KR102114814B1 - Electric wire for preventing electric shock - Google Patents

Abstract

The present invention relates to a distribution line support device of a building for preventing an electric shock accident. According to the present invention, the distribution line support device of a building for preventing an electric shock accident comprises: a pair of side rails (110, 110′) arranged to be parallel with each other; an under rung (120); upper layer assemblies (130, 130′); a holder (140) consisting of a reference weight (141), a supporter (142), and a torsion spring; a base (150); a leg (160); and an electric shock prevention device (170). According to the present invention, a leakage current of a distribution line can be detected to prevent an electric shock accident.

Description

ELECTRIC WIRE FOR PREVENTING ELECTRIC SHOCK

The present invention relates to a distribution line support mechanism of a building for preventing electric shock accidents.

Due to the increase in population, the number of apartments and large buildings, which are apartments, is increasing due to the relatively small number of residential, work, and living spaces. It is becoming a form.

In general, in the interior of a building, a lot of wiring such as a wire or a telephone line is complicatedly installed to use various electronic devices.

When constructing a conventional building, only the electric cable had to be wired. Recently, as the use of media has been diversified and speeded up, the installation of various medicinal wires other than electric cables such as telephone lines, high-speed Internet dedicated lines, and CATV / MATV distribution lines has also been installed. For this purpose, a communication EPS room or a pit (PIT) is provided for each floor and is designed by wiring using a distribution line tray.

However, since the support mechanism such as the distribution line tray directly supports and supports the distribution line through which a relatively high-voltage current flows, the manager has an electric shock accident due to the high-voltage current.

Therefore, measures to prevent electric shock accidents through the support mechanism were urgently required.

On the other hand, since the conventional tray for installing the distribution line has a shelf structure on the first floor, there is a limit to the number of supporting distribution lines compared to the occupied area.

In order to solve this problem, the conventional tray has a hanger shape on the wall of the building, so a plurality of distribution lines are simply hung or supported, or multi-layer shelves are installed horizontally to settle distribution lines for each floor. However, since the hanger-type tray needs to have a relatively large indoor space and a wall, the structure that can be installed is limited, and the multi-layer tray has difficulty in managing the distribution line wiring because the administrator cannot directly check the distribution line located on the lower floor.

Prior Art Document 1. Patent Registration No. 10-0958548 (announced on May 18, 2010)

Accordingly, the present invention is to solve the above problems, it is possible to detect the leakage current of the distribution line and warn the administrator, as well as insulate the leakage current so as not to cause an electric shock accident even in contact with the manager, and multiple distribution lines An object of the present invention is to solve the provision of a distribution line support mechanism of an electric shock prevention structure that can easily manage the distribution lines of the lower layer by intercepting the distribution lines of the upper layer which can be wired by floor and cover the distribution lines wired to the lower layer without interference.

In order to achieve the above object, the present invention,

A plurality of through grooves 112 are formed at regular intervals along the length direction, and pivoting grooves 113 and 113 'are formed on both side upper portions of the through grooves 112, and a pair of sides are arranged side by side. Rails 110, 110 '; An under rung 120 which is fixed by connecting a pair of the side rails 110 and 110 'and arranged at regular intervals along the side rails 110 and 110' so as to secure a distribution line; In the rotation groove (113, 113 '), the lower end is rotated around the first axis (A1) and the pivot (131, 131'), and the guide rail (2) to form a two-layer structure with the under rung (120) 110, 110 '), the over rung 132 disposed at regular intervals on the under rung 120 and the both ends of the one end of the over rung 132 are fixed to the upper portions of the pivots 131 and 131', respectively. The linker 133 to be instructed, the insulating panel 136 mounted on the upper surfaces of the under rung 120 and the over rung 132, respectively, and the power supply network 137 mounted on the upper surface of the insulating panel 136 to support the distribution line. ) Upper assembly (130, 130 '); The reference weight 141 and the lower portion are rotatably connected to the linker 133 to be drawn in and out into the through groove 112 along the rotation of the pivots 131 and 131 ', and the lower portion is the reference weight 141 ) And the supporter 142 which is rotatably connected to the lower part and the rotating shaft base 141a and extends laterally from the reference weight 141, and the rotating shaft in the direction in which the reference weight 141 and the supporter 142 fold. 141a) the holder 140 consisting of a torsion spring to apply elasticity; An ammeter 171 that is electrically connected to the energization network 137 to detect the current through leakage of the distribution line and measure the size, and an alarm device that sends an alarm signal when the measurement size of the ammeter 171 is greater than a reference value Electric shock prevention device 170 consisting of (172); includes,

