KR102301707B1 - Earthquake-proof lighting implement mounting structure - Google Patents

Abstract

The present invention relates to an earthquake-proof lighting lamp mounting structure. The earthquake-proof lighting lamp mounting structure comprises: a shaft support bracket (20) installed on a rear surface of a lighting lamp (10); a gear fixing bracket (30) installed on the rear surface of the lighting lamp (10); a shaft (40) rotatably coupled to the shaft support bracket (20) and the gear fixing bracket (30); a fixed support gear (50); a fixed support jaw (52) installed on the fixed support gear (50); a rotation gear (60) fixed to an outer circumferential surface of the shaft (40); a rotation support jaw (62) installed on the rotation gear (60); a gear coupling actuating spring (70) supported on the shaft support bracket (20); and a gear movement guide spring (30SP) installed in the gear fixing bracket (30). Therefore, the earthquake-proof lighting lamp mounting structure can quickly and conveniently mount a lighting lamp at a desired position under a building slab.

Description

Earthquake-proof lighting implement mounting structure

The present invention relates to a structure for mounting an earthquake-resistant lighting lamp, and more particularly, to a new installation structure for an earthquake-resistant lighting lamp that is quick and easy to install and remove at a location under a slab of a building and has earthquake resistance in a state installed under a slab of a building .

BACKGROUND ART In general, lighting lamps for brightly illuminating the interior are installed on indoor ceilings, such as homes and offices, schools, government offices, and officetels, such as detached houses or apartment houses. Ceiling lighting usually consists of a lighting body mounted on the lower surface of the ceiling and having a ballast and wire connecting member built-in, and a reflector coupled to the lower part of the lighting body to evenly diffuse the light of the internal lamp. A light source (such as an LED or a lamp) is built into the lighting body, and a power unit is built into the lighting body to supply power to the light source. The power unit is built into the lighting body and may include a power circuit and a ballast connected between the light source and an external power supply, and the power supplied from the power supply is supplied to the light source through the power unit to generate light Lighting is done by doing so.

At this time, a ceiling plate (tax) is installed under the ceiling slab of a building, and the lights are attached to the bottom surface of the ceiling plate and fixed in many cases.

However, in the prior art, there is a problem in that the seismic resistance (strong earthquake resistance) is deteriorated after being installed on the ceiling plate under the ceiling slab, so that it cannot be installed stably.

In addition, conventional mounting means such as brackets for installing the lighting on the ceiling of a building are relatively complicated, and there is a problem that the unit cost of the lighting is high, and there is a problem that a lighting installation manpower or lighting installation time is required a lot.

Domestic Registered Patent No. 10-0904082 (Registered on June 15, 2009) Domestic Registered Patent No. 10-0915990 (Registered on August 31, 2009) Domestic Patent Publication No. 10-2010-0012952 (published on Feb. 09, 2010) Domestic Registered Utility Model No. 20-0464090 (Registered on 2012.12.04)

The present invention has been developed to solve the problems as described above, and an object of the present invention is to have seismic resistance in a state installed under the slab of a building, so that it is stable when installed, but also when installing under the slab of a building and when separating under the slab of a building It is intended to provide a structure for mounting an earthquake-resistant lighting lamp of a new configuration that can work quickly and easily.

According to the present invention for solving the above problems, the shaft support bracket provided at the rear of the lighting lamp installed under the slab of the building; a gear fixing bracket provided on the rear surface of the lighting lamp and disposed at a position facing the shaft fixing bracket; a shaft rotatably coupled to the shaft support bracket and the gear fixing bracket; a fixed support gear having fixed support jaws and coupled to an outer circumferential surface of the shaft so that the shaft is relatively rotatable and mounted on the gear fixing bracket; a rotary gear having a rotary support jaw meshed with the fixed support jaw of the fixed support gear and fixed to an outer circumferential surface of the shaft; and a gear engagement operation spring supported by the shaft support bracket to push the shaft with an elastic force to keep the rotation support jaws of the rotation gear engaged with the fixed support jaws of the fixed support gear; An earthquake-resistant lighting fixture mounting structure is provided.

and a gear movement guide spring provided on the gear fixing bracket to support the fixed support gear to push the rotation gear toward the rotation gear.

The gear fixing bracket is provided with a fixed support pin, the fixed support gear is slidably coupled to the fixed support pin, the fixed support gear is fixed to the gear fixing bracket by the fixed support pin, and the fixed support The fixed support gear is configured to move forward and backward based on the pin, and the gear movement guide spring urges the fixed support gear to push the rotation gear toward the rotation gear.

a wire connected to the shaft; It further comprises; a hanger bracket connected to the wire and fixed to the upper surface of the ceiling plate installed under the slab of the building, wherein the hanger bracket connects the lighting lamp with the wire connected to the shaft. It is characterized in that it supports to be fixed to the.

The hanger bracket is composed of an Embar bracket having a pair of foot bracket pieces parallel to both sides, and a pair of Embars are installed on the upper surface of the ceiling plate in parallel to the left and right, so that the pair of foot bracket pieces of the hanger bracket are one pair of foot bracket pieces. Coupled to the embar, the wire is connected to the shaft and the hanger bracket, characterized in that it supports the lighting lamp to be mounted on the lower surface of the ceiling plate.

The hanger bracket is made of a metal plate spring and installed on the upper surface of the ceiling plate, and the wire is connected to the hanger bracket made of the shaft and the plate spring to support the lighting lamp to be mounted on the lower surface of the ceiling plate. characterized in that

The shaft support bracket has a shaft coupling hole communicating with an inner end and an outer end therein, the shaft is rotatably coupled to the shaft coupling hole, and the shaft has a tool groove at one end exposed toward the shaft coupling hole. is provided, the lighting lamp has a rim portion extending upward toward the rear side, and a first rim portion facing the inner end of the shaft support bracket among the rim portion is provided with a first tool insertion hole meeting the shaft coupling hole, By inserting a tool into the first tool insertion hole of the first rim of the lighting lamp and inserting it into the tool groove formed at one end of the shaft, the shaft is rotated by the tool so that the wire is attached to the outer circumferential surface of the shaft. It is characterized in that it is configured to be wound so that the lighting lamp is in close contact with the lower surface of the ceiling plate.

The gear fixing bracket has a shaft passing hole communicating with an inner end and an outer end therein, the shaft is rotatably coupled to the shaft passing hole, the lighting lamp has a rim portion extending upwardly toward the rear side, the rim Among the parts, a second tool insertion hole meeting the shaft passage hole is provided in a second edge portion facing the inner end of the gear fixing bracket, and a tool is inserted into the second tool insertion hole of the second edge portion of the lighting lamp. By pushing the shaft so that the state in which the rotation support jaw of the rotation gear is engaged with the fixed support jaw of the fixed support gear is released, the wire is released from the outer circumferential surface of the shaft by the weight of the lighting lamp, and the lighting lamp It is characterized in that it is configured to descend downward from the lower surface of the ceiling plate.

According to the present invention, the shaft support bracket provided at the rear of the lighting installed under the slab of the building; a gear fixing bracket provided on the rear surface of the lighting lamp and disposed at a position facing the shaft fixing bracket; a shaft rotatably coupled to the shaft support bracket and the gear fixing bracket; a fixed support gear having fixed support jaws and coupled to an outer circumferential surface of the shaft so that the shaft is relatively rotatable and mounted on the gear fixing bracket; a rotary gear having a rotary support jaw meshed with the fixed support jaw of the fixed support gear and fixed to an outer circumferential surface of the shaft; a gear engagement actuation spring supported by the shaft support bracket to push the shaft with an elastic force to keep the rotation support jaw of the rotation gear engaged with the fixed support jaw of the fixed support gear; a wire connected to the shaft; a hanger bracket connected to the wire and fixed to the upper surface of the ceiling plate installed under the slab of the building, wherein the wire is wound around the outer circumferential surface of the shaft and the hanger bracket connects the lighting lamp to the shaft Supported so as to be fixed to the lower surface of the ceiling plate together with the wire, the shaft is provided with a winding guide groove in the central portion between the both ends, the winding guide groove portion the wire in the central portion of the shaft without a change in position There is provided an earthquake-resistant lighting lamp mounting structure, characterized in that it is configured to be wound.

The shaft support bracket and the gear fixing bracket are coupled to the rear center portion of the lighting lamp so that the shaft is disposed in the rear center portion of the lighting lamp, and a wire is connected to the shaft, and the wire is located under the slab of the building. It is connected to a hanger bracket fixed to the upper surface of the ceiling plate to be installed, and the wire is wound around the outer peripheral surface of the shaft so that the upper end of the lighting lamp is mounted in close contact with the lower surface of the ceiling plate, and the lighting lamp is the lower surface of the ceiling plate The left and right sides of the lighting lamp are bent toward the lower surface of the ceiling plate based on the central part of the lighting lamp before being mounted in close contact with the lighting lamp so that pretension is applied to the lighting lamp, and the lighting lamp is in close contact with the lower surface of the ceiling plate When fixed as much as possible, the entire surface of the upper end of the lighting lamp is elastically in close contact with the lower surface of the ceiling plate by the tension elastic force applied with pretension, so that the middle portion of the lighting lamp wrapped around the wire and the outside of the lighting lamp outside the wire portion It is characterized in that the side periphery is configured to prevent a phenomenon from floating on the lower surface of the ceiling plate.

