KR101223090B1 - Multi cable transit for electromagnetic interference shielding end packing - Google Patents

Abstract

PURPOSE: An end packing for a multi-cable transit for shielding electromagnetic waves is provided to completely close an internal space of a multi-cable by moving a rear tension wedge back and forth by rotating a screw member. CONSTITUTION: An end packing(10) for a multi-cable transit for shielding electromagnetic comprises a front tension wedge(20), a rear tension wedge, an upper pressing wedge(40), a lower pressing wedge(50), and an elastic member(60). The front and rear tension wedges are faced each other and move back and forth due to the rotation of a screw member(12). The upper and lower pressing wedges are faced each other and positioned on upper and lower sides of the front and rear tension wedges. The upper and lower pressing wedges move to upper and lower sides by corresponding to the forward and backward movement. The upper and lower pressing wedges are not separated from the upper and lower sides of the front and rear tension wedges by the elastic member.

Description

Multi Cable Transit for electromagnetic interference shielding end packing}

The present invention relates to an end-packing for a multi-cable transit for electromagnetic shielding, and more specifically, to one screw means by forming a rear tension wedge in a number corresponding to a through hole of a front tension wedge into which a screw means is inserted. Since one rear tension wedge is configured to correspond, when the inner space of the multi-cable transit is not sealed, the screw means at the corresponding position is rotated so that the rear tension wedge flows before and after to completely seal the inner space of the multi-cable. The present invention relates to end-packing for multi-cable transit for electromagnetic shielding.

In addition, the overall size and volume of the end packing because the upper pressure wedge and the lower pressure wedge are not separated by the elastic member to efficiently maintain the assembly shape of the front tension wedge, the rear tension wedge, the upper pressure wedge, and the lower pressure wedge. Efficient assembly shape maintenance performance can be realized without changing the shape, and it is easy to insert into the frame, and there is an advantage of facilitating disassembly of the end packing during maintenance, management or rework, and the screw means is inserted and supported. By inserting the threaded sleeve into the inside of the front tension wedge and the rear tension wedge, the assembly structure is simplified, the production time and defect rate of the end packing are reduced, and the end packing is easy to be maintained, managed and transported. The present invention relates to an end packing for a multi-cable transit for electromagnetic shielding.

In general, a cable transit not only firmly supports and fixes line-shaped members such as cables, pipes, tubes, etc. installed in various buildings, workpieces, ships, electrical installations, etc. It is for sealing the penetrating part for inserting the member of the various kinds of facilities by blocking external harmful environmental elements (fire, water or moisture, gas, dust, electromagnetic waves, shock, vibration, etc.) that can be introduced through the penetrating part. Is to protect.

Such a cable transit has been proposed by the applicant of the patent application 10-2012-0089559 "multi-cable transit packing system for electromagnetic shielding", patent application 10-2012-0089693 "cable shielding system for electromagnetic shielding" Bar and cable as described above, the cable, plate and the insert block is stacked in the inner space of the frame, the end packing is installed on the top, the cable, plate and insert block is sealed by the pressing force of the end packing.

End packing for applying a pressing force to the cable, plate and the insert block is installed in the inner space of the frame in the above, as shown in Figure 1 in the Patent Registration No. 10-0353187 No. 10-0353187 "cable trans seat" According to this, two compressive wedges 510 and 520 which can be spaced and approached from each other by the screw means 550 and another two compressible wedges 530 and 540 which are spaced and accessible to each other and are in contact with the two wedges. It is configured to include).

At this time, the four wedges (510, 520, 530, 540) are connected together by the flexible strap 19 so as to be mutually movable, the wedges (510, 520, 530, 540) and the screw means 550 Is configured to be fitted to the frame, both ends of the screw means 550 is supported by a plate 560 made of a metal material, the plate 560 is the outer surface of the two compressible wedges (510, 520) It is constructed to protrude.