The support groove 151a is formed and the main body 151 is fixed to the bottom surface of the over rung 132, and a guide rail 152 formed on both inner surfaces of the support groove 151a is formed with a rectangular fitting hole 152a. , 152 ') consisting of a base 150;

The movable body 161 that is movably inserted into the support groove 151a, the protrusions 162 which are respectively protruded on both sides of the movable body 161 and are movably engaged with the fitting hole 152a, and the projection If (162) is located on the lowest side of the support groove (151a) along the fitting hole (152a) is introduced into the support groove (151a) and the projection (162) is located on the outermost side of the support groove (151a), the support groove (151a) ) Is connected to the moving body 161 via a hinge 164 to be drawn and rotated, and a leg 160 composed of a support 163 supporting the overrun 132 to maintain a posture; a building for preventing electric shock accidents further comprising It is a distribution line support mechanism.

The present invention has the effect of not only detecting a leakage current of the distribution line and warning the manager, but also insulating the leakage current so that an electric shock accident does not occur even in the contact of the manager.

In addition, a plurality of distribution lines can be wired for each layer, and the distribution lines of the upper layer that cover the distribution lines wired to the lower layer are easily collected, so that the distribution lines of the lower layer can be managed without interference.

1 is a perspective view showing a distribution wire is wired for each layer of the support mechanism according to the present invention,
2 and 3 are perspective views showing the operation of the support mechanism according to the present invention,
4 is a block diagram schematically showing an electric shock prevention device for detecting and alerting a short circuit of a supporting mechanism according to the present invention;
5 is a side view sequentially showing the operation of the support mechanism according to the present invention,
6 is a side view showing a state in which the upper layer of the support mechanism according to the present invention is completely unfolded,
7 is a perspective view showing another embodiment of a support mechanism according to the present invention,
8 is an exploded perspective view showing an installation state of a leg supporting an overrun of a support mechanism according to the present invention,
9 is a cross-sectional view showing an operation state of the leg.

The above-described features and effects of the present invention will become apparent through the following detailed description in connection with the accompanying drawings, and accordingly, those skilled in the art to which the present invention pertains can easily implement the technical spirit of the present invention. There will be. The present invention can be applied to various changes and may have various forms, and specific embodiments will be illustrated in the drawings and described in detail in the text. However, it is not intended to limit the present invention to a specific disclosure form, it should be understood to include all modifications, equivalents, or substitutes included in the spirit and scope of the present invention. Terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention.

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

1 is a perspective view showing a distribution wire is wired for each layer of the support mechanism according to the present invention, FIGS. 2 and 3 are perspective views showing an operation state of the support mechanism according to the present invention, and FIG. 4 is the present invention It is a block diagram schematically showing an electric shock prevention device that detects and alerts a short circuit of a supporting mechanism according to the present invention, FIG. 5 is a side view sequentially showing an operation state of the supporting mechanism according to the present invention, and FIG. 6 is a supporting device according to the present invention It is a side view that shows the upper layer of the mechanism fully unfolded.

1 to 6, the support mechanism 100 of the present embodiment connects a pair of side rails 110 and 110 ′ and a pair of side rails 110 and 110 ′, and the lower power distribution line C1 ), The upper assembly (130, 130 ') comprising a plurality of under-runs 120 for seating, and an over-rung 132 installed on top of the under-runs 120, and flows from the over-rung 132 by its own weight. The cradle 140 receiving and supporting the lowered upper power distribution line C2, the base 150 fixed to the over rung 132, and the leg 160 connected to the base 150 and foldable with the over rung 132 , Supporting mechanism 100 includes an electric shock prevention device 170 for detecting an electric leakage of the upper and lower distribution lines (C1, C2) supported by the support mechanism 100. Therefore, the support mechanism 100 of the present embodiment can place a plurality of distribution lines C1 and C2 on the rungs 120 and 132 constituting the second floor, and the under rung can be opened and closed in the case of the overrun 132. The lower power distribution line C1 seated at 120 can also be easily inspected and taken without interference.

