KR20080090901A - Joint kit having a foldable insulating shaft for bus duct - Google Patents

Abstract

A joint kit having a foldable insulating shaft for a bus duct is provided to facilitate assembly of both ends of the insulating shaft by forming suspension protrusions and suspension projections at the both ends of the insulating shaft. A joint kit connects bus ducts by being coupled to a connection unit bus bar at lateral ends of duct units. The joint kit includes a joint housing(31), an insulating plate(33), a conductor(35), an insulating shaft, and a high tension bolt(36). The joint housing includes a through hole(42). The insulating plate includes a through hole(41). The insulating shaft is inserted and installed into the through holes. The high tension bolt is inserted and installed into the insulating shaft. The insulating shaft is formed to be foldable.

Description

Joint Kit Having A Foldable Insulating Shaft For Bus Duct}

1 is a perspective view of a booth duct having a conventional conical connection part.

FIG. 2 is a perspective view showing a state in which the booth duct shown in FIG. 1 is connected by a joint kit. FIG.

3 is an exploded perspective view of the joint kit shown in FIG. 2.

It is a perspective view which shows the connection state of the booth duct provided with the joint kit which concerns on this invention.

5 is an exploded perspective view of the joint kit shown in FIG. 4.

6 is an assembled perspective view of the joint kit shown in FIG. 5.

7 is an exploded perspective view of the insulating shaft shown in FIG. 5.

8 is a cross-sectional view of the insulating shaft shown in FIG. 7.

Explanation of symbols on the main parts of the drawings

1: booth duct 2, 3: upper and lower duct

5: side duct 10: duct part

11 busbar 20 connection

30: joint kit 31: joint housing

33: insulation plate 35: conductor

36: high tension bolt 38: nut

39: insulation ring 41, 42: through hole

45: insulated shaft 47: locking jaw

491, 492: engaging projections 511, 512: auxiliary projections

The present invention relates to a joint kit for a bus duct, and more particularly, to a length of a high-strength bolt inserted through the center of the insulating plate and the conductor to couple the insulating plate and the conductor of the joint kit coupled to the busbars of two adjacent connections in a laminated state. In accordance with the present invention relates to a joint kit for a booth duct that is capable of varying the length of the insulated shaft inserted outside the high tension bolt.

In the past, the wiring method using wire cable has been widely adopted as the power wiring method. However, in recent years, as the power demand of buildings such as high-rise buildings, apartments, and large factories has increased rapidly, the adoption of the wiring method by booth ducts using busbars has been spreading. It is becoming. Booth ducts and cables have in common that they have conductors and insulators, but compared to cables, booth ducts can carry large amounts of current through the conductors, and as metal ducts to protect conductors and insulators, Extension and relocation are possible, and when an accident occurs, it is easy to deal with the accident, and the system can be easily managed.

As an example of such a booth duct, the booth duct 101 shown in FIG. 1 is mentioned. The booth duct 101 is a booth duct provided with the same type of connection part having the same shape of the connection part 120 formed at both ends of the duct part 110. As shown, the duct part 110 and both ends of the duct part 110 are shown. Consists of the same type of connection portion 120 formed in. Here, the duct unit 110 is composed of a side duct 105 connecting the upper duct 102 and the lower duct 103 and the upper and lower ducts 102 and 103, and the side duct 105 is predetermined along the center line. While the plurality of reinforcing screw portions 109 are fastened at intervals, the connecting portion 120 includes a plurality of bus bars 111 exposed to the outside from the duct portion 110.

In addition, in the joint kit 130 mounted between two adjacent duct parts 110, as shown in FIG. 2, the busbars 111 are inserted to the left and right between the two duct parts 110 arranged in a straight line, thereby allowing the duct part to be mounted. The busbars 111 of 110 are physically and electrically connected to each other.

To this end, as shown in FIG. 3, the joint kit 130 may include a plurality of insulating plates 133 and a plate-shaped conductor 136 to insert the busbars 111 between the front and rear joint housings 131. They are stacked at regular intervals, and the high tension bolt 135 penetrates and is inserted in the center of the outer surface of the joint housing 131 with a disk spring 134 such as a washer interposed therebetween, thereby providing a plurality of insulating plates 133 and conductors ( 136) is intended to be tightened under pressure.