The lighting lamp has a rim portion extending upwardly toward the rear side, and the rim portion is bent toward the bottom surface of the ceiling plate so that pretension is applied. The entire surface of the upper end of the edge portion of the lighting lamp is elastically in close contact with the bottom surface of the ceiling plate by the additional tension elastic force, so that the outer periphery of the central portion of the lighting lamp wrapped around the wire is prevented from lifting from the bottom surface of the ceiling plate. characterized in that it is composed.

The lighting lamp includes a pair of first reinforcing bars and a second reinforcing bar provided with a rim extending upward toward the rear surface and connected to the rim portion; a pair of first and second reinforcing frame bars connected to the support frame above the ceiling plate; a first reinforcing wire having one end connected to the shaft and coupled to the hanger bracket through the first reinforcing bar and the first reinforcing frame bar; and a second reinforcing wire having one end connected to the shaft and passing through a second reinforcing bar and the second reinforcing frame bar and coupled to the hanger bracket, and the wire and the first reinforcing wire are formed on the outer circumferential surface of the shaft and the second reinforcing wire is wound, the upper end of the lamp is mounted in contact with the lower surface of the ceiling plate, and the central portion around which the wire of the lighting lamp is wound is supported by the pulling force of the wire, and the lighting lamp deviated from the central portion of the lighting lamp The outer periphery of the is supported by the first reinforcing wire and the second reinforcing wire, so that the entire upper surface of the lighting lamp is firmly maintained in contact with the lower surface of the ceiling plate, and the central portion on which the wire of the lighting lamp is wound and It is characterized in that the outer periphery of the illuminating lamp outside the wire portion is configured to prevent lifting from the lower surface of the ceiling plate.

In the present invention, when a tool such as a screwdriver is inserted into a tool groove formed at one end of the shaft in a state in which the lighting lamp is lowered from the bottom of the building slab, and the tool is returned, the lighting lamp automatically rises to be mounted under the building slab Therefore, there is an effect that the lighting lamp can be quickly and conveniently mounted at a desired position under the building slab, and in a state where the lighting lamp is mounted at an appropriate position under the building slab, the end of the shaft where the tool groove is formed by a tool, etc. When the shaft is pushed from the end side, the rotation support jaw of the rotary gear is released from meshing with the fixed support jaw of the fixed support gear. It has the effect of being able to easily and quickly perform tasks such as replacing the lighting lamp by lowering it comfortably or repairing the lighting lamp.

In addition, in the present invention, there is no loosening phenomenon of the shaft support bracket, the gear fixing bracket, the shaft, the fixed support gear, and the rotating gear, which are the main parts due to external vibration after the installation of the lighting lamp is completed, so there is an effect that an earthquake-resistant design is possible.

1 is an exploded perspective view of a main part of a structure for mounting an earthquake-resistant lighting lamp according to the present invention;
Figure 2 is an exploded perspective view in A direction of Figure 1;
3 is a plan view of FIG. 1
4 is a perspective view of an earthquake-resistant lighting lamp mounting structure according to the present invention;
5 is a plan view of FIG. 4
Fig. 6 is an enlarged plan sectional view of the main part shown in Fig. 5;
7 is a perspective view showing a state in which the main part of the present invention shown in FIG. 4 is mounted on the rear side of the lighting lamp;
8 is an enlarged perspective view showing one end of the shaft, which is the main part shown in FIG. 7, in which a tool groove is formed;
9 is an enlarged perspective view showing the other end of the shaft which is the main part shown in FIG.
10 is a plan view showing the state before coupling the tool to the tool groove formed at one end of the shaft, which is the main part of the present invention shown in FIG.
11 is a plan view showing a state in which the tool is coupled to the tool groove formed at one end of the shaft which is the main part of the present invention shown in FIG.
12 is a state in which the fixed support jaw of the fixed support gear and the rotation support jaw of the rotating gear are engaged by inserting the tool into the second tool insertion hole formed at the other end of the lighting lamp shown in FIG. 10 and pushing the shaft; floor plan showing
13 is a perspective view showing a state in which the lighting lamp is installed on the ceiling plate under the ceiling slab by the earthquake-resistant lighting lamp mounting structure according to the present invention;
14 is a perspective view showing a state in which the lighting shown in FIG. 13 is lowered from the lower surface of the ceiling slab;
15 is a side view showing a state in which the lighting lamp is installed on the ceiling plate under the ceiling slab by the earthquake-resistant lighting lamp mounting structure according to the present invention;
16 is a side view showing a state in which the lighting shown in FIG. 15 is lowered from the lower surface of the ceiling slab;
17 is a perspective view showing a modified embodiment of a hanger bracket which is another main part of the present invention;
18 is an enlarged view showing a structure in which a drop-off prevention bolt is coupled to a gear fixing bracket, which is a main part of the present invention;
19 is a side view conceptually showing a state in which a pretension is applied to a lighting lamp mounted on a ceiling plate according to the present invention;
20 is a side view showing a state in which the lighting lamp shown in FIG. 19 is fixed to be in close contact with the lower surface of the ceiling plate;
21 is a perspective view showing a structure for mounting an earthquake-resistant lighting lamp according to another embodiment of the present invention;
22 is a perspective view showing a modified embodiment of the shaft which is the main part of the present invention;
23 is a perspective view showing a state in which a wire is wound around the outer circumferential surface of the shaft shown in FIG. 22 and the lighting lamp is installed so as to be in close contact with the lower surface of the ceiling plate;
24 is a perspective view showing a structure for mounting an earthquake-resistant lighting lamp according to another embodiment of the present invention, and is a perspective view showing a state in which the lighting lamp is descended from the lower surface of the ceiling plate;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The objects, features and advantages of the present invention will be more readily understood by referring to the accompanying drawings and the following detailed description. In the drawings, the same reference numbers are used for the same parts. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the components from other components, and the essence, order, or order of the components are not limited by the terms. When it is described that a component is “connected”, “coupled” or “connected” to another component, the component may be directly connected or connected to the other component, but between each component another component It will be understood that may also be "connected", "coupled" or "connected".

1 is an exploded perspective view of the main part of the earthquake-resistant lighting mounting structure according to the present invention, FIG. 2 is an exploded perspective view in A direction of FIG. 1, FIG. 3 is a plan view of FIG. 1, and FIG. A perspective view, Fig. 5 is a plan view of Fig. 4, Fig. 6 is an enlarged plan sectional view of the main part shown in Fig. 5, Fig. 7 is a perspective view showing a state in which the main part of the present invention shown in Fig. 4 is mounted on the rear surface of a lighting lamp, Fig. 8 is an enlarged perspective view showing one end of the shaft, which is the main part shown in FIG. 7, in which a tool groove is formed, FIG. 9 is an enlarged perspective view showing the other end of the shaft, which is the main part shown in FIG. 7, in FIG. A plan view showing the state before coupling the tool to the tool groove formed at one end of the shaft, which is the main part of the present invention, FIG. 11 is a tool in the tool groove formed at one end of the shaft which is the main part of the present invention shown in FIG. A plan view showing a coupled state, FIG. 12 is the fixed support jaw of the fixed support gear and the rotation support jaw of the rotating gear by inserting a tool into the second tool insertion hole formed at the other end of the lighting lamp shown in FIG. 10 and pushing the shaft 13 is a perspective view showing a state in which the lighting lamp is installed on the ceiling plate under the ceiling slab by the earthquake-resistant lighting lamp mounting structure according to the present invention, and FIG. 14 is the lighting lamp shown in FIG. A perspective view showing a state of being lowered from the lower surface of the ceiling slab, Figure 15 is a side view showing a state in which the lighting lamp is installed on the ceiling plate under the ceiling slab by the earthquake-resistant lighting lamp mounting structure according to the present invention, Figure 16 is Figure A side view showing a state in which the lighting lamp shown in Fig. 15 is lowered from the lower surface of the ceiling slab, Fig. 17 is a perspective view showing a modified embodiment of a hanger bracket which is another main part of the present invention, Fig. 18 is a gear which is a main part of the present invention An enlarged view showing a structure in which a drop-off prevention bolt is coupled to a fixing bracket. A side view, FIG. 20 is a side view showing a state in which the lighting lamp shown in FIG. 19 is fixed to be in close contact with the lower surface of the ceiling plate, FIG. 21 is a perspective view showing a structure for mounting an earthquake-resistant lighting lamp according to another embodiment of the present invention, FIG. 22 is A perspective view showing a modified embodiment of the shaft, which is a main part of the present invention, FIG. 23 is a perspective view showing a state in which a wire is wound around the outer circumferential surface of the shaft shown in FIG. 22 and the lighting lamp is installed so as to be in close contact with the lower surface of the ceiling plate; It is a perspective view showing a structure for mounting an earthquake-resistant lighting lamp according to another embodiment of the present invention, and is a perspective view showing a state in which the lighting lamp is descended from the lower surface of the ceiling plate.

