KR102247688B1 - Sturcture for coupling wire of electrical distribution device - Google Patents

Abstract

According to the present invention, a track body extending along one direction, a track module extending along a longitudinal direction of the track body, and having a plurality of electrode wires installed in the track body, and a terminal for a power demand device are connected. The plurality of electrode lines in an electrical distribution device including a power output module detachably coupled to the track module and electrically connected to the plurality of electrode lines, and a terminal module electrically connecting the track module and an external power source A structure for coupling the wires of the external power source and the electrical non-conductive support formed on the terminal module; An electrode line connection member made of an electrically conductive material coupled to the support and connected by inserting the electrode line protruding from the track module; And a fixing bolt fixing the electrode line connection member to the support, wherein the electrode line connection member has an electrode line insertion hole into which the electrode line is inserted, and a fixing bolt hole in which the fixing bolt is coupled and communicates with the electrode line insertion hole. An electrode wire coupling structure of an electrical distribution device is provided, wherein the electrode wire inserted into the electrode wire insertion hole is pressed by the fixing bolt to prevent separation from the electrode wire insertion hole.

Description

Electrode wire coupling structure of electric distribution device {STURCTURE FOR COUPLING WIRE OF ELECTRICAL DISTRIBUTION DEVICE}

The present invention relates to an electrical distribution device, and more particularly, in an electrical distribution device using a power output module installed on a track module so that the position of the power output module to which a terminal for a power demand device such as a plug is connected can be changed. It relates to a structure for coupling electrode lines provided in a track module with an external power supply line.

A pipe rack system that can be easily assembled, expanded, and removed in various environments, such as industrial sites such as factories and distribution facilities, and homes, is used, and in response to this, the efficiency of work is improved, convenience is improved, and inventory management is effective. For this, application of an Internet of Things (IoT) platform to which various sensors are applied is being attempted.

In the IoT platform-based system linked to such production and distribution, a number of parts that inevitably require electricity use occur.

However, conventionally, for the use of electricity in such a large number of parts, a method such as using a power strip, which is an outlet made to be able to insert a plurality of plugs, is mainly used. Since it can be used, the expandability for the electrical connection is greatly reduced, and if electricity is needed in a number of parts spaced apart from each other, a plurality of power strips must be installed so as to be spaced apart from each other, so the cable lines connecting the power strip and external power are exposed dirty. Of course, there are problems such as twisting of each cable line.

Republic of Korea Patent Publication Registration No. 10-1067417 (2011.09.27.)

An object of the present invention is to convert electrode wires provided in the power distribution device to external power in an expandable power distribution device for concise and simple electrical connection to a large number of parts requiring electricity in various environments such as industrial sites, homes, such as factories, distribution facilities, etc. It provides a structure that connects with the line.

In order to achieve the above object of the present invention, according to an aspect of the present invention, a track body extending long along one direction, and a plurality of electrode wires extending along the length direction of the track body and installed inside the track body A power output module having a track module having a power supply, a terminal for a power demand device being connected to the track module and being detachably coupled to the track module to be electrically connected to the plurality of electrode wires, and electrically connecting the track module and an external power source. In an electrical distribution device including a terminal module, a structure for coupling the plurality of electrode wires and wires of the external power source, comprising: an electrically non-conductive support formed on the terminal module; An electrode line connection member made of an electrically conductive material coupled to the support and connected by inserting the electrode line protruding from the track module; And a fixing bolt fixing the electrode line connection member to the support, wherein the electrode line connection member has an electrode line insertion hole into which the electrode line is inserted, and a fixing bolt hole in which the fixing bolt is coupled and communicates with the electrode line insertion hole. An electrode wire coupling structure of an electrical distribution device is provided, wherein the electrode wire inserted into the electrode wire insertion hole is pressed by the fixing bolt to prevent separation from the electrode wire insertion hole.

According to the present invention, all the objects of the present invention described above can be achieved. Specifically, when the electrode wire protruding from the track module is inserted into the electrode wire insertion hole formed in the electrode wire connection member in the terminal module, it is pressed and fixed by a fixing bolt that fixes the electrode wire connection member, thereby improving the coupling force and electrical connection state. .

