KR20210056582A - Tube-binding apparatus for fire extinguishing - Google Patents

Abstract

A tube-binding apparatus for fire exitniguishing according to the present invention comprises: a tube position determining bracket including a first semi-elliptical plate, a second semi-elliptical plate positioned on the first semi-elliptical plate, and a square segment connecting straight edges of the first semi-elliptical plate and the second semi-elliptical plate at opposite sides of curved edges of the first and second semi-elliptical plates; a tube position adjusting shim inserted into the second semi-elliptical plate in a ring shape to expose the first semi-elliptical plate to the outside through the inside of the ring shape; and a through-fastening unit that is screwed with the tube position adjusting shim past the first semi-elliptical plate and the second semi-elliptical plate.

Description

Firefighter restraint device {TUBE-BINDING APPARATUS FOR FIRE EXTINGUISHING}

The present invention relates to a fire fighter restraint apparatus for placing a cylindrical reducer on a ceiling of a building in a fire fighting facility of a building.

In general, a center bracket is used to connect a new pipe and a sprinkler to a cylindrical reducer penetrating the ceiling of a building to position the new pipe on the upper side of the ceiling and the sprinkler on the lower side of the ceiling. It has a shape and is used to place the reducer on the ceiling by surrounding the reducer at the lower or upper side of the ceiling.

For example, in the center bracket, side brackets are fixed to both grids facing each other among square grids in a T-grid ceiling of a building with a first bolt, and a square support is made on one side of the center bracket. In the state where the bar is inserted, both ends of the square support bar are connected and fixed to the side brackets, and then a circular reducer is accommodated on the other side of the center bracket to fix the reducer around the square support bar.

Here, the center bracket has a circular insertion hole on the other side and receives the reducer through the insertion hole to penetrate the reducer through the center bracket. The reducer and the square support bar face inside the center bracket. Further, the square support bar starts from the periphery of the center bracket, passes through the center bracket, and is pushed from the center bracket toward the reducer using a second bolt contacting the square support bar to contact the reducer.

Thereafter, the reducer is connected to the expansion pipe at the upper side of the ceiling and with the sprinkler at the lower side of the ceiling while protruding from the lowermost surface of the square grid. However, since the center bracket uses a circular insertion hole to make line contact with the reducer through the insertion hole, it is necessary to hold the reducer firmly on the ceiling during the vibration related to the natural disaster of the building and the vibration related to the discharge of fire water from the sprinkler. Can't.

In addition, the center bracket serves as an intermediary for the connection between the square support bar and the reducer in the ceiling of the building, but the center bracket does not require a support structure other than the square support bar when viewed from the outside. Due to insufficient use of the structure, it is increasing the difficulty in quickly constructing a firefighting facility in the building.

Meanwhile, the center bracket is similarly disclosed as a prior art in Korean Patent Publication No. 10-1418791.

Korean Patent Publication No. 10-1418791

The present invention has been conceived to solve the conventional problem, and quickly build a firefighting facility on the ceiling by freely using a ceiling structure shape or a structure around the ceiling in order to firmly position a cylindrical reducer on the ceiling of a building. The purpose of this is to provide a fire-fighting system that is suitable to be used to control.

The fire fighting apparatus restraint apparatus according to the present invention includes a first semi-elliptic plate and a second semi-elliptic plate positioned on the first semi-elliptic plate so as to position a cylindrical reducer on the ceiling of the building in the fire fighting facility of the building. A plate, and a tube positioning bracket having a rectangular fragment connecting the straight edges of the first semi-elliptic plate and the second semi-elliptic plate on opposite sides of the curved edges of the first semi-elliptic plate and the second semi-elliptic plate; A tube position adjustment shim inserted into the second semi-elliptic plate in a ring shape to expose the first semi-elliptic plate to the outside through the ring-shaped interior; And a through-fastening unit that passes through the first semi-elliptic plate and the second semi-elliptic plate and is screwed with the pipe position adjustment shim, and the through-fastening with the pipe positioning bracket and the pipe position adjustment shim The unit surrounds the reducer, and the first semi-elliptic plate and the second semi-elliptic plate extend horizontally in a distant direction starting from the rectangular fragment to face the same shape, and the tube position adjustment shim is the second It is characterized in that it is fixed to the semi-elliptic plate.