Referring to the drawings, the seismic lighting lamp mounting structure of the present invention is provided on the rear surface of the lighting lamp 10 and disposed at a position facing each other a shaft support bracket 20, a gear fixing bracket 30, and the shaft support bracket 20 ) and the shaft 40 rotatably coupled to the gear fixing bracket 30, the rotation gear 60 coupled to the shaft 40, the fixed support gear 50 coupled to the gear fixing bracket 30, and a gear engagement actuation spring 70 coupled to the shaft 40 .

The shaft support bracket 20 is configured in a block shape. The shaft support bracket 20 is configured in a square block shape. The shaft support bracket 20 is provided with a locking piece 26 protruding downward at the inner end. The shaft support bracket 20 is provided with a shaft coupling hole 22 communicating with an inner end and an outer end therein. The shaft coupling hole 22 has a circular hole shape. The shaft support bracket 20 is provided with a bolt insertion hole 24 . The bolt insertion hole 24 is provided with a bolt insertion hole 24 communicating from the upper surface to the lower surface of the shaft support bracket 20 . By tightening the bolt inserted into the bolt insertion hole 24 to the frame 12 of the lighting lamp 10 , the shaft support bracket 20 is installed on the rear surface of the lighting lamp 10 . A shaft support bracket 20 is fixed behind the rear plate of the lighting lamp 10 . At this time, since the locking piece 26 protruding downward from the inner end of the shaft support bracket 20 comes into contact with the inner surface of the edge frame 12 of the lighting lamp 10 and is caught, look at the shaft support bracket 20 . It can be stably mounted on the rear of the lighting lamp 10 . Even after the shaft support bracket 20 is mounted on the rear surface of the lighting lamp 10, the locking piece 26 supports the shaft support bracket 20 on the edge frame 12 of the lighting lamp 10, so that the support support bracket is attached to the lighting lamp ( Even after being mounted on the rear side of 10), it can be more stably mounted to the lighting lamp 10 without shaking.

The gear fixing bracket 30 is provided on the rear surface of the lighting lamp 10 and is disposed at a position facing the shaft support bracket 20 . The gear fixing bracket 30 is provided with a gear support-side locking piece 36 protruding downward from the inner end. The gear fixing bracket 30 is provided with a shaft passing hole 32 communicating with an inner end and an outer end therein. The shaft through hole 32 has a circular hole shape. At this time, the shaft passage hole 32 is provided with a large-diameter shaft passage hole 32A and a small-diameter shaft passage hole 32B, and is inside the boundary between the large-diameter shaft passage hole 32A and the small-diameter shaft passage hole 32B. A step portion 38 is provided. The diameter of the inner step 38 is the same as the diameter of the shaft 40 . The gear fixing bracket 30 is provided with a bolt insertion hole 24 communicating from the upper surface to the lower surface, and by tightening the bolt inserted into the bolt insertion hole 24 to the rim frame 12 of the lighting lamp 10, the The gear fixing bracket 30 is installed on the rear side of the lighting lamp 10 and is disposed at a position facing the shaft support bracket 20 at the same time. A gear fixing bracket 30 is fixed to the rear of the rear plate of the lighting lamp 10 . At this time, since the gear support-side locking piece 36 protruding downward from the inner end of the gear fixing bracket 30 comes into contact with the inner surface of the rim frame 12 of the lighting lamp 10 and is caught, the gear fixing bracket 30 can be mounted on the rear side of the lighting lamp 10 more stably. Even after the gear fixing bracket 30 is mounted on the rear surface of the lighting lamp 10, the gear support side locking piece 36 supports the gear fixing bracket 30 on the edge frame 12 of the lighting lamp 10, so the gear fixing bracket ( Even after the 30) is mounted on the rear side of the lighting lamp 10, it can be more stably mounted on the lighting lamp 10 without shaking.

In addition, a support pin 39 is provided in the large-diameter shaft passage hole 32A of the gear fixing bracket 30 , and a part of the support pin 39 is formed in the internal stepped portion 38 of the gear fixing bracket 30 . ) is inserted into and coupled to the pinhole 54 extending to a certain depth toward the outer end. A portion of the two support pins 39 is entered at a certain depth inward from the inner stepped portion 38 of the gear fixing bracket 30, and the rest of the support pins 39 come forward from the inner stepped portion 38, and the It has a structure that enters the large diameter shaft through hole (32A).

The gear fixing bracket 30 is provided with a gear movement guide spring 30SP. The gear movement guide spring 30SP is built into the large-diameter shaft through hole 32A of the gear fixing bracket 30 . A gear movement guide spring 30SP is disposed between the two support pins 39 . Both ends of the gear movement guide spring 30SP are in contact with the inner step 38 in the gear fixing bracket 30 and the inner end of the rotation gear 60 coupled to the shaft 40 . The gear movement guide spring 30SP applies an elastic force for pushing the fixed support gear 50 toward the rotation gear 60 .

The shaft 40 is rotatably coupled to the shaft support bracket 20 and the gear fixing bracket 30 . An outer peripheral surface adjacent to one end of the shaft 40 is rotatably coupled to the shaft support bracket 20 , and an outer peripheral surface adjacent to the other end of the shaft 40 is rotatably coupled to the gear fixing bracket 30 . The outer circumferential surface adjacent to one end of the shaft 40 is rotatably coupled to the shaft coupling hole 22 provided inside the shaft support bracket 20 , and the outer circumferential surface adjacent to the other end of the shaft 40 is the gear fixing bracket (30) is rotatably coupled to the shaft through hole (32). The outer peripheral surface adjacent to the other end of the shaft 40 is rotatably coupled to the small-diameter shaft passage hole 32B inside the gear fixing bracket 30 . The shaft 40 is configured to be rotatable above the rear plate of the lighting lamp 10 .

The fixed support gear 50 is mounted on the gear fixing bracket 30 . A portion adjacent to the outer end of the fixed support gear 50 is coupled to the large-diameter shaft through hole 32A formed inside the gear fixing bracket 30 . The large diameter shaft passing hole 32A has a circular hole shape, and the fixed support gear 50 has a circular block shape. The fixed support gear 50 is provided with a plurality of fixed support jaws 52 at the inner end. A plurality of fixed support jaws 52 are provided in plurality at the inner end of the fixed support gear 50 along the circumferential direction. The fixed support gear 50 has a plurality of fixed support jaws 52 , and is coupled to the outer peripheral surface of the shaft 40 so that the shaft 40 is relatively rotatable and has a structure mounted on the gear fixing bracket 30 .

The rotary gear 60 has rotary support jaws 62 meshed with the fixed support jaws 52 of the fixed support gear 50 and is fixed to the outer peripheral surface of the shaft 40 . A shaft 40 hole on the rotation gear 60 side communicating on both sides is provided inside the rotation gear 60 , so that the shaft 40 hole on the rotation gear 60 side is connected to the other end of the shaft 40 . It is inserted and fixed to the adjacent outer circumferential surface. A fixing bolt coupling hole communicating with an inner circumferential surface and an outer circumferential surface is provided inside the rotary gear 60, and the fixing bolt coupled to the fixing bolt coupling hole is pressed against the outer circumferential surface of the shaft 40, so that the rotary gear 60 has a structure fixed to the shaft 40 . The rotation gear 60 has a circular block shape. A plurality of rotation support jaws 62 are provided at the inner end of the rotation gear 60 along the circumferential direction.

A spring stopper 42 is provided on an outer peripheral surface close to one end of the shaft 40 . The spring stopper 42 is provided with a shaft 40 hole communicating on both sides therein, and the shaft 40 hole is inserted into the outer circumferential surface of the shaft 40 . The spring stopper 42 is provided with a fixing bolt coupling hole communicating from the outer circumferential surface to the inner circumferential surface, and the fixing bolt is pressed against the outer circumferential surface of the shaft 40 in a state in which the fixing bolt is coupled to the fixing bolt coupling hole, so that the shaft The spring stopper 42 is configured to be fixed to the outer circumferential surface of the 40 .

A gear engagement actuation spring 70 is coupled to an outer circumferential surface adjacent to one end of the shaft 40 . At this time, one end of the shaft 40 and an adjacent washer are coupled. A washer is interposed between the inner end of the gear-engaging actuating spring 70 and the outer end of the spring stopper 42 , and the inner end of the gear-engaging actuating spring 70 is in contact with the washer. By contacting the outer end of the gear engagement operation spring 70 with the inner end of the shaft support bracket 20, the gear engagement operation spring 70 is supported on the shaft support bracket 20, and the gear engagement operation spring ( 70 pushes the shaft 40 with an elastic force to keep the rotation support jaws 62 of the rotation gear 60 engaged with the fixed support jaws 52 of the fixed support gear 50 . The gear engagement actuation spring 70 is supported by the shaft support bracket 20 to push the shaft 40 with an elastic force so that the rotation support jaw 62 of the rotation gear 60 is the fixed support jaw of the fixed support gear 50 . (52) to keep it engaged. In other words, the gear engagement operation spring 70 is interposed between the shaft support bracket 20 and the spring stopper 42 to have a structure supported by the shaft support bracket 20, and the gear engagement operation spring 70 is By pushing the shaft 40 with an elastic force, the rotational support jaws 62 of the rotational gear 60 are kept engaged with the fixed support jaws 52 of the fixed support gear 50 . Of course, even in a state in which the gear coupling actuating spring 70 is pushing toward the fixed support gear 50 with an elastic force, the shaft 40 is not removed from the shaft support bracket 20 and is a shaft inside the shaft support bracket 20 . The coupling hole 22 is maintained in an inserted state.