At this time, the plurality of insulating plates 133 and the conductor 136 is to be coupled as one module by fastening the nut 138 from the opposite side through the one bolt 135 in the center in a stacked state. However, there is a problem in that the assembling work becomes inconvenient because the insulating plate 133 and the conductor 136 stacked at the time of assembly are moved without being fixed.

Thus, in the conventional joint kit 130, as shown in FIG. 3, the insulating shaft 145 is previously inserted into the through hole 141 of the insulating plate 133 and the conductor 136 to surround the high tension bolt 135. By preventing the movement of the insulating plate 133 and the conductor 136 and guiding the progress of the bolt 135 to facilitate the assembly work by the bolt 135.

However, as shown in FIG. 3, the length of the conventional insulating shaft 145 is determined according to the number of the insulating plates 133 and the conductors 136 to be stacked, and thus, the insulating plates 133 and the conductors 136 may be formed. If the number is increased or decreased, the length cannot be changed according to the increased or decreased thickness. Therefore, a new insulation shaft having a suitable length must be manufactured. As a result, this increases the manufacturing process and the production cost, thereby inhibiting the productivity of the joint kit. There was a problem.

The present invention has been proposed to solve the problems of the conventional joint kit for booth duct as described above, the insulation plate is inserted into the through-hole formed in the center of the insulation plate and the conductor to guide the high-strength bolt to tie them together insulated plate length And it is intended to improve the productivity of the joint kit by making a folding type so that the number of conductors, etc., that is, depending on the laminated thickness can be changed.

In order to achieve the above object, the present invention is a joint kit for a booth duct coupled to a connection busbar of mutually opposite side ends of a duct part between adjacent booth ducts to connect a booth duct, a joint housing having a through hole, and a through hole formed therein. And an insulating plate and a conductor, an insulating shaft inserted into the through hole, and a high tension bolt inserted into the insulating shaft. The insulating shaft inserted into the through hole is foldable.

In the above, the insulating shaft is characterized by consisting of a female hollow shaft portion, and a male hollow shaft portion capable of sliding in the axial direction into the female hollow shaft portion.

In the above, the insulating shaft is characterized in that it comprises a locking projection protruding in the upper and lower corners of the male and female hollow shaft portion, and the locking projection is spaced apart from the locking projection up and down respectively.

Each of the locking projections is arranged at an angular interval of 180 ° on the outer circumferential surface of the male and female hollow shaft parts, and a plurality of auxiliary protrusions are formed to protrude between the locking projections.

And in the above, the female hollow shaft portion is formed in the axial direction with the guide slot on one side wall, the male hollow shaft portion is formed in the axial direction so that the sliding projection moves along the guide slot on the corresponding one outer peripheral surface. It is done.

Hereinafter, with reference to the accompanying drawings an embodiment of a joint kit for a booth duct having an insulating shaft that can be adjusted in length according to the present invention.

Joint kit 30 of the present invention, as shown in Figure 4, the upper and lower duct (2, 3) and the side duct (5) surrounding the bus bar (11) inside, and In order to connect the busbars 11 of the adjacent booth duct 1 which consists of the connection part 20 formed in the both ends of the duct part 10, it is physically and electrically connected with both connection parts 20. As shown in FIG.

Here, the joint kit 30 again includes a joint housing 31, an insulation plate 33, a conductor 35, a high tension bolt 36, a folding insulation shaft 45, and the like, as shown in FIG. 5. First, the joint housing 31 is a plate member serving as a clamp as shown in FIG. 6, and is closely attached to the outer surfaces of the plurality of stacked insulating plates 33 and the conductor 35 to bind them together and protect them from both sides. It is supposed to. In the joint housing 31, a through hole 42 through which the high tension bolt 36 inserted into the insulating shaft 45 and the insulating shaft 45 passes is formed at the center thereof. There is a pair of sliding grooves 57 facing each other to sandwich the anti-rotation plate 61 is formed vertically long.

