase power supply can be drawn out to the lead-out terminal assembly A having such a configuration. That is, if the C phase power source is to be drawn out, the neutral phase band 375c adjacent to the C phase band 374d may be drawn out.

In this case, as described above, when the single phase power supply is drawn out, a load terminal 470 similar to the drawing terminal assembly A and a connector C connecting the drawing terminal assembly A and the load terminal 470 are provided. The single phase power supply can be drawn out more conveniently.

Meanwhile, the single phase shaft 374 and the neutral shaft 375 shown in FIG. 6A may be formed to be flat to be fixed by the connector C and the fastening means, and as shown in FIG. It is also possible to form the single-phase shaft 374 and the neutral shaft 375 of the A) to be recessed to insert the connector (C).

Example 5

In the case of the fifth embodiment is applicable to all of the other embodiments as to the method by the locking plate to the close contact between the withdrawal terminal 380 and the bus booth 210. This will be described with reference to FIG. 7.

The busbar booth strip 212 of the present embodiment has a slit-shaped opening portion 212a formed at an upper portion different from the busbar booth shaft 220 of the above-described embodiment, and a space portion formed below the opening portion 212a. 212b).

In addition, in the case of the drawing terminal 380 of the present embodiment, the built-in strip 382 is the same as that in which the insulating plate 381 is embedded, but a through-hole is formed in a portion of the built-in strip 382 in close contact with the bus booth strip 212. After forming the 384, the nut (H1) is fitted to the through hole (384). At this time, the locking plate (H2) is installed in the lower portion of the nut (H1), the locking plate (H2) is located on the lower surface (212b) of the space portion of the busbar booth 212.

By this configuration, the lead-out terminal 380 and the bus booth 210 are firmly in close contact with each other. Referring to the action, first, the fastening means B, for example, a bolt, is connected to the nut H1. Screw). At this time, as the tightening means B rotates, the nut H1 is raised, whereby the locking plate H2 is raised.

However, the locking plate (H2) is located on the lower surface (212b) of the space portion and is caught by the space portion (212b) after being raised by a certain distance. Therefore, the drawing terminal 380 and the bus booth 210 are firmly adhered to each other because they cannot rise any more.

Since the connection configuration with the other load terminal 480 is as described above, a detailed description thereof will be omitted.

Example 6

The sixth embodiment is applicable to all the outgoing terminals of the above embodiment, and uses a braided wire as a part of a built-in shaft that is built in the outgoing terminal.

Hereinafter, a description will be given with reference to FIG. 8. For convenience of explanation, a new reference numeral 330 is used to be used for the withdrawal terminal of the present embodiment.

The drawing terminal 330 uses the built-in belt 332 embedded in the insulating plate 331 and uses the load terminal 430 as above, but a part of the built-in belt 332 is braided (W). The point of using is different.

Said braided wire is produced using an element wire and has a good bendability.

With this configuration, when the drawing terminal 330 is tightened to the bus booth 200 and the load terminal 430 by using the fastening means B, the drawing terminal is applied by bending forces added to both sides of the drawing terminal 330. The bending stress is generated in the terminal 330. At this time, the bending stress is removed by the braided wire having good bendability.

Example 7

The seventh embodiment is also applicable to all of the other drawing terminals described above, and will be described with reference to FIGS. 9A and 9B. For convenience of description, a new reference numeral 340 will be used.

The draw-out terminal 340 has the same point that the built-in strip 342 is embedded in the insulating plate 341, but differs in that the elastic member 345 is provided below the built-in strip 342.

As described above, the lead-out terminal used in the power distribution device of the present invention is tightened to one side busbar 200 by a bolt and the other side to a load terminal to receive a bending force.

This bending force can be eliminated by the elastic member 345 of this embodiment. In this case, it is also preferable to further include a separate insulating plate 346 under the elastic member 345 for a more complete insulation.