However, the conventional endpacking for the cable transit as described above is composed of four wedges (510, 520, 530, 540), that is, one of the two compressible wedges (510, 520) of the back compressible wedge 510 The screw means 550 is composed of a pair of fastening force is applied to the pair of screw means 550 according to the pair of the back compression wedge 510 made of a single block or any one When only one screw means 550 is tightened, the rear compressive wedge 510 is twisted and deformed.

In addition, as the four wedges 510, 520, 530, and 540 are restrained from each other by the strap 570, the insertion into the frame is increased as the size and volume of the entire endpacking are increased by the strap 570. Not only is it cumbersome, it is difficult to disassemble during maintenance, maintenance or rework, and there is also a problem in that the assembly shape maintenance performance between the wedges is insufficient compared to the size and volume of the strap 570.

In addition, as the metal plate 560 supporting both ends of the screw means 550 is assembled separately from the outer surfaces of the two compressible wedges 510 and 520, the assembly structure becomes complicated, and production of end packing is performed. In addition to the increase in time and defective rate, there was a problem that the handling, such as maintenance, management and transportation is cumbersome.

On the other hand, a technology consisting of two rear tension wedges have been proposed, as shown in Figure 2, Korean Patent Publication No. 10-2009-0074150 of the Patent Document 2 "A pressure sealing means for cable transit" sharp side Two wedge-shaped pressing elements 610 positioned opposite each other and facing each other vertically, and two wedge-shaped tension elements 620 positioned horizontally with their sharp sides facing each other. The pressure sealing means further comprises at least one tension member 630 disposed between the two tension elements 620. The tension member 630 is fixed axially by the fastening means 640 of the pressing element 610 and has a right hand thread on one side of the fastening means 640 and a left thread on the other side of the fastening means 640. At least one screw is characterized in that.

The prior art having such a configuration has a problem that assembly is difficult because the upper and lower pressure elements are separately positioned and fixed to the tension element by the fixing means.

Patent Document 1: Korean Patent Publication No. 10-0353187 "Cable Transmitter" Patent Document 2: Korean Laid-Open Patent Publication No. 10-2009-0074150 "Pressure sealing means for cable transit"

Therefore, the present invention has been proposed to improve such a conventional problem, by forming the rear tension wedge corresponding to the number of through holes of the front tension wedge into which the screw means is inserted, so that one rear tension wedge corresponds to one screw means. When the inner space of the multi-cable transit is not sealed, a new type of electromagnetic wave is formed to rotate the screw means at the corresponding position so that the rear tension wedge flows back and forth to completely seal the multi-cable inner space. It is an object to provide endpacking for multi-cable transit for shielding.

In addition, the overall size and volume of the end packing because the upper pressure wedge and the lower pressure wedge are not separated by the elastic member to efficiently maintain the assembly shape of the front tension wedge, the rear tension wedge, the upper pressure wedge, and the lower pressure wedge. Efficient assembly shape maintenance performance can be realized without changing the shape, and it is easy to insert into the frame, and there is an advantage of facilitating disassembly of the end packing during maintenance, management or rework, and the screw means is inserted and supported. By inserting the threaded sleeve into the inside of the front tension wedge and the rear tension wedge, the assembly structure is simplified, the production time and defect rate of the end packing are reduced, and the end packing is easy to be maintained, managed and transported. To provide endpacking for multi-cable transit for new forms of electromagnetic shielding The purpose.

According to a feature of the present invention for achieving the above object, the multi-cable transformer by the pressing force generated before, after, up and down by the rotation of the screw means located on the front end of the multi-cable transit sheet formed on the front In the end packing for the multi-cable transit for shielding the electromagnetic waves for sealing the space between the cable, the plate and the insert block installed in the inner space of the seat, the front face which is formed to face each other and flows before and after the rotation of the screw means Tension wedges and rear tension wedges; An upper pressurizing wedge and a lower pressurizing wedge formed to face each other and positioned at upper and lower sides of the front tension wedge and the rear tension wedge to flow up and down in response to the front and rear flows of the front tension wedge and the rear tension wedge; It characterized in that it comprises an elastic member for preventing the upper pressure wedge and the lower pressure wedge is separated from the upper and lower sides of the front tension wedge and the rear tension wedge.