1 is a perspective view illustrating an electrical distribution device according to an embodiment of the present invention, and illustrates a terminal for a power demand device connected to the electrical distribution device.
FIG. 2 is an exploded perspective view showing the main module of the electric distribution device shown in FIG. 1 by separating.
3 is a perspective view of a track unit in the track module shown in FIG. 1.
4 is a cross-sectional view taken along line AA of FIG. 1.
5 is a perspective view of the power output module shown in FIG. 1.
6 is a side view of the power output module shown in FIG. 1.
7 is a bottom view of the power output module shown in FIG. 1.
FIG. 8 is an exploded perspective view of the terminal module shown in FIG. 1, showing a part of the connected track module.
9 is a perspective view showing an external wire connection from the inside of the terminal module shown in FIG. 8.
10 is a cross-sectional view illustrating a structure in which electrode wires of a track module are coupled in the terminal module shown in FIG. 8.

Hereinafter, the configuration and operation of an embodiment of the present invention will be described in detail with reference to the drawings.

1 and 2 are perspective and exploded perspective views of an electrical distribution device according to an embodiment of the present invention, respectively. 1 and 2, the electric distribution device 100 according to an embodiment of the present invention is detachably coupled to the track module 110 and the track module 110, and the terminal P ) And a terminal module 170 coupled to the track module 110 to electrically connect the external power source and the track module 110 to each other. The terminal P for the power demand device may be various, such as USB, camera, and wireless charger, in addition to a general electric plug, as shown in the drawing. In response to this, the power output module 130 also includes a device capable of connecting various power demand devices such as USB, camera, and wireless charger in addition to the general electric plug.

The track module 110 includes a bar-shaped track unit 111 extending in a straight line, and two finishing bodies 120a and 120b respectively coupled to both ends of the track unit 111 in the longitudinal direction.

In FIG. 3, the track unit 111 is shown as a perspective view, and in FIG. 4, a cross-sectional view of A-A in FIG. 1 is shown. Referring to FIGS. 3 and 4, the track unit 111 is a rod shape that extends in a straight line, and two finishes 120a and 120b are coupled to both ends of the track unit 111 in the longitudinal direction. The track unit 111 includes a track body 112, a plurality of electrode wires 113a, 113b, 113c installed on the track body 112, and a plurality of insulating members 114a, 114b installed on the track body 112. ).

The track body 112 is elongated in a straight line, and may be made of a metal material by a metal processing method such as extrusion. On one surface of the track body 112, a main coupling groove 115 and two auxiliary coupling grooves 118 positioned on both sides with the main coupling groove 115 interposed therebetween are formed.

The main coupling groove 115 is a trench groove extending along the longitudinal direction of the track body 112 on one surface of the track body 112, and a plurality of electrode wires 113a and 113b are provided on both sides of the main coupling groove 115. , 113c) and a plurality of insulating members 114a and 114b are formed with a first receiving groove 115a and a second receiving groove 115b, respectively. The first receiving groove 115a and the second receiving groove 115b face each other and extend long along the longitudinal direction of the track body 112. The width of the first receiving groove 115a (the length in the depth direction of the main coupling groove 115) is larger than the width of the second receiving groove 115b (the length in the depth direction of the main coupling groove 115), and the second receiving groove The center of (115b) is located below the center of the first receiving groove (115a) (that is, closer to the bottom (115c) of the main coupling groove (115)).

Each of the two auxiliary coupling grooves 118 is formed to be positioned on both sides with the main coupling groove 115 interposed on one surface of the track body 112 in which the main coupling groove 115 is formed. The auxiliary coupling groove 118 is a trench groove extending parallel to the main coupling groove 115 along the length direction of the track body 112 on one surface of the track body 112, and the inner surface of the auxiliary coupling groove 118 A locking groove 119 is formed. The locking groove 119 is a trench groove extending in a straight line along the longitudinal direction of the track body 112.

The plurality of electrode wires 113a, 113b, and 113c are fixed to the track body 112 while being wrapped by a plurality of insulating members 114a and 114b. The plurality of electrode lines 113a, 113b, and 113c include a first power electrode line 113a, a ground electrode line 113b, and a second power electrode line 113c.