Example 8

In the eighth embodiment, a plurality of unit bus booths 220, which are not integral to the bus booths 200, are coupled to each other. This will be described with reference to FIG. 10.

The unit busbar 220 has the same basic configuration as the integrated bus bar 200, but an insertion portion 220a protruding from one side of the unit busbar 220 and an insertion space 220b formed at the other side. The point of having a structure of) is different.

In this configuration, the adjacent unit busbars 220 are inserted into and connected to the insertion space 220b.

The reason why the configuration of the unit busbar 220 is reconfigurable as described above is that when the drawer terminal 300 is used, in the case of the general integrated bus booth 200 described above, there is a waste of material remaining in the spare part. It was developed with the intention of using only necessary parts because there is a risk of challenge due to the exposure of spare parts.

In other words, if one withdrawal terminal 300 is used, one unit bus booth 220 is used, and if another withdrawal terminal 300 is added, the unit bus booth 220 is added correspondingly to waste materials. And the risk of the challenge can be eliminated, this is shown in Figure 10.

Example 9

In Example 9, the same as the unit bus booth of Example 8, but the bonding method is somewhat different. Hereinafter, referring to FIG. 11, the unit bus booth 230 according to the present embodiment includes an insertion part 230a protruding from a central portion thereof and the unit bus booth 230 to allow the insertion part 230a to be inserted therein. The insertion space 230b is formed in the other center portion of the other matters are the same as in the eighth embodiment.

As described above, there has been a problem in that a large amount of distribution lines bound to the leader line increases the risk of contact failure, thereby increasing the risk of fire. When the power supply of the electric equipment is changed, it was difficult to work because it had to find and change the distribution line that is bound to the electric equipment.

In the case of the power distribution device according to the present invention, since many distribution lines are not bound to the leader line exposed from the bus bar, a plurality of outgoing terminals are attached to one bus booth, thereby preventing contact failure and fire occurrence. In addition, when the power type of the electric device or the meter used is changed, it is possible to simply increase the convenience of work by simply replacing the drawing terminal for the power type.

Claims (15)