A fixed support pin 39 is provided on the gear fixing bracket 30 , and a fixed support gear 50 is slidably coupled to the fixed support pin 39 , and is fixed and supported by the fixed support pin 39 . The gear 50 is fixed to the gear fixing bracket 30, the fixed support gear 50 is configured to operate forward and backward based on the fixed support pin 39, and the gear movement guide spring 30SP is fixed and supported The gear 50 is supported so as to be pushed toward the rotation gear 60 .

A pinhole 54 communicating with the outer end is provided inside the fixed support gear 50 , and since the pinhole 54 is slidably inserted into the fixed support pin 39 , the fixed support gear 50 is fixed It can slide along the support pin 39 , whereby the fixed support gear 50 can be operated forward and backward at the inner end of the gear fixing bracket 30 . Of course, the gear movement guide spring 30SP supports the fixed support gear 50 to push it toward the rotation gear 60 while supporting the fixed support gear 50 with an elastic force at the outer end thereof.

The present invention further includes a wire 80 connected to the shaft 40, and a hanger bracket 90 connected to the wire 80 and fixed to the upper surface of the ceiling plate 3 installed under the slab of the building. .

The hanger bracket 90 supports the lighting lamp 10 to be fixed to the lower surface of the ceiling plate 3 together with the wire 80 connected to the shaft 40 . A wire coupling hole is provided in a central portion between both ends of the shaft 40, and a wire 80 is coupled to and connected to the wire coupling hole, and the hanger bracket 90 is provided with a bracket-side wire coupling hole. The wire 80 is inserted and coupled to the bracket-side wire coupling hole.

The hanger bracket 90 is composed of an embar bracket having a pair of foot bracket pieces 92 side by side on both sides. A bracket-side wire coupling hole is formed in the central portion between a pair of foot bracket pieces 92 of the hanger bracket 90, and the upper end of the wire 80 is coupled and fixed to the bracket-side wire coupling hole, and the shaft The lower end of the wire 80 is coupled and fixed to the wire coupling hole of (40).

On the upper surface of the ceiling plate 3, a pair of embars 94 are installed in parallel to the left and right. A pair of foot bracket pieces 92 of the hanger bracket 90 are coupled to a pair of embers 94 . Embar 94 is provided with a coupling hole communicating with the upper surface therein, so that the pair of foot bracket pieces 92 of the hanger bracket 90 are inserted into the coupling hole of the pair of embars 94, the hanger bracket A pair of foot bracket pieces 92 of (90) take a structure coupled to a pair of embers (94). Embar 94 may be called a support frame 94 installed spaced apart under the slab of the building.

The wire 80 is connected to the shaft 40 and the hanger bracket 90 to support the lighting lamp 10 to be mounted on the lower surface of the ceiling plate 3 . The hanger bracket 90 is supported on the upper surface of the ceiling plate 3 (tax or gypsum board) under the slab of the building, and the wire 80 is mounted on the back of the hanger bracket 90 and the lighting lamp 10 . Since they are respectively connected to the shaft 40 , the lighting lamp 10 is supported to be mounted on the lower surface of the ceiling plate 3 . The hanger bracket 90 and the wire 80 support the lighting lamp 10 to be hung under the ceiling plate 3 under the building slab, and when the wire 80 is wound around the outer circumferential surface of the shaft 40, the hanger bracket (90) and a wire (80) to support the lighting lamp (10) to be installed in close contact with the lower surface of the ceiling plate (3) under the building slab, and when the wire (80) is released from the shaft (40), the lighting lamp (10) In a state suspended by the wire 80 , it is supported so as to come down from the lower surface of the ceiling plate 3 .

On the other hand, in the present invention, the hanger bracket 90 may be composed of a plate spring made of metal. When the hanger bracket 90 is made of a metal plate spring, the hanger bracket 90 is installed on the upper surface of the ceiling plate 3, and the wire 80 is a hanger bracket 90 made of a shaft 40 and a plate spring. It is connected to the illuminating lamp 10 is supported so as to be mounted on the lower surface of the ceiling plate (3).

The shaft support bracket 20 is provided with a shaft coupling hole 22 communicating with an inner end and an outer end therein, the shaft 40 is rotatably coupled to the shaft coupling hole 22, and the shaft ( 40 is provided with a tool groove 44 at one end exposed toward the shaft coupling hole 22 . The shaft coupling hole 22 communicates with the inner end and the outer end of the shaft support bracket 20 , and the shaft 40 is rotatably coupled to the shaft coupling hole 22 inside the shaft 40 bracket. It is configured such that the tool groove 44 is provided at one end exposed as a step. The tool groove 44 is composed of a cross-shaped or straight-shaped driver groove or a ranch groove, and the shaft 40 is driven by the rotation of the driver by inserting a Phillips screwdriver or a flat-head screwdriver into the tool groove 44. Rotate the support bracket and the gear fixing bracket 30 as a reference, or insert a wrench into the tool groove 44 and turn the wrench to rotate the shaft 40 based on the shaft support bracket 20 and the gear fixing bracket 30 can be rotated to

In addition, the illuminating lamp 10 has a rim portion 14 extending upward toward the rear side. The edge portion 14 includes first and second edge portions 14A and 14A connected in a rectangular frame shape, and a pair of left and right side edge portions 14C.

A first tool insertion hole 14AH that meets the shaft coupling hole 22 formed in the shaft support bracket 20 in the first edge portion 14A facing the inner end of the shaft support bracket 20 in the edge portion 14 . ) is provided, and inserting the tool 1 into the first tool insertion hole 14AH of the first edge portion 14A of the lighting lamp 10 (inserting the tool 1 such as a screwdriver) to the shaft 40 In a state where a tool 1 such as a screwdriver is inserted into the tool groove 44 formed at one end of the By winding it up, the lighting lamp 10 can be brought into close contact with the lower surface of the ceiling plate 3 .

In addition, the gear fixing bracket 30 has a shaft passing hole 32 communicating with the inner end and the outer end therein, and the shaft 40 is rotatably coupled to the shaft passing hole 32 , the lighting lamp (10) is provided with a rim portion 14 extending upward toward the rear side, the shaft passage hole (32) in the second rim portion (14B) facing the inner end of the gear fixing bracket (30) of the rim portion (14) A second tool insertion hole 14BH that meets the

By inserting the tool 1 into the second tool insertion hole 14BH of the second edge portion 14B of the lighting lamp 10 and pushing the shaft 40, the rotation support jaw 62 of the rotation gear 60 is fixed. The state engaged with the fixed support jaws 52 of the support gear 50 is released, and at the same time, the gear movement guide spring 30SP is compressed to elastically push the fixed support gear 50 toward the rotation gear 60. , The plurality of rotation support jaws 62 of the rotation gear 60 step by step over the plurality of fixed support jaws 52 of the fixed support gear 50 due to the elastic force acting from the gear movement guide spring 30SP. Since the wire 80 is released from the outer circumferential surface of the shaft 40 by the weight of the lighting lamp 10 , the lighting lamp 10 can be lowered from the lower surface of the ceiling plate 3 . When the shaft 40 is pushed by inserting a tool 1 such as a screwdriver into the second tool insertion hole 14BH of the second edge portion 14B of the lighting lamp 10, the rotation gear 60 is pushed out. Since the rotational support jaw 62 is engaged with the fixed support jaw 52 of the fixed support gear 50 is released, the wire 80 is moved from the outer circumferential surface of the shaft 40 by the weight of the lighting lamp 10 . As it is released, the lighting lamp 10 can be lowered from the lower surface of the ceiling plate 3 .

At this time, one side of the rotary support jaw 62 is composed of a fixed support surface 62A parallel to the path connecting the inner end and the outer end of the rotary gear 60, and the other side of the rotary support jaw 62 is rotated It is composed of a release guide surface 62B inclined at a certain angle with respect to the direction parallel to the path connecting the inner end and the outer end of the gear (60).

If the rotation direction of the shaft 40 and the rotation direction of the rotation gear 60 are the first rotation directions for winding the wire 80 on the outer circumferential surface of the shaft 40, one side of the rotation support jaw 62 is rotated It is composed of a fixed support surface 62A along a path parallel to the direction of the inner end and the outer end of the gear 60, so that the rotation direction of the shaft 40 and the rotation direction of the rotation gear 60 are rotated in the first rotation direction While the fixed support surface 62A of the rotation support jaw 62 is kept engaged with the fixed support jaw 52 of the fixed support gear 50, the wire 80 on the outer circumferential surface of the shaft 40 is It is wound, and as the wire 80 is wound around the outer circumferential surface of the shaft 40, the lighting lamp 10 rises and is mounted in close contact with the lower surface of the ceiling plate 3 (tax or gypsum board) under the building slab.