The first power electrode line 113a is positioned in the first receiving groove 115a of the track body 112 while being wrapped in the insulating member 114a, and extends long along the longitudinal direction of the track body 112. The first power electrode line 113a is made of a conductor such as a copper alloy, and is electrically connected to one of the anodes of the external power source through the terminal module 170, and in this embodiment, it will be described as being connected to the + electrode. One end of the first power electrode line 113a passes through one of the two finishes 120a and 120b and protrudes to the outside for connection with the terminal module 170.

The ground electrode wire 113b is located in the first receiving groove 115a of the track body 112 while being wrapped in the insulating member 114a, and extends long along the length direction of the track body 112. The ground electrode line 113b is positioned closer to the bottom 115c of the main coupling groove 115 than the first power electrode line 113a in the first receiving groove 115a. That is, in the first receiving groove 115a, the first power electrode line 113a and the ground electrode line 113b are spaced apart along the depth direction of the main coupling groove 115, and the ground electrode line 113b is the first power electrode line. It is located closer to the bottom (115c) side of the main coupling groove (115) than (113a). The ground electrode line 113b is made of a conductor such as a copper alloy, and is electrically connected to a ground electrode of an external power source through the terminal module 170. One end of the ground electrode line 113c passes through one of the two finishes 120a and 120b and protrudes to the outside for connection with the terminal module 170.

The second power electrode line 113c is located in the second receiving groove 115b of the track body 112 while being wrapped in the insulating member 114b, and extends long along the longitudinal direction of the track body 112. Accordingly, the second power electrode line 113c is located opposite to the first power electrode line 113a with the main coupling groove 115 therebetween, and is located at the bottom of the main coupling groove 115 than the first power electrode line 113a. They are located closer together. The second power electrode line 113c is made of a conductor such as a copper alloy, and is electrically connected to one of the anodes of the external power source through the terminal module 170. In this embodiment, it will be described as being connected to the-electrode. One end of the second power electrode line 113c passes through one of the two finishes 120a and 120b and protrudes to the outside for connection with the terminal module 170.

The plurality of insulating members 114a and 114b surround the plurality of electrode lines 113a, 113b and 113c and are coupled to the track body 112. Between the plurality of electrode wires 113a, 113b, and 113c and the track body 112 are insulated by the plurality of insulating members 114a and 114b.

The plurality of insulating members 114a and 114b are accommodated in a first insulating member 114a accommodated in a first receiving groove 115a of the track body 112 and a second receiving groove 115b of the track body 112 It is provided with a second insulating member (114b).

The first insulating member 114a surrounds the first power electrode line 113a and the ground electrode line 113b and is fitted and received in the first receiving groove 115a of the track body 112. The first insulating member 114a includes an opening 1141a for accessing the first power electrode line and a first receiving groove 115a to allow access to the first power electrode line 113a through the first receiving groove 115a. An opening 1142a for accessing the ground electrode line is formed through which the ground electrode line 113b can be accessed. The first power electrode line access opening 1141a and the ground electrode line access opening 1142a have a slit shape and are elongated along the length direction of the track body 112.

The second insulating member 114b surrounds the second power electrode line 113c and is fitted and received in the second receiving groove 115b of the track body 112. An opening 1141b for accessing a second power electrode line is formed in the second insulating member 114b to allow access to the second power electrode line 113c through the second receiving groove 115b. The second power source electrode line access opening 1141b has a slit shape and extends long along the longitudinal direction of the track body 112.

1 and 2, the two finishes 120a and 120b are provided with a first finish 120a and a second finish 120b respectively coupled to both ends of the track unit 111 in the longitudinal direction. The two finishes 120a and 130b are made of a cutting material, and are respectively screwed to both ends of the track body 112 in the longitudinal direction.