On the other hand, a plurality of insulating plates 33 are stacked between the joint housing 31 by a plurality of intervals by the insulating ring 39 to sandwich the plurality of busbars 11, and inserted between the busbars 11 Keep it insulated. At this time, the insulating ring 39 maintains a constant gap between the insulating plate 33 and the conductor 35 to be laminated, and prevents the insulating plate 33 and the conductor 35 from moving arbitrarily. In addition, the conductor 35 is a plate-shaped component having a width smaller than that of the insulating plate 33, as shown in the figure. The through-hole 41 through which the insulating shaft 45 passes is formed in the center, and a pair of stoppers 40 protrude at the point slightly shifted to the left and right of the through-hole 41 at the center. have. In addition, the high-strength bolt 36 is a fastening means for tying the plurality of insulating plates 33 and the conductors 35 stacked between the joint housings 31 as one, and preferably can withstand high tensile force, such as a double head joint bolt. The joint housing 31, the insulation plate 33, the conductor 35, and the joint housing 31 with the disc spring 34 acting as a washer between the joint housing 31 being used. It penetrates in turn and is fixed by the nut 38 on the opposite side, and the insulating plate 33, the conductor 35, the insulating ring 39, etc., which are laminated inside the joint housing 31, are strongly pressed to bind together.

Finally, the joint kit 30 of the present invention is inserted into the through hole 42 of the insulating plate 33 and the conductor 35 so that the insulating shaft 45 surrounding the high tension bolt 36 can be folded in the axial direction. To this end, the insulating shaft 45 is composed of a female hollow shaft portion 451 and a male hollow shaft portion 452 coupled to be movable relative to the axial direction as shown in FIG. The male and female hollow shaft portions 451 and 452 are rectangular cylinders, respectively, and locking jaws 471 and 472 protrude from the upper and lower edges thereof, and the female hollow shaft portion 451 in the lower portion has an upper surface open. The male hollow shaft portion 452 has an extended shaft diameter portion 46, which is slidably inserted into the opening of the female shaft portion 451 on the lower surface thereof.

In the above, the male and female hollow shaft parts 451 and 452 are not necessarily formed as rectangular cylinders, but may be formed in a polygonal shape, and the through-holes 41 and 42 may also be similar to the female and female hollow shaft parts 451 and 452. It is possible to form a polygon.

In addition, the male and female hollow shaft portions 451 and 452 are provided in a pair of opposite sidewalls of the female hollow shaft portion 451 to guide the male hollow shaft portion 452 to be inserted into the female hollow shaft portion 451 smoothly. The guide slot 53 is formed long in the axial direction, and the sliding protrusion 55 extends in the axial direction on the outer circumferential surface of the male hollow shaft portion 452 corresponding to the guide slot 53. Therefore, when the male and female hollow shaft portions 451 and 452 are coupled, the sliding protrusion 55 of the male hollow shaft portion 452 slides along the guide slot 53 of the female hollow shaft portion 451 to allow the female hollow shaft portion 451. The male hollow shaft portion 452 is smoothly inserted into the guide.

As such, the insulating shaft 45 can adjust the length by moving the male and female hollow shaft portions 451 and 452 in the axial direction, and has a length determining means on its own to keep the increased and decreased length constant. It goes without saying that various means can be employed as the determining means 471, 472, 491, 492, and preferably, the protrusions 491, 492 as shown in FIGS. 7 and 8 can be employed. The locking projections 491 and 492 protrude from the upper and lower wall surfaces of the male and female hollow shaft portions 451 and 452 at 180 ° intervals so as to face each other. At this time, the locking projections 491 and 492 are spaced apart from each other by the thickness of the joint housing 31 up and down from the locking projections 471 and 472 protruding from the corner portions, respectively, and the joint housing 31 together with the locking projections 471 and 472. The length of the insulating shaft 45 is perfectly matched with the stacking thickness of the insulating plate 33 and the conductor 35 because the length of the insulating shaft 45 is variable up and down along the joint housing 31. Keep it to length.

At the same time, a plurality of auxiliary protrusions 511 and 512 protrude from the outer wall and the outer wall adjacent to the outer circumferential surfaces of the female and female hollow shaft portions 451 and 452 from which the locking protrusions 491 and 492 protrude so as to be engaged with the locking protrusions 491 and 492. The inner wall of the through hole 42 of the joint housing 31 is fitted between the jaws 471 and 472.