In the end packing for the multi-cable transit for shielding electromagnetic waves according to the present invention as described above, the front tension wedge has a plurality of through holes so that the screw means penetrates from one side to the other side, so that the upper and lower surfaces are narrowed from one side to the other side. It has an inclined surface, has a settling hole so that the elastic member is located at a position corresponding to the elastic member on the other side, the rear tension wedge has a plurality of insertion grooves so that the screw means is inserted from one side to the other side, the upper and lower surfaces It has an inclined surface to widen from one side to the other side, has a settling hole so that the elastic member is located at a position corresponding to the elastic member on one side, the through hole of the front tension wedge and the insertion groove of the rear tension wedge the screw By means of rotation of the screw means moving along the threaded portion, the threaded portion being inserted into the means; It characterized in that the threaded sleeve for interfacing the front tension wedge and the rear tension wedge before, after the flow.

In the end-packing for the multi-cable transit for shielding electromagnetic waves according to the present invention, the threaded sleeve inserted into the through hole of the front tension wedge has a through hole penetrating from one side to the other side, and the inner peripheral surface of the through hole has The screw means has a threaded portion is inserted, the outer peripheral surface is fixed to the front tension wedge has a projection so as not to be separated, the threaded sleeve inserted into the insertion groove of the rear tension wedge has an insertion groove inserted from one side to the other side The inner peripheral surface of the insertion groove has a screw portion into which the screw means is inserted, and the outer peripheral surface is characterized in that it has a projection so as not to be fixed to the rear tension wedge.

In the end packing for the multi-cable transit for shielding electromagnetic waves according to the present invention, the rear tension wedge has a plurality of rear tension wedges having an insertion groove corresponding to the through hole of the front tension wedge so that the front tension wedge is adjacent to each other. It is made in a shape corresponding to, wherein the number of the rear tension wedge is characterized in that corresponding to the number of through holes of the front tension wedge.

The upper pressurizing wedge and the lower pressurizing wedge in the end packing for the multi-cable transit shielding for electromagnetic shielding according to the present invention are disposed to face each other above and below the front tension wedge and the rear tension wedge; The upper pressurizing wedge has an inclined surface to be narrowed from the upper surface to the lower surface to correspond to the inclined surfaces of the front tension wedge and the rear tension wedge, and has a settle hole at a position corresponding to the screw means on the lower surface, and penetrates the upper and lower surfaces. The elastic member has an insertion hole in which the lower pressure wedge is characterized in that it is made in a shape corresponding to the upper pressure wedge.

In the end packing for the multi-cable transit for shielding electromagnetic waves in accordance with the present invention, the upper pressurizing wedge protrudes in the direction of the front tension wedge and the rear tension wedge on the upper surface to prevent and support the end-packing during stacking. It further comprises a protruding end.

In the end-packing for the multi-cable transit for shielding electromagnetic waves according to the present invention, the elastic member is fixed to the insertion hole is fixed to the insertion hole of the upper pressure wedge and the lower pressure wedge; It characterized in that it comprises an elastic body having an elastic force coupled to the fixture.

In the end packing for the multi-cable transit for electromagnetic shielding according to the present invention, the elastic member of the elastic member is made of any one selected from the spring, rubber band, suspension.

According to the end-packing for the multi-cable transit for shielding electromagnetic waves according to the present invention as described above, by forming the rear tension wedge in the number corresponding to the through hole of the front tension wedge into which the screw means is inserted, one screw means Since the rear tension wedge is configured to correspond, when the inner space of the multi-cable transit is not sealed, the screw means at the corresponding position is rotated so that the rear tension wedge can flow before and after to completely seal the inner space of the multi-cable. It works.