Each configuration for this will be described in more detail.

Side rails (110, 110 '), a plurality of through grooves 112 are formed at regular intervals along the longitudinal direction, and pivoting grooves (113, 113') are formed on both sides of the through grooves 112, respectively. They form a pair that is placed next to each other.

Typically, the tray consists of side rails and rungs. However, since the support mechanism 100 of the present embodiment additionally constitutes the over rung 132, the side rails 110 and 110 'have a through groove 112 and a rotation groove 113 and 113' for installing the over run 132. ) Are formed respectively.

2 and 3, the pivoting grooves 113 and 113 'are formed to have chins on both sides at the upper portion of the through groove 112, and the pivoting plates 131 and 131 installed in the pivoting grooves 113 and 113' are respectively formed. ').

The under rung 120 is fixed by connecting a pair of side rails 110 and 110 ', and is arranged at regular intervals along the side rails 110 and 110' to seat the distribution line. As described above, the under rung 120 performs a function of a rung configured in a known tray.

Upper assembly (130, 130 '), the rotating groove (113, 113'), the lower end is rotated around the first axis (A1) is installed to rotate (131, 131 '), the under rung 120 and Two sides of the overrun 132 and one end of the over rung 132 disposed at regular intervals on the under rung 120 along the guide rails 110 and 110 'to form a two-layer structure. ') Each of the linker 133 fixed to the upper portion, the under rung 120 and the over rung 132, the insulating panel 136 that is seated on the upper surface of the insulating panel 136, and the upper surface of the insulating panel 136, respectively to distribute the power distribution line. The supporting network is composed of a power supply network (137).

The rotating table (131, 131 ') is connected to rotate about the first axis (A1) in the rotating groove (113, 113'), and the over rung (132) fixed to the rotating table (131, 131 ') is supported. It is preferable that a stopper (not shown) is configured so as not to incline from the inside of the mechanism 100 to the floor. The first shaft (A1) is connected to the lower end of the rotating table (131, 131 ') so that the upper portion of the rotating table (131, 131') rotates.

The over rung 132 forms the upper layer of the under rung 120, and one end is fixed to the pivots 131 and 131 'via the linker 133. Therefore, the over rung 132 rotates as shown in the drawing (b) of FIG. 5 along the rotation of the pivots 131 and 131 '. The over rung 132 of the present embodiment forms a 'a' shape with the pivots 131 and 131 ', and the other end of the overrun 132 is guide rails by the stopper of the pivots 131 and 131'. 110, 110 ') maintain my posture without tilting to the bottom.

The support mechanism 100 of the present embodiment, the upper assembly (130, 130 ') is installed in pairs on each of a pair of guide rails (110, 110'), each over rung of the upper assembly (130, 130 ') ( 132) the other end is connected to each other.

The linker 133 fixes the pivots 131 and 131 'and the overrun 132 in the form of' a 'as described above.

Meanwhile, the upper layer assemblies 130 and 130 ′ of the present embodiment further include a cover 134 covering the upper surface of the over rung 132. The cover 134 is formed so that the ends protrude toward the paired upper layer assembly 130 ', so that the cover 134 is supported by the upper layer assembly 130'. This is to allow the base 150 (see FIG. 8) and the leg 160 (see FIG. 8) to be installed only in one of the pair of upper assembly 130, 130 ', the base 150 and the leg 160 are It will be explained again below.

The insulating panel 136 is seated on the upper surfaces of the under rung 120 and the over rung 132, and insulates the power distribution lines C1 and C2 from the under rung 120 and the over rung 132, respectively. Therefore, even if a short circuit occurs in the distribution lines C1 and C2, the support mechanism 100 including the under rung 120 and the over rung 132 maintains an insulation state, and through this, the manager is directly connected to the support mechanism 100. Electric shock can be prevented.

The power supply network 137 is seated on the upper surface of the insulating panel 136 to directly support the distribution lines C1 and C2. Therefore, when a short circuit occurs in the distribution lines C1 and C2, the power supply network 137 receives the shorted current. Of course, the power supply network 137, the under rung 120, and the over rung 132 are insulated by the insulating panel 136, so even if current flows through the power supply network 137, the support mechanism 100 except for the power supply network 137 The constituent members of maintain the insulating state.