On the other hand, if the rotation direction of the shaft 40 and the rotation direction of the rotation gear 60 are the second rotation direction to release the wire 80 from the outer circumferential surface of the shaft 40 , the other side of the rotation support jaw 62 . The side surface is composed of a release guide surface 62B inclined at a certain angle with respect to the direction parallel to the direction along the path in the direction of the inner end and the outer end of the rotation gear 60, so that the rotation direction of the shaft 40 and the rotation gear ( As the rotation direction of 60 rotates in the second rotation direction, the release guide surface 62B of the rotation support jaw 62 slips on the fixed support jaw 52 of the fixed support gear 50 while at the same time the fixed support gear (50) is pushed toward the gear movement guide spring (30SP), the gear movement guide spring (30SP) is compressed to hold the elastic restoring force.

Accordingly, while the release guide surface 62B of the rotation support jaw 62 of the rotation gear 60 is elastically in close contact with the fixed support jaw 52 of the fixed support gear 50 and slips at the same time, the rotation gear 60 ) while the plurality of rotation support jaws 62 of the fixed support gear 50 ride over the plurality of fixed support jaws 52 of the fixed support gear 50 step by step, the rotation gear 60 and the shaft 40 rotate in the second rotation direction. Because the wire 80 is released from the outer circumferential surface of the shaft 40, the lighting lamp 10 can be lowered from the ceiling plate 3 under the building slab.

In the present invention, the gear movement guide spring (30SP) functions to enter and exit the fixing support gear when the rotation gear 60 and the shaft 40 rotate, and the gear engagement operation spring 70 is the fixed support gear ( When the shaft 40 is pushed at the opposite end (ie, the end opposite to the end in which the tool groove 44 is formed in the shaft 40) to separate the rotation gear 60 from 50), it is compressed while retaining elastic restoring force, Then, when releasing the force pushing the end opposite to the end on which the tool groove 44 is formed in the shaft 40, the shaft 40 and the rotary gear 60 are automatically returned to their original positions to return the rotary gear 60. It functions to return the plurality of rotation support jaws 62 of the fixed support gear 50 to be engaged with the plurality of fixed support jaws 52 .

The lighting lamp 10 is mainly installed so as to be in close contact with the lower surface of the ceiling plate 3 (tax or gypsum board, etc.) under the slab of the building. The process is explained as follows. For convenience, in a state in which the lighting 10 is attached to the lower surface of the ceiling plate 3, the lighting 10 is lowered below the lower surface of the ceiling plate 3, and the lighting 10 is removed from the ceiling plate 3 The process of attaching it back to the lower surface of the

In the state in which the lighting lamp 10 is mounted, a wire 80 is wound around the outer circumferential surface of the shaft 40, and the wire 80 is connected to the hanger bracket 90 provided above the upper surface of the ceiling plate 3, The plurality of rotation support gears of the rotation gear 60 are meshed with the plurality of fixed support gears 50 of the fixed support gear 50 so that the lighting lamp 10 is mounted in close contact with the lower surface of the ceiling plate 3 . remain in state

In the state in which the lighting lamp 10 is mounted, the tool 1 is inserted into the second tool insertion hole 14BH in the second frame of the lighting lamp 10 to push the shaft 40 . Then, the state in which the rotation support jaw 62 of the rotation gear 60 is engaged with the fixed support jaw 52 of the fixed support gear 50 is released, and at the same time, the gear movement guide spring 30SP is compressed and the fixed support gear (50) is elastically pushed toward the rotation gear 60, the plurality of rotation support jaws 62 of the rotation gear 60 are fixed support gear 50 due to the elastic force acting from the gear movement guide spring 30SP. ), because the wire 80 is released from the outer circumferential surface of the shaft 40 by the weight of the lighting lamp 10, the lighting lamp 10 is removed from the ceiling plate 3 because the plurality of fixed support jaws 52 of It can be lowered from the bottom of the When the shaft 40 is pushed by inserting a tool 1 such as a screwdriver into the second tool insertion hole 14BH of the second edge portion 14B of the lighting lamp 10, the rotation gear 60 is pushed out. Since the rotational support jaw 62 is engaged with the fixed support jaw 52 of the fixed support gear 50 is released, the wire 80 is moved from the outer circumferential surface of the shaft 40 by the weight of the lighting lamp 10 . As it is released, the lighting lamp 10 can be lowered from the lower surface of the ceiling plate 3 .

While the release guide surface 62B of the rotation support jaw 62 of the rotation gear 60 is elastically closely contacted with the fixed support jaw 52 of the fixed support gear 50 and slips at the same time of the rotation gear 60 As the plurality of rotation support jaws 62 ride over the plurality of fixed support jaws 52 of the fixed support gear 50 in stages, the rotation gear 60 and the shaft 40 rotate in the second rotation direction. As the wire 80 is released from the outer circumferential surface of the shaft 40, the lighting lamp 10 can be lowered from the ceiling plate 3 under the building slab.

In a state in which the lighting lamp 10 is descending from the lower surface of the ceiling plate 3, the shaft 40 is pressed from the second tool insertion hole 14BH side of the second edge frame 12 of the lighting lamp 10. When the force (force to be pressed by the tool 1 such as a screwdriver) is released, the gear engagement actuation spring 70 expands again in a compressed state, and holds the shaft 40 and the rotating gear 60 as the fixed supporting gear. By pushing back toward (50) to re-engage the plurality of rotation support gears of the rotation gear 60 with the plurality of fixed support gears 50 of the fixed support gear 50, the lighting lamp 10 is installed on the ceiling plate 3 You can maintain the state that you have descended the desired distance from the bottom to the bottom.

In a state where the lighting lamp 10 is lowered to the lower surface of the ceiling plate 3, a tool 1 such as a screwdriver is inserted into the first tool insertion hole 14AH of the first edge portion 14A of the lighting lamp 10. By inserting the tool 1 such as a screwdriver into the tool groove 44 formed at one end of the shaft 40 by turning the tool 1 to turn the shaft 40, the wire 80 is connected to the shaft. It is wound around the outer peripheral surface of (40) so that the lighting lamp (10) can be brought into close contact with the lower surface of the ceiling plate (3).

If the rotation direction of the shaft 40 and the rotation direction of the rotation gear 60 are the first rotation directions for winding the wire 80 on the outer circumferential surface of the shaft 40, one side of the rotation support jaw 62 is rotated It is composed of a fixed support surface 62A along a path parallel to the direction of the inner end and the outer end of the gear 60, so that the rotation direction of the shaft 40 and the rotation direction of the rotation gear 60 are rotated in the first rotation direction While the fixed support surface 62A of the rotation support jaw 62 is kept engaged with the fixed support jaw 52 of the fixed support gear 50, the wire 80 on the outer circumferential surface of the shaft 40 is It is wound, and as the wire 80 is wound around the outer circumferential surface of the shaft 40, the lighting lamp 10 rises and is mounted in close contact with the lower surface of the ceiling plate 3 (tax or gypsum board) under the building slab.

In a state in which the lighting lamp 10 is mounted in close contact with the lower surface of the ceiling plate 3, the shaft 40 is driven from the first tool insertion hole 14AH side of the first edge frame 12 of the lighting lamp 10, such as a screwdriver, etc. If no rotational force is applied to the tool 1 of As the plurality of rotation support gears of the rotation gear 60 are engaged again with the plurality of fixed support gears 50 of the fixed support gear 50 , the lighting lamp 10 is in close contact with the lower surface of the ceiling plate 3 . and can remain installed.

Therefore, the present invention is a state in which the lighting 10 is down from the bottom of the building slab (mainly, the lighting 10 is a state in which the lighting 10 is down from the lower surface of the ceiling plate 3 under the building slab, but for convenience, in the building slab It is formed at one end of the shaft 40 by passing a tool 1 such as a screwdriver through the first tool insertion hole 14AH of the first edge portion 14A of the lighting lamp 10 in the state of being lowered) When the tool 1 such as a screwdriver is inserted into the tool groove 44 and the tool 1 is returned, the lighting lamp 10 automatically rises and is mounted under the building slab (mainly, the ceiling under the building slab). Since the lighting lamp 10 is mounted on the lower surface of the plate 3 by rising, but for convenience, it is referred to as being mounted under the building slab), so that the lighting 10 can be mounted quickly and conveniently at a desired location under the building slab. have.

In addition, in the state where the lighting lamp 10 is mounted at an appropriate position under the building slab, the tool 1 is inserted into the second tool insertion hole 14BH in the second frame of the lighting lamp 10 in the state in which the lighting lamp 10 is mounted. is inserted to push the shaft 40 . Then, the state in which the rotation support jaw 62 of the rotation gear 60 is engaged with the fixed support jaw 52 of the fixed support gear 50 is released, so that the lighting lamp 10 can be quickly moved to the desired position under the slab of the building. And it can be conveniently taken down, and it is possible to quickly and easily lower the lighting 10 , such as replacing the lighting 10 or repairing the lighting 10 , more easily and quickly.