In addition, the overall size and volume of the end packing because the upper pressure wedge and the lower pressure wedge are not separated by the elastic member to efficiently maintain the assembly shape of the front tension wedge, the rear tension wedge, the upper pressure wedge, and the lower pressure wedge. Efficient assembly shape maintenance performance can be realized without changing the shape, and it is easy to insert into the frame, and there is an advantage of facilitating disassembly of the end packing during maintenance, management or rework, and the screw means is inserted and supported. By inserting the threaded sleeve into the inside of the front tension wedge and the rear tension wedge, the assembly structure is simplified, the production time and defect rate of the end packing are reduced, and the end packing is easy to be maintained, managed and transported. There is one advantage.

1 and 2 are views for explaining the prior art,
3 is a perspective view of an end packing for a multi-cable transit for electromagnetic shielding according to a preferred embodiment of the present invention;
4 is an exploded perspective view of an end packing for a multi-cable transit for shielding electromagnetic waves according to a preferred embodiment of the present invention;
5 is a cross-sectional view of an end packing for a multi-cable transit for shielding electromagnetic waves according to a preferred embodiment of the present invention;
6 is a view showing an operating state of the end packing for the multi-cable transit for electromagnetic shielding according to a preferred embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 3 to 6, and like reference numerals denote like elements for performing the same functions in FIGS. 3 to 6. In the drawings and the detailed description, detailed description of specific elements and functions of elements not directly related to the technical features of the present invention will be omitted. .

3 to 6, the end packing 10 for the multi-cable transit for shielding electromagnetic waves in accordance with a preferred embodiment of the present invention is located on the top end of the multi-cable translating screw means (12) Front tension wedge 20, rear tension to seal the space between the cable, plate and insert block installed in the interior space of the multi-cable transit by the pressing force generated before, after, up and down by the rotation of The wedge 30, the upper pressurization wedge 40, the lower pressurization wedge 50 is composed of mutually assembled. Here, the front tension wedge 20 and the rear tension wedge 30 are formed to face each other and flow before and after the rotation of the screw means 12, the upper pressure wedge 40 and the lower pressure wedge 50 is the front Located in the upper and lower sides of the tension wedge 20 and the rear tension wedge 30 is to flow up and down in response to the front and rear flow of the front tension wedge 20 and the rear tension wedge 30. At this time, the upper pressure wedge 40 and the lower pressure wedge 50 is supported by the elastic member 60 so as not to be separated from the upper and lower sides of the front tension wedge 20 and the rear tension wedge 30.

The front tension wedge 20 has a plurality of through holes 22 so that the screw means 12 penetrates from one side to the other side, and has an inclined surface 24 so that the upper and lower surfaces thereof narrow from one side to the other side, which will be described later on the other side. It has a settling hole 26 so that the elastic member 60 is located. In addition, the threaded sleeve 72 is installed in the through-hole 22 so that the screw means 12 is inserted to be moved forward and backward by the rotation of the screw means 12.

The threaded sleeve 72 has a through hole 722 penetrating from one side to the other side, and has a screw portion 7222 into which the screw means 12 is inserted on the inner circumferential surface of the through hole 722, and on the outer circumferential surface. It has a projection (7224) to be fixed to the tension wedge 20 so as not to be separated.

The rear tension wedge 30 has an insertion groove 32 to insert the screw means 12 from one side to the other side, and has an inclined surface 34 so that the upper and lower surfaces thereof are widened from one side to the other side, and an elastic member described later on one side. It has a settle hole 36 so that the elastic member 60 is positioned at a position corresponding to the 60. In addition, a threaded sleeve 74 is installed in the insertion groove 32 so that the screw means 12 is inserted to move forward and backward by the rotation of the screw means 12.