From the track unit 111, the first power electrode line 113a, the ground electrode line 113b, and the second power electrode line 113c can pass through the first finish 120a of the two finishes 120a and 120b, respectively. Passage holes are formed, and through the passage holes, the first power electrode line 113a, the ground electrode line 113b, and the second power electrode line 113c protrude to be exposed to the outside. The first closing body 120a is fixed by being combined with the terminal module 170. The end of the first power electrode line 113a exposed to the outside, the end of the second power electrode line 113c exposed to the outside, and the end of the ground electrode line 113b exposed to the outside are two external power electrodes in the terminal module 170. And each of the external ground electrodes is electrically connected to each other.

The power output module 130 is detachably coupled to an appropriate position in the longitudinal direction of the track unit 111 of the track module 110. In FIG. 5, the power output module 130 is shown as a perspective view, in FIG. 6, the power output module 130 is shown as a side view, and in FIG. 7, the power output module 130 is shown as a bottom view. 1, 2, and 4 to 7, the power output module 130 includes a fixed body 140 and a rotating body that axially rotates about a rotation axis X with respect to the fixed body 140 ( 150).

The fixture 140 has a generally cylindrical shape, and the rotation axis X passes through the center thereof, and the rotation body 150 axially rotates with respect to the fixture 140 around the rotation axis X. 140). The fixture 140 includes two insertion legs 141 positioned opposite the circumferential direction with the rotation axis X interposed therebetween. The two insertion legs 141 may be inserted one by one into the two auxiliary coupling grooves 118 formed in the track body 112. The inner ends of the two insertion legs 141 are inclined to become narrower toward the ends, and this is a structure for allowing the two insertion legs 141 to be easily inserted into each of the two auxiliary coupling grooves 118. In addition, the fixture 140 further includes a plurality of ball members 145 that can be fitted into each of the two locking grooves 119 formed in the track body 112. The plurality of ball members 145 are elastically supported to facilitate fastening and separation with the locking groove 119, and improves the coupling force of the power output module 130 to the track body 112.

The rotating body 150 is coupled to the fixed body 140 to enable reciprocating shaft rotation within a range of 90 degrees around the rotation axis X. The rotating body 150 includes a connection part 151 to which a terminal P for a power receiving device is coupled, a coupling column part 160 protruding along the rotation axis X, and a plurality of electrical connections to the connection part 151. It includes three electrode line connection terminals 155a, 155b, and 155c.

The connection part 151 is located on the opposite side of the two insertion legs 141 provided in the fixture 140, and a general structure in which the terminal P of a general power demand device such as an electric plug or USB can be electrically connected Consists of Although not shown in detail, when the connection part 151 has a structure in which an electric plug is connected, two socket power terminals connected to two power plug pins of the plug and a socket ground terminal connected to the ground terminal of the plug are provided. Each of the two power terminals and the ground terminals provided in the connection part 151 is electrically connected to each of the plurality of electrode line connection terminals 155a, 155b, and 155c.

The coupling pillar 160 is formed to protrude in the shape of a pillar along the rotation axis X on the opposite side of the connection portion 151 and is positioned between the two insertion legs 141. The coupling pillar 160 is a rectangular pillar shape centered on the axis of rotation (X), and the four corner portions are rounded. Accordingly, the coupling pillar portion 160 is formed with different lengths of the two sides. The coupling pillar 160 is inserted into the main coupling groove 115 of the track body 112, and when the relatively short side faces both sides of the main coupling groove 115, it is tightly fitted to improve the coupling force and thus the outlet module ( When the slide movement of the track module 110 of 130) is suppressed, and the relatively long side faces both sides of the main coupling groove 115, the outlet module 130 is easily moved with respect to the track module 110. You will be able to move. That is, the coupling pillar 160 is in contact with or non-contact with both sides of the main coupling groove 115 according to the rotational position of the rotating body 150, so that a relatively long length in the long axis direction D1 and a length in the long axis direction D1 ) Has a cross-sectional shape having a shorter axial length (D2) than). The major axis direction and the minor axis direction will be described as forming a right angle. Accordingly, the cross-sectional shape of the coupling column unit 160 may be various shapes such as an ellipse as well as a rectangular shape, which is also within the scope of the present invention. The plurality of electrode line connection terminals 155a, 155b, and 155c are formed to protrude outward from both ends of the coupling pillar 160 in the long axis direction. A plurality of terminal connection passages 162a, 162b, and 162c through which a plurality of electrode line connection terminals 155a, 155b, and 155c pass are formed in the coupling pillar unit 160. The plurality of terminal connection passages 162a, 162b, and 162c will be described together while describing the plurality of electrode line connection terminals 155a, 155b, and 155c.