At this time, when the shaft 40 is pushed by inserting the tool 1 into the second tool insertion hole 14BH in the second frame of the lighting 10 in the state in which the lighting 10 is mounted, the gear movement guide spring 30SP ) is compressed and elastically pushes the fixed support gear 50 toward the rotary gear 60, the plurality of rotary support jaws 62 of the rotary gear 60 act on the gear movement guide spring 30SP. As the wire 80 is released from the outer peripheral surface of the shaft 40 by the weight of the lighting lamp 10, the wire 80 is released from the lighting lamp ( 10) is not abruptly lowered from the lower surface of the ceiling plate 3, but the lighting 10 is lowered step by step, so it is safer and more stable even when the lighting 10 is lowered from the building slab to a desired position.

Meanwhile, the wire 80 is wound around the outer circumferential surface of the shaft 40 and the hanger bracket 90 is fixed to the lower surface of the ceiling plate 3 together with the wire 80 connected to the shaft 40 for the lighting lamp 10 . However, the shaft 40 is provided with a winding guide groove portion 40WG in the central portion between both ends, so that the wire in the winding guide groove portion 40WG is wound on the central portion of the shaft 40 without a change in position. is composed

Therefore, when the wire 80 is wound on the outer circumferential surface of the shaft 40, the wire 80 is wound at a position pushed in the direction of both ends of the shaft 40 from the central portion (central portion) of the shaft 40. Rather, since it is wound precisely in the middle of the shaft 40 , the position of the lighting lamp 10 when the wire 80 is wound around the shaft 40 so that the lighting lamp 10 is installed in close contact with the ceiling plate 3 . Prevents the case of being in close contact with the bottom of the ceiling plate 3 (for example, when it does not fit properly with the lighting coupling hole formed in the ceiling plate 3 and the position is misaligned and is in close contact with the lower surface of the ceiling plate 3) Therefore, it is possible to install the lighting lamp 10 more stably, quickly and conveniently.

On the other hand, the gear fixing bracket 30 is provided with a drop-off prevention bolt 110 (step-out prevention bolt), and in a state in which the fixed support gear 50 is coupled to the gear fixing bracket 30 , in the gear fixing bracket 30 . prevent escape.

The fixed support gear 50 includes a large-diameter gear body portion 110A, and a small-diameter gear body portion 110B connected to the large-diameter gear body portion 110A and having an outer diameter smaller than the outer diameter of the large-diameter gear body portion. and the fixed support jaws 52 are provided at the distal end of the small-diameter gear body portion 110B, and a step portion 110ST between the large-diameter gear body portion 110A and the small-diameter gear body portion 110B. is provided, the large-diameter gear body portion (110A) is inserted into the large-diameter shaft through hole (32A) inside the gear fixing bracket (30) and coupled, the drop-off prevention bolt (110) is the gear fixing bracket (30) Since the head part 112 of the drop-off prevention bolt 110 holds the step part 110ST of the fixed support gear 50 from the front, the large diameter shaft of the gear fixing bracket 30 is coupled to the front end of the In a state in which the fixed support gear 50 is coupled to the through hole 32A, it is possible to prevent the gear fixing bracket 30 from being separated to the front end (front). That is, the fixed support gear 50 is provided with a step portion 110ST on an outer circumferential surface, and the fixed support gear 50 is coupled to the gear fixing bracket 30 in a state in which the fixed support gear 50 is coupled to the gear fixing bracket 30 . Since the head portion 112 of the drop-off prevention bolt 110 holds the step portion 110ST of the fixed support gear 50 from the front, the fixed support gear 50 is separated from the gear fixing bracket 30 . it will be prevented

In addition, in the present invention, the tension spring 122 is coupled between the wire 80 and the hanger bracket 90 so that the lighting lamp is more stably attached to the ceiling plate 3 by the tension of the tension spring 122 . It is fixed, and due to the elasticity of the tension spring 122, it has more reliably earthquake-resistant characteristics.

On the other hand, when the ceiling plate 3 is a ceiling plaster finishing material, a metal plate spring is employed as the hanger bracket 90. Even when the hanger bracket 90 is made of a plate spring, the lighting lamp is more stable by the tension of the plate spring. It is fixed to be in close contact with the ceiling plate 3, and has a stronger earthquake-resistance characteristic due to the elasticity of the leaf spring more reliably.

On the other hand, a winding guide groove 40GR is provided in a central portion between both ends of the shaft 40, and the winding guide groove 40GR is configured in a long groove shape.

Therefore, since the wire 80 is wound around the outer circumferential surface of the winding guide groove 40GR among the outer circumferential surfaces of the shaft 40, when the wire 80 is wound around the shaft 40, the wire 80 is the shaft ( 40) is prevented from being excessively displaced from the central portion between both ends and being wound, so that the lighting lamp 10 can be more reliably fixed in place without too much deviating from the desired position of the ceiling plate 3 .

On the other hand, in the present invention, the shaft support bracket 20 and the gear fixing bracket 30 are coupled to the center portion of the rear surface of the lighting lamp 10 so that the shaft 40 is disposed in the center portion of the rear surface of the lighting lamp 10 . A wire 80 is connected to the shaft 40, and the wire 80 is connected to a hanger bracket 90 fixed to the upper surface of the ceiling plate 3 installed under the slab of the building. , the wire 80 is wound around the outer circumferential surface of the shaft 40 so that the rear surface of the lighting lamp 10 is mounted in close contact with the lower surface of the ceiling plate 3 , and the lighting lamp 10 is the ceiling plate 3 ), both left and right sides of the lighting lamp 10 are bent toward the lower surface of the ceiling plate 3 based on the central portion of the lighting lamp 10 before being mounted in close contact with the lower surface of the lighting lamp 10 so that the lighting lamp 10 is pre-tensioned. When the lighting lamp 10 is fixed to be in close contact with the lower surface of the ceiling plate 3, the entire upper end surface of the lighting lamp 10 is formed by the pre-tensioned tension elastic force applied to the lower surface of the ceiling plate 3 The lower surface of the ceiling plate 3 is elastically adhered to the illuminating lamp 10 and the outer periphery of the illuminating lamp 10 outside the wire 80 and the central portion of the illuminating lamp 10 wrapped with the wire 80 . It is configured to prevent the phenomenon of lifting in the .

The lighting lamp 10 has a rim portion 14 extending upward toward the rear side, and both left and right portions of the rim portion 14 are ceilings based on the center portion of the lamp 10 in which the shaft 40 is disposed. It is configured to be bent toward the lower surface of the plate 3 (bending in the direction of arrow A in FIG. 20 ) so that pretension is applied to the edge portion 14 . The edge portion 14 of the lighting lamp 10 is bent upward (bending toward the lower surface of the ceiling plate 3) based on the central portion where the shaft 40 of the lighting lamp 10 is disposed. ) so that both side portions of the curved surface are bent upward in a convex shape, a pretension may be applied to the edge portion 14 of the lighting lamp 10, and the frame based on the central portion in which the shaft 40 of the lighting lamp 10 is disposed. Both left and right portions of the frame 12 are also bent upward in a curved shape, and the left and right side portions of the front plate and the rear plate of the lighting lamp 10 based on the central portion in which the shaft 40 of the lighting lamp 10 is disposed It may be configured such that a pretension is applied to the lighting lamp 10 by bending upward in a curved shape.

In this way, when the lighting 10 is fixed to the lower surface of the ceiling plate 3 in a state in which pretension is applied to the lighting lamp 10, the entire upper surface of the rim portion 14 of the lighting lamp 10 to which the pretension is applied is tension elastic. Thus, the phenomenon that the outer periphery of the central portion around which the wire 80 of the lighting lamp is wound is prevented from being lifted from the lower surface of the ceiling plate 3 by being elastically adhered to the lower surface of the ceiling plate 3 . Since the front plate of the lighting lamp 10 is also unfolded in a state in which pretension is applied in a curved shape, the front plate of the lighting lamp is also stretched in a straight line on the lower surface of the ceiling plate 3 and is firmly mounted under the ceiling plate 3 It can be have. Since a force is always applied to the entire upper end surface of the edge portion 14 of the lighting lamp 10 in the direction A shown in FIG. ) can always be maintained in close contact with the lower surface of the ceiling plate 3 .

The lighting lamp 10 has a rim portion 14 extending upwardly toward the rear side, and the rim portion 14 is bent toward the lower surface of the ceiling plate 3 so that pretension is applied, the lighting lamp 10 is fixed so as to be in close contact with the lower surface of the ceiling plate 3, the entire upper surface of the upper end portion of the edge portion 14 of the lighting lamp 10 by the elastic force of the tension applied to the edge portion 14 is the ceiling plate ( 3) is elastically in close contact with the lower surface of the lighting lamp 10 , and the outer periphery of the lighting lamp 10 deviated from the central portion wrapped around the wire 80 is configured to prevent lifting from the lower surface of the ceiling plate 3 .