The threaded sleeve 74 has an insertion groove 742 penetrating from one side to the other side, and has a screw portion 7742 on which the screw means 12 is inserted on the inner circumferential surface of the insertion groove 742, and on the outer circumferential surface. It is fixed to the tension wedge 20 has a projection (7424) to prevent it from being separated.

Meanwhile, the threaded sleeves 72 and 74 are configured differently and interpolated into the front tension wedge 20 and the rear tension wedge 30 to be inserted from one side of the front tension wedge 20 to the rear tension wedge 30. This is because the other end of the screw means 12 to be inserted does not need a separate fastening means, thereby increasing the efficiency of the work.

The threaded sleeves 72 and 74 are provided by installing the threaded sleeves 72 and 74 in the through holes 22 and the insertion grooves 32 of the front tension wedge 20 and the rear tension wedge 30. Since the screw means 12 is moved along the thread portions 7222 and 7422 formed in the through hole 722 and the insertion groove 742 of the front tension wedge 20 and the rear tension wedge ( It is easy to flow 30 before and after, it is possible to prevent the insertion hole 32 of the through hole 22 and the rear tension wedge 30 of the front tension wedge 20, even for long time use, There is an effect that can reduce the production time and the defective rate of the end-packing (10).

On the other hand, the rear tension wedge 30 is formed to have an insertion groove 32 corresponding to the through-hole 22 of the front tension wedge 20, a plurality of adjacent to each other shape (size) corresponding to the front tension wedge 20 Is made of. That is, the number of rear tension wedges 30 corresponds to the number of through holes 22 of the front tension wedge 20, and preferably two are adjacent to each other.

As described above, in the end packing 10 for the multi-cable transit for shielding electromagnetic waves, the through hole of the front tension wedge 20 into which the rear tension wedge 30 is screwed 12 is inserted. 22 and one rear tension wedge 30 correspond to one screw means 12, so that the screw means at the corresponding position when the inner space of the multi-cable transit is not sealed. The rear tension wedge 30 is rotated before and after the rotation of the 12 to completely seal the internal space of the multi-cable.

The upper pressurizing wedge 40 and the lower pressurizing wedge 50 have a corresponding shape and are disposed to face each other on the upper and lower sides of the front tension wedge 20 and the rear tension wedge 30.

The upper pressurizing wedge 40 has an inclined surface 42 to be narrowed from the upper surface to the lower surface so as to correspond to the inclined surfaces 24 and 34 of the front tension wedge 20 and the rear tension wedge 30, and screw means 12 on the lower surface. It has a mounting hole 44 at a position corresponding to the through hole and has an insertion hole 46 in which the elastic member 60, which will be described later, penetrates the upper and lower surfaces. At this time, the insertion hole 46 is a stepped portion 462 is formed so that the elastic member 60 is not separated.

The lower pressurizing wedge 50 has an inclined surface 52 to be narrowed from the lower surface to the upper surface so as to correspond to the inclined surfaces 24 and 34 of the front tension wedge 20 and the rear tension wedge 30, and the screw means 12 on the upper surface. It has a mounting hole 54 at a position corresponding to the through hole 56 has an insertion hole 56 is located through the upper and lower surfaces to be described later the elastic member 60. At this time, the insertion hole 56 is a stepped 562 is formed so that the elastic member 60 is not separated.

In this way, the upper pressing wedge 40 and the lower pressing wedge 50 are fastened by the elastic member 60, thereby making it easy to assemble.

On the other hand, the upper pressure wedge 40 further includes a protruding end 48 to protrude in the direction of the front tension wedge 20 and the rear tension wedge 30 on the upper surface so that the lower surface of the lower pressure wedge 50 can be positioned. Is done.

As such, by forming the protruding end 48 on the upper surface of the upper pressurizing wedge 40, the end packing 10 may be prevented from being separated during the lamination, and the lamination may be stably stacked.