An apparatus for distributing power from a single bus booth to a plurality of load sides by sequentially installing a drawing terminal in a bus booth that is energized with a bus having each phase, The busbar booth includes busbar busbars that are embedded in an insulator and are respectively energized by the busbars, The drawer terminal is embedded in the insulating plate, while the one side is tightened close to the busbar booth, the other side is a fastening type power distribution device comprising a built-in ties connected to the load side wires for applying power to the load side. An apparatus for distributing power from a single bus booth to a plurality of load sides, comprising a drawing terminal sequentially tightened to a bus booth energized with each phase and an energized bus booth, and a load terminal coupled to the drawing terminal to supply power to the load side. as, The busbar booth includes busbar busbars that are embedded in an insulator and are respectively energized by the busbars, The drawer terminal is embedded in the insulating plate while one side is fastened tightly to the busbar booth, the other side includes a built-in belt connected to the load terminal, The load terminal is a fastening power distribution device characterized in that it is embedded in the insulator while the load is tightened with the other side of the built-in shaft of the drawing terminal and a load side wire connected to the load shaft to transfer power to the load side. . A plurality of load sides are formed by drawing out the power supply to both sides of a single outgoing terminal, consisting of a drawing terminal which is tightened sequentially to a bus booth which is energized with each phase and energized bus booth, and a load terminal which is coupled to the drawing terminal and delivers power to the load side. Device for distributing power to The busbar booth includes busbar busbars that are embedded in an insulator and are respectively energized by the busbars, The lead-out terminal is embedded in an insulating plate while being tightened and tightly attached to the bus bar booth, both ends include a built-in belt connected to the load terminal, And the load terminal includes a load strip that is embedded in an insulator and is tightened with both ends of the built-in strip, and a load side wire connected to the load strip to transfer power to the load side. An apparatus for distributing single phase power to a plurality of loads, comprising a drawing terminal sequentially installed in a bus booth energized with a bus each having a phase, and a drawing terminal assembly formed at one side of the drawing terminal to draw out single phase power. , The busbar booth includes busbar busbars that are embedded in an insulator and are respectively energized by the busbars, The drawer terminal includes a plate-shaped insulating plate and a built-in type belt that is tightly coupled to the busbar busbars at one side and tightly coupled to the busbar shaft at the one side thereof, and connected to the takeout terminal assembly at the other side. The draw-out terminal assembly is connected to the other side of the built-in dongdae and formed between the single phase dongdae and the single phase dongdae respectively to which the power of each phase is applied, while the neutral dongdae is energized with the N-phase single phase dongdae of the single phase dongdae, and the single phase dongdae and Captive power distribution device comprising an insulator in which the neutral band is embedded. The method according to any one of claims 1 to 4, A bus bar terminal embedded in an insulator and including bus bar ties connected to the bus bars; And a connector configured to be simultaneously coupled to the bus bar ties and the bus bar ties to transfer power applied to the bus terminal to the bus bar ties, and a plate-shaped insulating plate to which the connection terminals are fixed. A fastening power distribution device characterized in that. The method of claim 2, An outgoing terminal assembly comprising an insulator formed on a side of the outgoing terminal and an outgoing terminal installed on the insulator and connected to the load bar; And a connector configured to include a drawing terminal of the drawing terminal assembly, a connecting terminal coupled to the load shaft of the load terminal, and an insulating plate to which the connecting terminal is fixed, to transfer power from the drawing terminal to the load side. Is a captive power distribution unit. The method according to any one of claims 2 to 3, The load-side electric wire is a braided power distribution device characterized in that the load-side electric wire is modularized by a wire cover that wraps the load-side wire while using a braided wire that is woven in a plurality of small wires. The method according to any one of claims 1 to 4, And an insulating member positioned below the elastic member and an insulating plate positioned below the elastic member. The method according to any one of claims 1 to 4, Fixing means penetrating the bottom of the busbar booth and an insulator to fix the busbar booth; And an insulating plate attached below the fixing means. The method according to any one of claims 1 to 4, Fastening type power distribution device characterized in that it further comprises a hanger consisting of a fixing part formed on the insulating plate upper portion of the drawing terminal and a locking pin fitted to the fixing part. The method of claim 3, Located at the upper side of the lead-out terminal, it is built in the insulating plate, and the inside of the insulated plate while one side is fastened tightly and tightly coupled with the built-in shaft of the lead-out terminal, the other side is composed of a two-stage lead-out pulley connected to the load-side wire And a drawout terminal. The method of claim 4, wherein The neutral shaft and the N-phase single-phase belt lower portion further comprises a neutral connection band penetrating the lower surface of the insulator while energizing the lower portion of the neutral shaft and the N-phase single-phase belt to allow the neutral band to have an N phase. Captive power distribution unit. The method according to any one of claims 1 to 4, The busbar booth is a combination of a plurality of unit busbar booth, it is coupled by the insertion portion protruding on the end surface of the unit busbar booth, the insertion space formed on the other side of the unit busbar booth Power distribution unit. The method according to any one of claims 1 to 4, The busbar booth further includes a slit-shaped opening portion formed at an upper portion and a space portion formed at a lower portion thereof. The withdrawal terminal is provided with a through hole formed in a portion of the built-in shaft in close contact with the busbar busbar, a nut inserted into the through hole and inserted into an opening of the busbar busbar, and installed under the nut. The locking plate inserted into the space portion of the busbar busbar and the nut and the locking plate are raised by being screwed with the nut so that the locking plate is caught on the lower side of the opening, thereby fixing the lead terminal and the busbar to each other. And a tightening means for fastening. The method according to any one of claims 1 to 4, And a portion of the built-in shaft of the drawing terminal is formed of a braided wire.

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