The plurality of electrode line connection terminals 155a, 155b, and 155c are electrically connected to the connection part 151, and the plurality of electrode wires 113a, 133b, 113c of the track module 110 and the plurality of electrode wires 113a, 133b, and 113c are electrically connected to the connection part 151 and according to the rotational position of the coupling column part 160. The electrical connection of is switched. The plurality of electrode line connection terminals 155a, 155b, and 155c include a first power connection terminal 155a, a ground connection terminal 155b, and a second power connection terminal 155c. When the plurality of electrode line connection terminals 155a, 155b, 155c are separated from the plurality of electrode lines 113a, 133b, 113c, the power output module 130 can slide along the length direction on the track unit 110. do.

The first power connection terminal 155a is formed by passing through the interior of the coupling pillar 160 from the connection portion 151 and protruding to the side of the coupling pillar 160. The first power connection terminal 155a extends radially outward from the end of the vertical extension portion 1551a extending from the connection portion 151 along the extension direction of the coupling column portion 160 and the vertical extension portion 1551a. It is provided with a horizontal extension portion (1552a). Since the horizontal extension part 1552a is exposed to the outside, an end of the horizontal extension part 1552a may contact the first power electrode line 113a of the track module 110. The coupling pillar 160 has a first power terminal connection passage 162a through which the first power connection terminal 155a passes, and the horizontal extension part 1552a extends vertically so that it can move radially inward by an external force. Allows the elastic deformation of the portion (1551a). To this end, a spare space 1621a is formed radially inward in a portion corresponding to the end of the vertical extension portion 1551a of the first power connection terminal 155a in the first power terminal connection passage 162a. The electrical and mechanical connection state between the first power connection terminal 155a and the first power electrode line 113a is improved by elastic deformation of the first power connection terminal 155a. The horizontal extension part 1552a protrudes from the short side of the coupling column part 160.

The ground connection terminal 155b is formed by passing through the interior of the coupling pillar 160 from the connection portion 151 and protruding in the same direction as the first power connection terminal 155a toward the side of the coupling pillar 160. The ground connection terminal 155b includes a vertical extension part 1551b extending from the connection part 151 along the extending direction of the coupling column part 160, and a horizontal extending radially outward from the end of the vertical extension part 1551b. It has an extension part 1552b. The horizontal extension part 1552b is located closer to the end of the coupling column part 160 than the horizontal extension part 1552a of the first power connection terminal 155a. Since the horizontal extension part 1552b is exposed to the outside, an end of the horizontal extension part 1552b may contact the ground electrode line 113b of the track module 110. The coupling pillar 160 has a ground terminal connection passage 162a through which the ground connection terminal 155b passes, and a vertical extension portion 1551b so that the horizontal extension portion 1552b can move radially inward by an external force. Allows the elastic deformation of. To this end, a spare space 1621b is formed radially inward in a portion of the ground terminal connection passage 162b corresponding to the end of the vertical extension portion 1551b of the ground connection terminal 155b. The electrical and mechanical connection state between the ground connection terminal 155b and the ground electrode line 113b is improved by elastic deformation of the ground connection terminal 155b.