The elastic member 60 is inserted into the insertion holes 46 and 56 of the upper pressure wedge 40 and the lower pressure wedge 50 so that the upper pressure wedge 40 and the lower pressure wedge 50 have the front tension wedge 20. And to prevent the separation from the upper and lower tension wedge 30, the fastener 62 is inserted into the insertion holes 46, 56 of the upper pressure wedge 40 and the lower pressure wedge 50, Both sides include an elastic body 64 coupled to the fixture 62. Here, the elastic body 64 is made to have an elastic force, characterized in that made of a selected one of the spring, rubber band, suspension (suspension). On the other hand, it is preferable to use a spring that is easy to fasten and has elasticity and tension.

The fastener 62 of the elastic member 60 is located at the stepped portions 462 and 562 formed in the insertion holes 46 and 56 of the upper pressure wedge 40 and the lower pressure wedge 50, and the elastic body 64 is It is coupled to both sides of the fixture 62 through the insertion holes 46 and 56, and pulls the upper pressure wedge 40 and the lower pressure wedge 50 from each other, the upper tension wedge 20 and the upper tension wedge 30, Do not let go of the lower side.

As described above, according to the end packing 10 for the multi-cable transit for shielding electromagnetic waves, the rear tension wedge 30 penetrates the front tension wedge 20 into which the screw means 12 are inserted. Since the rear tension wedge 30 is configured to correspond to one screw means 12 by forming the number corresponding to the hole 22, when the inner space of the multi-cable transit is not sealed, By rotating the screw means 12, the rear tension wedge 30 is flowed before and after, thereby effectively sealing the multi-cable internal space.

In addition, the upper pressure wedge 40 and the lower pressure wedge (40) and the lower pressure wedge (30), the upper pressure wedge (40), the upper pressure wedge (40) so that the assembly shape of the lower pressure wedge (50) can be efficiently maintained. Since the 50 is not separated by the elastic member 60, it is not only possible to realize efficient assembly maintenance performance without changing the overall size and volume of the end packing 10, but also easy to insert into the frame, and to maintain, maintain or When reworking, there is an advantage of facilitating disassembly of the end packing 10, and the threaded sleeves 72 and 74 in which the screw means 12 are inserted and supported are provided in the front tension wedge 20 and the rear tension wedge. By inserting into the inside of the 30, the assembly structure is simplified, the production time and the defective rate of the end packing 10 are reduced, and the advantages of easy handling, maintenance, management, and transportation of the end packing 10 are provided. have.

Looking at the operating state of the end-packing 10 for the multi-cable transit for shielding electromagnetic waves according to a preferred embodiment of the present invention having such a configuration, rotating the screw means 12 installed on the front of the front tension wedge 20 When the front tension wedge 20 is to the other side, the rear tension wedge 30 flows to one side to be in contact with each other. At this time, the front tension wedge 20 and the rear tension wedge 30, the upper pressure wedge 40 and the lower pressure wedge 50 in front of the idle flow, the inclined surface of the front tension wedge 20 and the rear tension wedge 30 It will flow up and down along (24, 34). In addition, the front tension wedge 20 and the rear tension wedge 30 are in contact with the expansion and the upper pressure wedge 40 and the lower pressure wedge 50 is expanded up and down, the cable installed in the multi-cable transit interior space, The plate and insert block will be sealed.

As described above, the end-packing for the multi-cable transit for shielding electromagnetic waves according to a preferred embodiment of the present invention is shown in accordance with the above description and drawings, but this is merely described for example and does not depart from the spirit of the present invention. It will be apparent to those skilled in the art that various changes and modifications can be made without departing from the scope of the present invention.