The cradle 140, the upper portion is rotatably connected to the linker 133, the reference weight 141 and the lower portion is suspended so as to be drawn out through the through groove 112 along the rotation of the pivot (131, 131 ') The supporter 142 that is rotatably connected to the lower portion of the reference weight 141 and the rotation axis 141a as a reference and extends laterally from the reference weight 141, and in a direction in which the reference weight 141 and the supporter 142 are folded. It consists of a torsion spring (not shown) that applies elasticity on the rotating shaft (141a).

The reference weight 141 is rotatably connected to the upper linker 133 to form a suspended connection structure, and is arranged to be drawn out from the through groove 112 as shown in FIG. Therefore, when the pivot (131, 131 ') is rotated on the guide rail (110, 110'), the reference weight 141 maintains the posture and moves without interference through the through groove (112). For reference, it is preferable that the reference weight 141 of the present embodiment has a weight greater than or equal to a reference value to keep the posture stable without shaking.

The supporter 142 is rotatably connected to the rotating shaft 141a formed to protrude outward from the lower portion of the reference weight 141. Therefore, the supporter 142 forms a connection structure foldable with the reference weight 141. The supporter 142 of this embodiment prevents the upper distribution line C2 from flowing out of the overrun 132 from being separated because the upper end has a bent 'A' shape. A detailed description of this will be made again below.

On the other hand, the rotating shaft 141a is configured with a torsion spring, so that the reference weight 141 and the supporter 142 are always folded. That is, in a state in which the external force is not maintained, the folded state is maintained, and when the external force beyond the elasticity of the torsion spring is received, it can be unfolded from the reference weight 141. Therefore, in the state where the over rung 132 of the upper assembly 130 and 130 'forms a two-layer structure in parallel with the under rung 120, the supporter 142 is a reference weight 141 as shown in FIG. 5 (a). While maintaining the folded state to perform the fence function of the over rung (132). To this end, it is preferable that the supporter 142 has a sufficient length protruding upward of the reference weight 141.

The electric shock prevention device 170 is electrically connected to the electricity supply network 137 to detect the current through electric leakage of the distribution line and measure the size, and if the measurement size of the ammeter 171 is greater than or equal to a reference value And an alarm device 172 that transmits an alarm signal.

The ammeter 171 is a known mechanism for measuring the magnitude of the current by sensing the current flowing through the energizing network 137 and measuring the magnitude. Therefore, description of the configuration, structure, and operation principle of the ammeter 171 will be omitted.

If the magnitude of the current measured by the ammeter 171 is greater than or equal to a reference value, the alarm device 172 recognizes the leakage of the distribution lines C1 and C2 and transmits an alarm signal. Here, the warning signal is a signal for operating the warning lamp or speaker, and notifies the manager of the current short circuit danger situation through the operation of the warning lamp or speaker.

The operation of the support mechanism 100 according to the present invention will be sequentially described with reference to FIGS. 1 to 6.

As illustrated in FIG. 1, the lower power distribution line C1 and the upper power distribution line C2 are mounted on the under rung 120 and the over rung 132, respectively. In this state, if a problem is identified in the upper power distribution line C2 as shown in FIG. 5 (a), the upper power distribution line C2 exposed to the outside can easily inspect the upper power distribution line C2. However, when a problem is confirmed in the lower power distribution line C1, the manager lifts the overrun 132 as shown in FIG. 5 (b) and rotates the pivot 131 around the first axis A1. Since the over rung 132 is integrally fixed with the rotating table 131, the rotating table 131 rotates corresponding to the rotation angle of the over rung 132.

When the rotating table 131 is rotated, the reference weight 141 is drawn out from the through groove 112 about the second axis A1 of the linker 133. At this time, the rotating table 131 moves while maintaining my posture.