The second power connection terminal 155c is formed by passing through the interior of the coupling pillar 160 from the connection portion 151 and protruding to the side of the coupling pillar 160. The second power connection terminal 155c extends radially outward from the end of the vertical extension portion 1551c and the vertical extension portion 1551c extending from the connection portion 151 along the extension direction of the coupling column portion 160 And a horizontal extension portion 1552c positioned on the opposite side of the horizontal extension portion 1552a of the first power connection terminal 155a with the coupling pillar portion 160 therebetween. The horizontal extension part 1552c is located closer to the end of the coupling column part 160 than the horizontal extension part 1552a of the first power connection terminal 155a, so that a position difference occurs in the extending direction of the coupling column part 160 do. This is to improve electrical safety. The horizontal extension part 1552c is exposed to the outside so that an end of the horizontal extension part 1552c may contact the second power electrode line 113c of the track module 110. The coupling pillar 160 has a second power terminal connection passage 162c through which the second power connection terminal 155c passes, and the horizontal extension part 1552c extends vertically so that it can move radially inward by an external force. The elastic deformation of the part 1551c is allowed. To this end, a spare space 1621c is formed radially inward in a portion corresponding to the end of the vertical extension portion 1551c of the second power connection terminal 155c in the second power terminal connection passage 162c. The electrical and mechanical connection state between the second power connection terminal 155c and the second power electrode line 113c is improved by elastic deformation of the second power connection terminal 155c.

Each of the first power connection terminal 155a, the ground connection terminal 155b, and the second power connection terminal 155c by rotation of the coupling pillar 160 is connected to the first power electrode line 113a and the second power electrode line 113b. ) And the third power electrode line 113c, and each of the electrode lines 113a, 113b, and 113c may be damaged by the respective electrode line connection terminals 155a, 155b, and 155c. To prevent this, the end edges of the horizontal extension portions 1552a, 1552b, 1552c of each electric wire connection terminal 155a, 155b, 155c are rounded, and the horizontal extension portion 1552b of the ground connection terminal 155b The round portion R2 formed in the round portion (not shown) formed in the horizontal extension portion 1552a of the first power connection terminal 155a and the horizontal extension portion 1552c of the second power connection terminal 155c. It has a radius of curvature smaller than that of the round portion D3. This is to improve electrical safety by increasing the contact area of the ground connection terminal 155b. Since the end of the coupling pillar 160 is located inside the end of the two insertion legs 141, the power output module 130 may be erected by the two insertion legs 141. To this end, the ends of the two insertion legs 141 are formed with a flat surface.

The electrical distribution device 100 further includes an erroneous coupling prevention structure for preventing erroneous coupling between the track module 110 and the power output module 130. 3 to 6, the erroneous coupling preventing structure is formed in one of the stepped jaws 119a formed upward on one side of the two auxiliary coupling grooves 119 and the two insertion legs 141 It is provided with a locking jaw (141a) that is caught on the stepped (119a). Among the two insertion legs 141, the insertion leg 141 on which the locking jaw 141a is formed has a relatively larger thickness than the other insertion leg 141 so that it is not inserted into the other auxiliary coupling groove 119, and the locking jaw It is fitted only to the auxiliary locking groove 119 in which (141a) is formed.

In the drawing of this embodiment, the track module 110 is illustrated and described as being used in combination with one power output module 130, but the track module 110 may be formed to be extended longer than that shown in the drawing. , A plurality of power output modules 130 may be detachably coupled to the track module 110 and used.

1 and 2, the terminal module 170 is coupled to the track module 110 to electrically connect the external power source and the track module 110. The terminal module 170 includes a first power electrode line 113a, a ground electrode line 113b, and a second power electrode line 113c protruding from the two end bodies 120a and 120b of the track module 110 to be exposed to the outside. 1 It is coupled to the closing body (120a), in this embodiment will be described as being coupled by a fastening means such as bolts.

8 is an exploded perspective view of the terminal module 170 shown in FIG. 1, showing a part of the track module 110 to be connected, and FIG. 9 is an external wire connected from the inside of the terminal module shown in FIG. Is a perspective view showing so as to be seen. 8 and 9, the terminal module 170 couples the first power electrode wire 113a protruding from the track module 110 and connects the first external power wire w1 to the first electrode wire coupling structure ( 180a), a second electrode wire coupling structure 180b that couples the ground electrode wire 113b protruding from the track module 110 and is connected to the external ground wire w2, and a second power supply protruding from the track module 110 A third electrode wire coupling structure 180c is provided to couple the electrode wires 113c and connect to the second external power wire w3. Since the three electrode wire coupling structures 180a, 180b, and 180c are all formed in the same configuration, only the configuration of the third electrode wire coupling structure 180c will be described in detail here.