Therefore, in a state in which the lighting lamp 10 is fixed in close contact with the lower surface of the ceiling plate 3 , the central part of the lighting lamp 10 suspended and supported by the wire 80 is always fixed in a state in close contact with the ceiling plate 3 . In addition, the left and right side portions, which are outside the center of the lighting lamp 10 , can be kept firmly attached to the lower surface of the ceiling plate 3 without lifting, and thereby the lighting lamp 10 is attached to the ceiling plate 3 . It can be made to be fixed more firmly.

On the other hand, in another embodiment of the present invention, the shaft support bracket 20 and the gear fixing bracket 30 are coupled to the center portion of the rear surface of the lighting lamp 10 so that the shaft 40 is disposed in the center portion of the rear surface of the lighting lamp 10 . and the hanger bracket 90 includes a pair of first hanger brackets 90F and second hanger brackets 90S coupled to the support frame 94 above the ceiling plate 3, and the lighting lamp (10) has a rim portion 14 extending upward toward the rear surface, and a pair of first reinforcing bars 12F and a second reinforcing bar connected to the rim portion 14 on the rear surface of the lighting lamp 10 ( 12S) is provided, and the wire 80 has one end connected to the shaft 40 and a first wire 80F coupled to the first hanger bracket 90F via the first reinforcing bar 12F; One end is connected to the shaft 40 and configured to include a second wire 80S coupled to a second hanger bracket 90S via a second reinforcing bar 12S, and on the outer circumferential surface of the shaft 40 In a state in which the first wire 80F and the second wire 80S are wound, the lighting lamp 10 is mounted to be in contact with the lower surface of the ceiling plate 3, and the first reinforcing wire 80FR and the second reinforcing wire The lighting lamp 10 is supported so as to be mounted in close contact with the lower surface of the ceiling plate 3 by the 80SR, and the middle part of the lighting lamp 10 and the outer periphery of the lighting lamp 10 are of the ceiling plate 3 . It is configured to prevent lifting from the lower surface.

At this time, the first reinforcing bar 12F is provided with a pulley 12GRF, and the second reinforcing bar 12S is also provided with a pulley 12GRS, so that one end of the first wire 80F is the shaft 40 ), the first wire 80F enters under the first reinforcing bar 12F and passes through the outer circumferential surface of the pulley 12GRF and is connected to the first hanger bracket 90F, and the second wire One end of the 80S is connected to the shaft 40 so that the second wire 80S enters below the second reinforcing bar 12S and passes through the outer circumferential surface of the pulley 12GRS, and the second hanger bracket ( 90S).

According to another embodiment of the present invention, by turning the shaft 40 in one direction as described above, the first wire 80F is wound on the outer circumferential surface of the shaft 40 and the second wire 80S is also wound, so that the lighting lamp (20) is supported so as to be mounted in close contact with the lower surface of the ceiling plate (3).

At this time, while the first wire 80F is wound around the outer circumferential surface of the shaft 40, the first wire 80F passes through the outer circumferential surface of the pulley 12GRF rotatably coupled to the first reinforcing bar 12F. Therefore, the case where the first wire 80F is broken by frictional force is prevented in advance. In addition, while the second wire 80S is wound around the outer circumferential surface of the shaft 40, the second wire 80S passes through the outer circumferential surface of the pulley 12GRS rotatably coupled to the second reinforcing bar 12S. Therefore, the case where the second wire 80S is broken by frictional force is also prevented in advance.

In addition, the first wire (80F) is provided with the tension spring 122, the second wire (80S) is also provided with a tension spring 122, the first wire (80F) and the second wire (80S) Since the tension spring 122 provided in the above also has the same function as the tension spring 122 provided in the single wire 80, a redundant description thereof will be omitted.

Meanwhile, in another embodiment of the present invention, a pair of first reinforcing bars 12F and second reinforcing bars 12S provided on the rear surface of the lighting lamp 10 and connected to the rim portion 14, and the ceiling A pair of first reinforcing frame bars 3F and second reinforcing frame bars 3S connected to the support frame 94 above the plate 3, and one end connected to the shaft 40 and the first reinforcing bar A first reinforcing wire 80FR coupled to the hanger bracket 90 via (12F) and the first reinforcing frame bar 3F, and one end connected to the shaft 40 and a second reinforcing bar 12S ) and a second reinforcing wire (80SR) coupled to the hanger bracket (90) via the second reinforcing frame bar (3S) may be further included.

The first reinforcing bar 12F is provided with a pulley 12GRF, the second reinforcing bar 12S is also provided with a pulley 12GRS, and the first reinforcing frame bar 3F and the second reinforcing frame bar are provided. 3S) is also provided with pulleys 12GRS, one end of the first reinforcing wire 80FR is connected to the shaft 40 so that the first wire 80F enters below the first reinforcing bar 12F. It passes through the outer peripheral surface of the pulley 12GRF and the pulley 12GRF rotatably coupled to the first reinforcing frame bar 3F and is connected to the first hanger bracket 90F, and the second wire 80S. is connected to the shaft 40 so that the second wire 80S enters below the second reinforcing bar 12S, passes through the outer circumferential surface of the pulley 12GRS, and rotates on the second reinforcing frame bar 3S. It is configured to pass through the outer circumferential surface of the pulley 12GRS coupled thereto and to be connected to the second hanger bracket 90S.

In a state in which the wire 80, the first reinforcing wire 80FR, and the second reinforcing wire 80SR are wound on the outer circumferential surface of the shaft 40, the lighting lamp 10 is mounted in contact with the lower surface of the ceiling plate 3, , The central portion of the lighting lamp 10 around which the wire 80 is wound is supported by the pulling force of the wire 80 , and the outer periphery of the lighting lamp 10 outside the central portion of the lighting lamp 80 is first reinforced. Supported by the wire 80FR and the second reinforcing wire 80SR, the lighting lamp 10 is firmly maintained in contact with the lower surface of the ceiling plate 3, and the wire 80 of the lighting lamp 10 is maintained. It is configured to prevent a phenomenon that the outer periphery of the lighting lamp 10 outside of the central portion and the wire 80 part wrapped around it is lifted from the lower surface of the ceiling plate 3 .

By turning the shaft 40, the wire 80, the first reinforcing wire 80FR, and the second reinforcing wire 80SR are wound around the outer circumferential surface of the shaft 40, and the lighting lamp 10 is installed on the lower surface of the ceiling plate 3 It is mounted to be in close contact, and by pulling the middle part of the lighting lamp 10 by the wire 80, the central part of the lighting lamp 10 is supported so that it is firmly attached to the lower surface of the ceiling plate 3 without lifting it, as well as the first reinforcement. The wire 80FR and the second reinforcing wire 80SR always pull the left and right sides of the lighting 10, which is a position away from the center of the lighting 10, so that the left and right sides of the lighting 10 are also always on the lower surface of the ceiling plate 3 It can be supported so that it adheres firmly without lifting. The fact that the central portion around which the wire 80 of the lighting lamp 10 is wound and the outer periphery of the lighting lamp 10 out of the wire 80 portion is prevented from floating on the lower surface of the ceiling plate 3 is a lighting lamp (10) It means that the phenomenon that the entire upper end surface of the edge portion 14 of the rim portion 14 is prevented from being lifted from the lower surface of the ceiling plate 3 .

Therefore, when the lighting lamp 10 is pulled by the wire 80, the first reinforcing wire 80FR, and the second reinforcing wire 80SR and supported to be fixed to the lower surface of the ceiling plate 3, the lighting 10 is In a state in which the light 10 is suspended and supported by a wire 80 in a state in which it is fixed in close contact with the lower surface of the ceiling plate 3, not only the central part of the light 10 is always fixed in close contact with the ceiling plate 3, but also the light 10 Both the left and right parts, which are outside the center, are not lifted from the lower surface of the ceiling plate 3 by the pulling force of the first reinforcing wire 80FR and the second reinforcing wire 80SR, and can always be maintained in a tightly adhered state. , this makes it possible to more firmly fix the lighting lamp to the ceiling plate 3 .

Meanwhile, while the first reinforcing wire 80FR is wound around the outer circumferential surface of the shaft 40 , the first wire 80F is rotatably coupled to the first reinforcing bar 12F and the pulley 12GRF and the first reinforcing frame. Since it passes through the outer circumferential surface of the pulley 12GRF rotatably coupled to the bar 3F, the case where the first reinforcing wire 80FR is broken by frictional force is prevented in advance. In addition, while the second reinforcing wire 80SR is wound around the outer circumferential surface of the shaft 40, the second reinforcing wire 80SR is rotatably coupled to the second reinforcing frame bar 3S. Since it passes through, the case where the second reinforcing wire 80SR is broken due to frictional force is also prevented in advance.

In addition, the first reinforcing wire 80FR is provided with the tension spring 122 , the second reinforcing wire 80SR is also provided with a tension spring 122 , and the wire 80 is also provided with a tension spring 122 . is provided, the first reinforcing wire (80FR), the second reinforcing wire (80SR), and the tension spring 122 provided in the wire 80 also includes the tension spring 122 provided in the single wire 80 and Since they perform the same function, a redundant description thereof will be omitted.