On the other hand, the upper power distribution line (C2) seated on the over-rung 132 flows down the ramp by the inclination of the over-rung (132), in this process the upper power distribution line (C2) is as shown in Figure 5 (b) The supporter 142 is pressed. When the upper power distribution line (C2) is a certain number or more, since the weight exceeds the elasticity of the torsion spring installed on the rotating shaft (141a), the supporter (142) is opened to rotate from the reference weight (141), as shown in Figure 6 The upper power distribution line C2 is accommodated on the supporter 142. For reference, the supporter 142 of the present embodiment has an upper end protruding in an 'A' shape, preventing the upper distribution line C2 flowing from the overrun 132 from being pulled into the supporter 142 without departure, and the supporter (142) to maintain my posture without departure even when in the state.

7 is a perspective view showing another embodiment of a support mechanism according to the present invention.

2 and 3 and 7, the upper assembly (130, 130 ') of the present embodiment, the rotating assembly (131, 131') of the upper assembly (130, 130 ') adjacent to each other integrally connects The connecting rod 135 is further included.

The upper assembly 130 and 130 'shown in FIG. 2 are individually operated in the same side rail 110 and 110'. In this case, the manager has a hassle of rotating the upper assembly 130 and 130 'one by one in order to manage the lower power distribution line C2 in the whole rather than a part of the support mechanism 100.

Therefore, the upper assembly (130, 130 ') of the present embodiment is connected to the rotating stand (131, 131') of the upper assembly (130, 130 ') adjacent to each other with a connecting rod 135, the administrator pulls the connecting rod 135 All the upper assembly (130, 130 ') configured in the support mechanism 100 is operated while the over rung 132 is vertically unfolded as shown in FIG.

Of course, when the manager pushes the connecting rod 135, the pivots 131, 131 'are operated in a batch, and the overrun 132 is horizontally arranged as shown in FIG.

8 is an exploded perspective view showing an installation state of a leg supporting an overrun of a support mechanism according to the present invention, and FIG. 9 is a cross-sectional view showing an operation state of the leg.

2 to 9, the support mechanism 100 of the present embodiment includes a main body 151 in which a support groove 151a is formed and fixed to the bottom surface of the overrun 132, and a rectangular fitting hole 152a. A base 150 formed of guide rails 152 and 152 'formed on both inner surfaces of the support groove 151a; The movable body 161 that is movably inserted into the support groove 151a, and the protrusions 162 and protrusions 162 which are respectively protruded on both sides of the movable body 161 and are movably engaged with the fitting hole 152a, If it is located on the lowest side of the support groove 151a along the fitting hole 152a, it is drawn into the support groove 151a, and when the protrusion 162 is located on the outermost side of the support groove 151a, it is withdrawn from the support groove 151a. It is further connected to the moving body 161 via the hinge 164 to be rotated, and the leg 160 composed of a support 163 to maintain the posture by supporting the overrun 132.

The base 150 is a medium that connects the legs 160 and the over rung 132 to each other, and includes a body 151 fixed to the bottom surface of the over rung 132, and the body 151 is a support groove 151a This is formed, and guide rails 152 and 152 'are installed on both inner surfaces. Here, the guide rails 152 and 152 'are formed with a rectangular fitting hole 152a, and the legs 160 connected to the guide rails 152 and 152' are drawn in and out of the support groove 151a.

The leg 160 supports the over rung 132. Therefore, the over rung 132 maintains a horizontal posture without tilting from the inside of the support mechanism 100.

To this end, the leg 160 includes a moving body 161 moving in the support groove 151a. Here, projections 162 engaged with the guide rails 152 and 152 'are formed on both sides of the movable body 161, respectively, so that the movable body 161 can move within the range of the guide rails 152 and 152'. .

On the other hand, the support 163, when the projection 162 is located on the lowest side of the support groove 151a along the fitting hole 152a, is introduced into the support groove 151a, and the projection 162 is the support groove 151a When located on the outermost side of the withdrawal from the support groove (151a). Here, when the projection 162 is located at the lowest side of the support groove 151a, when the support 163 is pressed as shown in FIG. 9 (a), the moving body 161 moves deeply into the support groove 151a. , When the projection 162 is located on the outermost side of the support groove 151a, the overrun 132 is lifted as shown in FIG. 9 (b), so that the support 163 is moved from the support groove 151a by its own weight. It is time to move down.