10 is a cross-sectional view of a third electrode line coupling structure 180c. 8 to 10, the third electrode line coupling structure 180c includes a support 181, an electrode line connecting member 182 fixed to the support 181 and electrically connected to the second power electrode line 113c. , To the fixing bolt 186 for improving the electrical connection between the second power electrode line 113c and the electrode line connection member 182 while fixing the electrode line connection member 182 to the support 181, and the electrode line connection member 182 A terminal member 187 that is coupled and to which the external electric wire w3 is connected, and a coupling bolt 188 for coupling the terminal member 187 to the electrode line connection member 182c are provided.

The support 181 is a structure integrally formed with the case 171 of the terminal module 170, and the electrode wire connection member 182 is fixed to the support 181 by a fixing bolt 186. A bolt hole 181b through which the fixing bolt 186 passes is formed in the support 181. A flat support surface 181a is formed in the support 181. In addition, a passage hole 171 through which the second power electrode line 113c passes is formed in the case 171 of the terminal module 170 adjacent to the support 181. In order to improve the coupling force between the track module 110 and the terminal module 170, the first closing body 120a is fitted with a passage hole 171 and a through hole through which the second power electrode line 113c passes is formed. The protrusion 121a is formed.

The electrode line connecting member 182 is fixed to the support 181 and coupled to the electrode line connecting member 182 so that the second power electrode line 113c and the terminal member 187 are electrically connected. The electrode line connecting member 182 has a generally square bar shape, and an electrode line insertion hole 183 penetrating the center along the length direction is formed therein. The second power electrode line 113c is inserted and connected to the electrode line insertion hole 183. A fixing bolt hole 184a and a terminal coupling bolt hole 184b are formed on a flat side surface of the electrode line connection member 182 to be spaced apart along the longitudinal direction of the electrode line connection member 182. The fixing bolt hole 184a and the terminal coupling bolt hole 184b are connected to the electrode line insertion hole 183.

The fixing bolt 186 improves the electrical connection between the second power electrode line 113c and the electrode line connection member 182 while fixing the electrode line connection member 182 to the support 181. The fixing bolt 186 is coupled through a bolt hole 181b of the support 181 and a fixing bolt hole 184a of the electrode wire connection member 182 to firmly fix the electrode wire connection member 182 to the support 181 . The end of the pillar portion 186a of the fixing bolt 186 protrudes into the electrode line insertion hole 183 of the electrode line connection member 182 and presses the second power electrode line 113c, thereby forming the second power electrode line 113c and the electrode line. The electrical connection state of the connection member 182 is improved.

The terminal member 187 is coupled to the electrode line connecting member 182 by a coupling bolt 188. A bolt hole 187a for the coupling bolt 188 is formed in the terminal member 187. An external electric wire w corresponding to the second power electrode line 113c is connected to the terminal member 87. In the case of the second electrode line coupling structure 180b coupled to the ground electrode line 113b of the track module 110, a ground external wire is connected. The terminal member 187 is a plate-shaped member and is electrically connected by making surface contact with a flat side surface of the electrode line connecting member 182.

The coupling bolt 188 couples the terminal member 187 to the electrode line connection member 182c. The coupling bolt 188 is coupled to the coupling bolt hole 184b formed in the electrode line connection member 182c. Although not shown, the pillar portion 188a of the coupling bolt 188 may also be formed to protrude into the electrode line insertion hole 183 of the electrode line connection member 182 to press the second power electrode line 113c.

Now, the assembly method of the electric distribution device 100 will be described as follows.

First, a finishing body coupling step in which the first finish body 120a is coupled to the track unit 111, a terminal module coupling step in which the terminal module 170 is coupled to the first finish body 120a, and a fixing bolt 186 ) To fix the electrode wires 113a, 113b, and 113c to each of the corresponding electrode wire connecting members 182.

In the finish coupling step, the first finish (120a in Fig. 2) is coupled to and fixed to the one-way end of the track unit (111 in Fig. 2). In this case, as shown in FIG. 2, ends of the plurality of electrode lines 113a, 113b, and 113c of the track unit 111 protrude out of the first finish body 120a and are exposed. After the first finish 120a is coupled to the track unit 111 through the finish coupling step, the terminal module coupling step is performed.