In the above, specific embodiments of the present invention have been described above. However, the spirit and scope of the present invention is not limited to these specific embodiments, and various modifications and variations are possible within the scope that does not change the gist of the present invention. Anyone who has it will understand.

Therefore, since the embodiments described above are provided to fully inform those of ordinary skill in the art to which the present invention pertains the scope of the invention, it should be understood that they are exemplary in all respects and not limiting, The invention is only defined by the scope of the claims.

10. Lights 12. Border Frame
20. Shaft support bracket 22. Shaft coupling hole
24. Bolt insertion hole 26. Locking piece
30. Gear fixing bracket 32. Shaft through hole
32A. Large diameter shaft through hole 32B. Small diameter shaft through hole
34. Bolt insertion hole 36. Gear support side locking piece
38. Internal step 40. Shaft
42. Spring stopper 44. Tool groove
50. Fixed support gear 52. Fixed support jaw
54. Pinhole 60. Rotating Gear
62. Rotating Jigsaw 62A. fixed support surface
62B. Release guide face 70. Gear engagement actuation spring
80. Wire 90. Hanger Bracket
92. Foot Bracket Edition 94. Embar

Claims (10)

a shaft support bracket 20 provided at the rear of the lighting lamp 10 installed on the ceiling plate 3 under the slab of the building;
a gear fixing bracket 30 provided on the rear surface of the lighting lamp 10 and disposed at a position facing the shaft support bracket 20;
a shaft 40 rotatably coupled to the shaft support bracket 20 and the gear fixing bracket 30 ;
a fixed support gear 50 coupled to the outer circumferential surface of the shaft 40 to be relatively rotatable and mounted on the gear fixing bracket 30;
a fixed support jaw 52 provided on the fixed support gear 50;
a rotation gear 60 fixed to the outer circumferential surface of the shaft 40;
a rotation support jaw (62) provided in the rotation gear (60) and meshed with the fixed support jaw (52) of the fixed support gear (50);
It is supported by the shaft support bracket 20 and pushes the shaft 40 with an elastic force so that the rotation support jaw 62 of the rotation gear 60 is attached to the fixed support jaw 52 of the fixed support gear 50 . a gear engagement actuation spring 70 to keep it engaged;
A gear movement guide spring (30SP) provided in the gear fixing bracket 30 to support the fixed support gear 50 to push the rotation gear 60 toward the rotation gear 60;
A fixed support pin 39 is provided on the gear fixing bracket 30 , and the fixed support gear 50 is slidably coupled to the fixed support pin 39 , and is A fixed support gear 50 is fixed to the gear fixing bracket 30 , and the fixed support gear 50 is configured to operate forward and backward based on the fixed support pin 39 , and the gear movement guide spring 30SP ) is tanned to push the fixed support gear 50 toward the rotation gear 60,
a wire 80 connected to the shaft 40;
A hanger bracket (90) connected to the wire (80) and fixed to the upper surface of the ceiling plate (3) installed under the slab of the building;
The hanger bracket (90) supports the lighting lamp (10) to be fixed to the lower surface of the ceiling plate (3) together with the wire (80) connected to the shaft (40).
delete delete delete According to claim 1,
The hanger bracket 90 is configured to include a pair of foot bracket pieces 92 side by side on both sides. The pair of foot bracket pieces 92 of the bracket 90 are coupled to the pair of support frames 94 , and the wire 80 is connected to the shaft 40 and the hanger bracket 90 . , An earthquake-resistant lighting lamp mounting structure, characterized in that it supports the lighting lamp (10) to be mounted on the lower surface of the ceiling plate (3).
According to claim 1,
The hanger bracket 90 is made of a metal plate spring and installed on the upper surface of the ceiling plate 3 , and the wire 80 is connected to the hanger bracket 90 made of the shaft 40 and a plate spring. The earthquake-resistant lighting lamp mounting structure, characterized in that it supports the lighting lamp (10) to be mounted on the lower surface of the ceiling plate (3).
According to claim 1,
The shaft support bracket 20 is provided with a shaft coupling hole 22 communicating with an inner end and an outer end therein, the shaft 40 is rotatably coupled to the shaft coupling hole 22, and the shaft ( 40) is provided with a tool groove 44 at one end exposed toward the shaft coupling hole 22, the lighting lamp 10 is provided with a rim portion 14 extending upward toward the rear side, and the rim portion 14 ) of the first rim portion 14A facing the inner end of the shaft support bracket 20 is provided with a first tool insertion hole 14AH meeting the shaft coupling hole 22, The tool 1 is passed through the first tool insertion hole 14AH of the first edge portion 14A and inserted into the tool groove 44 formed at one end of the shaft 40. ) to rotate the shaft 40 so that the wire 80 is wound around the outer circumferential surface of the shaft 40 so that the lighting lamp 10 is in close contact with the lower surface of the ceiling plate 3, characterized in that Earthquake-resistant lighting installation structure.
According to claim 1,
The gear fixing bracket 30 has a shaft passing hole 32 communicating with an inner end and an outer end therein, and the shaft 40 is rotatably coupled to the shaft passing hole 32, and the lighting lamp ( 10) is provided with a rim portion 14 extending upwardly toward the rear side, and the shaft passage hole 32 has a second rim portion 14B facing the inner end of the gear fixing bracket 30 among the rim portion 14. ) is provided with a second tool insertion hole 14BH that meets the By pushing (40) the rotational support jaws 62 of the rotational gear 60 are released from meshing with the fixed support jaws 52 of the fixed support gear 50, the wire 80 is connected to the An earthquake-resistant lighting lamp mounting structure, characterized in that the lighting lamp (10) is lowered from the lower surface of the ceiling plate (3) while being released from the outer peripheral surface of the shaft (40) by the weight of the lighting lamp (10).
According to claim 1,
The shaft support bracket 20 and the gear fixing bracket 30 are coupled to the rear center portion of the lighting lamp 10 so that the shaft 40 is disposed in the rear center portion of the lighting lamp 10, and the shaft ( 40) is connected to a wire 80, and the wire 80 is connected to a hanger bracket 90 fixed to the upper surface of the ceiling plate 3 installed under the slab of the building, and the wire 80 is wound around the outer circumferential surface of the shaft 40 so that the lighting lamp 10 is mounted in close contact with the lower surface of the ceiling plate 3, and the lighting lamp 10 is mounted in close contact with the lower surface of the ceiling plate 3 Previously, the left and right sides of the lighting lamp 10 are bent toward the lower surface of the ceiling plate 3 based on the central part of the lighting lamp 10 so that a pretension is applied to the lighting lamp 10, and the lighting lamp ( When 10) is fixed to be in close contact with the lower surface of the ceiling plate 3, the lighting lamp 10 is elastically adhered to the lower surface of the ceiling plate 3 by the pre-tensioned tension elastic force, and the lighting lamp 10 An earthquake-resistant lighting lamp mounting structure, characterized in that the central portion around which the wire (80) is wound and the peripheral portion of the lighting lamp (10) are configured to prevent a phenomenon from floating on the lower surface of the ceiling plate (3).
According to claim 1,
The shaft support bracket 20 and the gear fixing bracket 30 are coupled to the rear center portion of the lighting lamp 10 so that the shaft 40 is disposed in the rear center portion of the lighting lamp 10,
The hanger bracket 90 includes a pair of first hanger brackets 90F and second hanger brackets 90S coupled to the support frame 94 above the ceiling plate 3,
The lighting lamp 10 is provided with a rim portion 14 extending upward toward the rear side,
A pair of first reinforcing bars (12F) and second reinforcing bars (12S) connected to the edge portion (14) are provided on the rear surface of the lighting lamp (10),
a pair of first reinforcing frame bars (3F) and second reinforcing frame bars (3S) connected to the support frame (94) above the ceiling plate (3);
a first reinforcing wire (80FR) having one end connected to the shaft (40) and coupled to the hanger bracket (90) via the first reinforcing bar (12F) and the first reinforcing frame bar (3F);
A second reinforcing wire (80SR) having one end connected to the shaft (40) and coupled to the hanger bracket (90) via a second reinforcing bar (12S) and the second reinforcing frame bar (3S); is composed by
In a state in which the wire 80, the first reinforcing wire 80FR, and the second reinforcing wire 80SR are wound on the outer circumferential surface of the shaft 40, the upper end of the lighting lamp 10 is the ceiling plate 3 is mounted in contact with the lower surface of the lighting lamp 10, and the central portion around which the wire 80 of the lighting lamp 10 is wound is supported by the pulling force of the wire 80, and the lighting lamp ( 10) the outer periphery is supported by the first reinforcing wire 80FR and the second reinforcing wire 80SR, so that the entire upper end surface of the lighting lamp 10 is firmly attached to the lower surface of the ceiling plate 3 The lower surface of the ceiling plate 3 is maintained in a contact state, so that the central portion around which the wire 80 of the lighting lamp 10 is wound and the outer periphery of the lighting lamp 10 deviated from the wire 80 portion Seismic lighting light mounting structure, characterized in that configured to prevent the lifting phenomenon in the.

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