On the other hand, since the support 163 and the movable body 161 are rotatably connected via a hinge 164, when the support 163 is withdrawn from the support groove 151a as shown in FIG. 9 (b), the support 163 ) Is rotatable based on the hinge 164. However, as shown in FIG. 9 (a), when the support 163 is drawn into the support groove 151a, the support 163 is caught in the support groove 151a to maintain my posture without shaking, and thus the over rung 132 Keeps the level stable without shaking.

The base 150 and the leg 160 may be installed on both a pair of upper layer assemblies 130 and 130 ', but may be installed on only one of the two. When installed only in one upper layer assembly 130 ', the cover 134 is covered by the over rung 132 of the other upper layer assembly 130, so that the protruding portion of the cover 134 is one upper layer assembly 130' ).

As a result, the over rung of one upper layer assembly 130 'is supported by the base 150 and the leg 160, and the other upper layer assembly 130 is supported by the cover 134 caught in the over rung.

In the detailed description of the present invention described above, the preferred embodiments of the present invention have been described, but those skilled in the art or those skilled in the art will appreciate the spirit of the present invention as set forth in the claims below. And it will be understood that the present invention can be variously modified and changed within a range not departing from the technical field.

100; Support mechanisms 110, 110 '; Side rail 112; Through groove
113, 113 '; Hoedong Home 120; Under rung 130; Upper assembly
131, 131 '; Hoedongdae 132; Overrun 133; Linker
134; Cover 135; Connecting rod 140; holder
141; Reference weight 142; Supporter 150; Base
151; Body 151a; Support grooves 152, 152 '; Guide rail
152a; Fitting hole 160; Leg 161; Moving object
162; Protrusion 163; Support 164; Hinge

Claims (1)

A plurality of through grooves 112 are formed at regular intervals along the length direction, and pivoting grooves 113 and 113 'are formed on both side upper portions of the through grooves 112, and a pair of sides are arranged side by side. Rails 110, 110 '; An under rung 120 which is fixed by connecting a pair of the side rails 110 and 110 'and arranged at regular intervals along the side rails 110 and 110' to seat a distribution line; In the rotation groove (113, 113 '), the lower end is rotated around the first axis (A1) and the pivot (131, 131'), and the guide rail (2) to form a two-layer structure with the under rung (120) 110, 110 '), the over rung 132 disposed at regular intervals on the under rung 120 and the both ends of the one end of the over rung 132 are fixed to the upper portions of the pivots 131 and 131', respectively. A linker 133, an insulating panel 136 mounted on the upper surfaces of the under rung 120 and an over rung 132, and an electricity network 137 seated on the upper surface of the insulating panel 136 to support the distribution line. ) Upper assembly (130, 130 '); The reference weight 141 and the lower portion are rotatably connected to the linker 133 to be drawn in and out into the through groove 112 along the rotation of the pivots 131 and 131 ', and the lower portion is the reference weight 141 ), The supporter 142 that is rotatably connected to the lower part and the rotational shaft 141a as a reference and spreads laterally from the reference weight 141, and the rotational shaft in the direction in which the reference weight 141 and the supporter 142 fold. 141a) the holder 140 consisting of a torsion spring to apply elasticity; An ammeter 171 that is electrically connected to the energization network 137 to detect the current through the leakage of the distribution line and measure the size, and an alarm device that sends an alarm signal when the measurement size of the ammeter 171 is greater than a reference value Electric shock prevention device 170 consisting of (172); includes,
The support groove 151a is formed and the main body 151 fixed to the bottom surface of the over rung 132, and a guide rail 152 having a rectangular fitting hole 152a formed on both inner surfaces of the support groove 151a , 152 ') consisting of a base 150;
The movable body 161 that is movably inserted into the support groove 151a, the protrusions 162 which are respectively protruded on both sides of the movable body 161 and are movably engaged with the fitting holes 152a, and the projections If (162) is located on the lowest side of the support groove (151a) along the fitting hole (152a) is introduced into the support groove (151a) and the projection (162) is located on the outermost side of the support groove (151a), the support groove (151a) Characterized in that it further comprises a leg 160 consisting of a support 163 that is connected to the mobile body 161 via a hinge 164 and rotated to be rotated by being pulled from) and supporting the overrun 132 to maintain posture. Distribution line support mechanism for buildings to prevent electric shock.

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