In the terminal module coupling step, the terminal module 170 is coupled to the first closing body 120a. The first closing body 120a and the terminal module 170 are coupled through a fastening means such as a coupling bolt. At this time, the insertion protrusion 121a formed in the first closing body 120a is fitted to fit the passage hole formed in the case 171 of the terminal module 170. In addition, in the terminal module coupling step, the electrode lines 113a, 113, and 113c are inserted into the electrode line insertion holes 183 formed in the corresponding electrode line connection members 182. After the terminal module 170 is coupled to the first finished body 120a through the terminal module coupling step, the electrode wire fixing step is performed.

In the electrode wire fixing step, the electrode wires 113a, 113b, and 113c are fixed by the fixing bolt 186 while being inserted into the electrode wire insertion hole 183 formed in the corresponding electrode wire connecting member 182.

Although the present invention has been described through the above embodiments, the present invention is not limited thereto. The above embodiments may be modified or changed without departing from the spirit and scope of the present invention, and those skilled in the art will recognize that such modifications and changes also belong to the present invention.

100: electrical distribution device 110: track module
111: track unit 112: track body
113a: first power electrode line 113b: ground electrode line
113c: second power electrode line 114a: first insulating member
114b: second insulating member 115: main coupling groove
115a: first receiving groove 115b: second receiving groove
118: auxiliary coupling groove 119: locking groove
120a: first finished body 120b: second finished body
130: outlet module 140: fixture
141: insertion leg 145: ball member
150: rotating body 151: connection
155a: first outlet power connection terminal 155b: outlet ground connection terminal
155c: second outlet power connection terminal 160: coupling pillar portion
170: terminal module 180a: first electrode wire coupling structure
180b: second electrode wire coupling structure 180c: third electrode wire coupling structure
181: support 182: electrode wire connecting member
186: fixing bolt 187: terminal member
188: coupling bolt

Claims (11)

A track module having a track body extending long along one direction, a plurality of electrode wires extending along the longitudinal direction of the track body and installed inside the track body, and a terminal for a power demand device are connected to the track module. The plurality of electrode lines and the external power supply in an electrical distribution device including a power output module that is detachably coupled and electrically connected to the plurality of electrode lines, and a terminal module electrically connecting the track module and an external power source As a structure that combines the wires of,
An electrically non-conductive support formed on the terminal module;
An electrode line connecting member made of an electrically conductive material coupled to the support and connected by inserting the electrode line protruding from the track module;
A fixing bolt fixing the electrode wire connecting member to the support;
A terminal member made of an electrically conductive material connected to the electric wire of the external power source and coupled to the electrode line connection member; And
And a coupling bolt for coupling the electrode line connection member and the terminal member,
The electrode line connection member includes an electrode line insertion hole into which the electrode wire is inserted, a fixing bolt hole in which the fixing bolt is coupled and communicates with the electrode line insertion hole, and a terminal coupling through which the coupling bolt is coupled and communicates with the electrode line insertion hole. Bolt holes are formed,
The fixing bolt hole and the terminal coupling bolt hole are disposed to be spaced apart from the electrode line connecting member along the length direction of the electrode line insertion hole,
An electrode wire coupling structure of an electrical distribution device in which the electrode wire inserted into the electrode wire insertion hole is pressed by the fixing bolt and the coupling bolt to prevent separation from the electrode wire insertion hole. The method according to claim 1,
An electrode line coupling structure of an electrical distribution device in which an extension direction of the electrode line insertion hole and an extension direction of the fixing bolt hole form a right angle. The method according to claim 1,
The electrode line connection member has a hollow rectangular rod shape extending along an extension direction of the electrode line insertion hole. delete delete delete The method according to claim 1,
An electrode line coupling structure of an electrical distribution device in which an extension direction of the electrode line insertion hole and an extension direction of the terminal coupling bolt hole form a right angle. The method according to claim 1,
The plurality of electrode lines are an electrode line coupling structure of an electric bonsai device including two power electrode lines and a ground electrode line. delete delete delete

Images