10: End packing for multi-cable transit for electromagnetic shielding
12: screw means 20: front tension wedge
30: rear tension wedge 40: upper pressurized wedge
50: lower pressure wedge 60: elastic member
72, 74: threaded sleeve

Claims (8)

Cables, plates installed in the interior space of the multi-cable transit sheet by pressing force generated before, after, up and down by the rotation of the screw means formed on the front and located on the top end of the multi-cable transit for electromagnetic shielding; In the end packing for multi-cable transit for electromagnetic shielding to seal the space between the insert blocks,
A front tension wedge and a rear tension wedge formed to face each other and flowing before and after the rotation of the screw means;
An upper pressurizing wedge and a lower pressurizing wedge formed to face each other and positioned at upper and lower sides of the front tension wedge and the rear tension wedge to flow up and down in response to the front and rear flows of the front tension wedge and the rear tension wedge;
It includes an elastic member for preventing the upper pressure wedge and the lower pressure wedge is separated from the upper and lower sides of the front tension wedge and the rear tension wedge;
The front tension wedge has a plurality of through holes to penetrate the screw means from one side to the other side, and has an inclined surface so that the upper and lower surfaces are narrowed from one side to the other side, and the elastic member is located at a position corresponding to the elastic member on the other side. With an anchor hole to be positioned,
The rear tension wedge has a plurality of insertion grooves so that the screw means is inserted from one side to the other side, and has an inclined surface so that the upper and lower surfaces thereof are widened from one side to the other side, and the elastic member is positioned at one side corresponding to the elastic member. With an anchor hole to be positioned,
The front tension wedge and the rear tension wedge are moved forward and rearward by the rotation of the screw means moving along the threaded portion, with the screw portion inserted into the through hole of the front tension wedge and the insertion groove of the rear tension wedge. End packing for multi-cable transit for electromagnetic shielding, characterized in that a threaded sleeve is interpolated to allow flow.
delete The method of claim 1,
The threaded sleeve inserted into the through hole of the front tension wedge has a through hole penetrating from one side to the other side, has a screw portion into which the screw means is inserted into the inner circumferential surface of the through hole, and is fixed to the front tension wedge on an outer circumferential surface thereof. Have projections to prevent them from falling off,
The threaded sleeve inserted into the insertion groove of the rear tension wedge has an insertion groove inserted from one side to the other side, and has a screw portion into which the screw means is inserted into an inner circumferential surface of the insertion groove, and is fixed to the rear tension wedge on an outer circumferential surface thereof. End packing for multi-cable transit for electromagnetic shielding, characterized in that it has a projection so as not to be separated.
The method of claim 1,
The rear tension wedge is formed of a plurality of rear tension wedges having insertion grooves corresponding to the through holes of the front tension wedge are adjacent to each other to correspond to the front tension wedge.
The number of the rear tension wedge is the end packing for the multi-cable transit for electromagnetic shield, characterized in that corresponding to the number of through holes of the front tension wedge.
The method of claim 1,
The upper pressurizing wedge and the lower pressurizing wedge are disposed to face each other on the upper and lower sides of the front tension wedge and the rear tension wedge;
The upper pressurizing wedge has an inclined surface to be narrowed from the upper surface to the lower surface to correspond to the inclined surfaces of the front tension wedge and the rear tension wedge, and has a settle hole at a position corresponding to the screw means on the lower surface, and penetrates the upper and lower surfaces. Has an insertion hole in which the elastic member is located,
The lower pressurizing wedge is an end packing for a multi-cable transit for electromagnetic shields, characterized in that the shape corresponding to the upper pressurizing wedge.
The method of claim 5, wherein
The upper pressurizing wedge further includes a protruding end for protruding in the direction of the front tension wedge and the rear tension wedge on the upper surface to prevent and support the separation of the end packing when the stacking is stacked. For endpacking.
The method of claim 5, wherein
The elastic member is fixed to the insert is fixed to the insertion hole of the upper pressure wedge and the lower pressure wedge;
End packing for a multi-cable transit for electromagnetic shields, characterized in that it comprises an elastic body having an elastic force coupled to the fixture.
The method of claim 7, wherein
End packing for the multi-cable transit for the electromagnetic shield, characterized in that the elastic member of the elastic member is made of any one selected from the spring, rubber band, suspension.

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