Now, the operation of the joint kit for the booth duct that can adjust the length of the insulating shaft according to an embodiment of the present invention configured as described above.

The joint kit 30 for the booth duct according to the present invention, in assembling the joint kit 30 as shown in FIG. 5, the joint housing 31, the insulating plate 33, the conductor 35, and the insulating ring 39. ) Are sequentially stacked as shown, inserting the insulating shaft 45 through the through holes 41 and 42 of each member, and then passing the high tension bolt 36 into the insulating shaft 45 to allow the nut 38 on the opposite side. ) Combines the stacked members together.

To this end, the insulating shaft 45 must first be inserted into the through-holes 41 and 42 of each member, so that the female hollow shaft portion 451 of the insulating shaft 45 is inserted into the lower (or upper) joint housing 31. After inserting the male hollow shaft portion 452 at the upper side (or lower side) of the upper (or lower) joint housing 31 at the lower side (or the upper side), the sliding protrusion 55 of the male hollow shaft portion 452 is female hollow. The shaft diameter portion 46 of the male hollow shaft portion 452 is inserted into the opening of the female hollow shaft portion 451 while being matched with the slot 53 of the shaft portion 451.

Then, when the male and female hollow shaft portions 451 and 452 have fully entered the through holes 41 and 42, between the locking projections 491 and 492 and the locking projections 471 and 472 of the hollow shaft portions 451 and 452. By inserting the inner wall of the through hole 42 of the joint housing 31, the insulating shaft 45 can be inserted into the through holes 41 and 42 of the laminated members with the optimum length.

As described above, according to the joint kit for booth duct provided with the insulation shaft which can adjust the length of this invention, it is laminated by manufacturing the insulation shaft inserted into the through-hole formed in the center of an insulation plate and a conductor by folding the male and female in two stages. Regardless of the number of insulating plates or conductors, that is, the thickness of the laminate, the length of the insulating shaft can be increased or decreased to exactly match the thickness of the laminate.

In addition, by forming the locking projection and the locking jaw at both ends of the insulating shaft, it becomes possible to more easily assemble the both ends of the insulating shaft that are snap-fit to the through-hole of the joint housing.

Therefore, even if the number of insulation plates and conductors applied to the joint kit changes, there is no need to manufacture a new insulation shaft separately, and since a single folding insulation shaft can be used universally, it is possible to prevent the increase of the production process or the unit cost, thereby preventing joint kits and more. Furthermore, the productivity of the booth duct can be expected.

Claims (5)

In the joint kit 30 which is connected to the connection part busbar 11 of the side end of the duct part 10 which mutually opposes between the adjacent booth duct 1, and connects the booth duct 1, The joint kit 30 is inserted into the joint housing 31 having the through hole 42, the insulating plate 33 and the conductor 35 having the through hole 41, and inserted into the through holes 41 and 42. And an insulating shaft 45 to be inserted into the insulating shaft 45, and a high tension bolt 36 inserted into the insulating shaft 45, wherein the insulating shaft 45 inserted into the through hole is foldable. Joint kit for booth ducts (30). According to claim 1, The insulating shaft 45 has a female hollow shaft portion 451 and a male hollow shaft portion 452 which is slidable in the axial direction into the female hollow shaft portion 451. ). The method of claim 2, The insulating shaft 45 has locking jaws 471 and 472 protruding from upper and lower edge portions of the male and female hollow shaft portions 451 and 452, and locking protrusions protruding from and below the locking jaws 471 and 472, respectively. Booth duct joint kit 30 characterized by including (491, 492). The method of claim 3, wherein The locking projections 491 and 492 are arranged at angular intervals of 180 ° on the outer circumferential surfaces of the male and female hollow shaft portions 451 and 452, respectively, and a plurality of auxiliary projections 511 and 492 are disposed between the locking projections 491 and 492. Booth duct joint kit 30, characterized in that 512 protrudes between the engaging projection (471, 472). The method according to any one of claims 1 to 4, The female hollow shaft portion 451 has a guide slot 53 formed in an axial direction on one wall thereof, and the male hollow shaft portion 452 has a sliding protrusion 55 formed on one side outer circumferential surface thereof to guide the guide slot 53. Booth duct joint kit 30, characterized in that formed in the axial direction to move along.

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