The first semi-elliptic plate and the second semi-elliptic plate have a through hole near a curved edge of the individual semi-elliptic plate, and both edges together with a hole for exclusive use of a square pillar in a central area near a straight edge of the individual semi-elliptic plate. Has a circular column dedicated hole, the second semi-elliptic plate has the tube position adjustment shim in the through hole of the second semi-elliptic plate, the square fragment, the first semi-elliptic plate and the second Between the semi-elliptical plates, there may be a hole for exclusive use of the square pillar and a hole for exclusive use of a butterfly bolt that is opened at a right angle to the hole for exclusive use of the circular pillar.

The first semi-elliptic plate through-hole, the square pillar-only hole and the circular column-only hole face each of the through-holes of the second semi-elliptic plate, the square-pillar-only hole and the circular-pillar-only hole, and The through hole of the plate and the through hole of the second semi-elliptic plate may penetrate the reducer.

The first semi-elliptic plate and the second semi-elliptic plate have a through hole near a curved edge of the individual semi-elliptic plate, and have a plurality of position fixing grooves along a circumference of the through hole of the second semi-elliptic plate, The pipe position adjustment shim includes a cylindrical wall positioned between the first semi-elliptic plate and the second semi-elliptic plate and a circular flange positioned on the second semi-elliptic plate, and the cylindrical wall and the circular flange It is possible to penetrate the reducer.

The cylindrical wall body extends from the circumference of the through hole of the second semi-elliptic plate toward the first semi-elliptic plate, and the circular flange extends around the through hole of the second semi-elliptic plate, 2 It is in close contact with the circumference of the through hole of the semi-elliptical plate and can be crushed and fitted by pressing into the plurality of position fixing grooves.

The pipe position adjustment shim may have a female thread along the inner circumferential surface of the cylindrical wall, and may couple the female thread of the cylindrical wall to a male thread located on the outer circumferential surface of the tube receiving structure.

The through fastening unit includes an irrigation structure that penetrates the reducer while in contact with the pipe position adjustment shim, a detachable member located inside the irrigation structure to surround the reducer, and the irrigation structure And a tightening pipe positioned between the detachable member and surrounding the reducer, and the detachable member and the tightening pipe may move relative to the irrigation structure along a length direction of the reducer.

The through fastening unit comprises the irrigation structure, the detachable member, and the tightening tube as a set, and the irrigation structure in the through hole of the first semi-elliptic plate and the second semi-elliptic plate, The detachable member and the tightening tube may be inserted, and the irrigation structure may be screwed to the tube position adjusting shim.

The irrigation structure, when screwed with the pipe position adjustment shim, protrudes from the irrigation structure from the lower side of the irrigation structure to contact the first semi-elliptical plate and in close contact with the first semi-elliptic plate It has a pressure flange, and when the pipe position adjustment shim is screwed together, on the upper side of the irrigation structure, it may have a receiving pipe surrounding the detachable member and the tightening pipe.

The accommodation tube has a male thread located on the outer circumferential surface of the accommodation tube and coupled with a female thread of the tube positioning shim, and a female thread located on the inner circumferential surface of the accommodation tube and coupled with the male thread of the tightening tube. I can have it.

The detachable member has a thickness gradually thinning from the bottom of the receiving pipe toward the tightening pipe, and when viewed from the outer circumferential surface of the detachable member, it is to be cut to a predetermined width vertically along the length direction of the reducer. I can.

The detachable member, through the relative movement of the tightening pipe with respect to the receiving pipe, moves along the length direction of the reducer to reduce the cut width while gradually inside the tightening pipe when viewed from the bottom of the receiving pipe. Or moving along the length direction of the reducer to restore the cut width and gradually retreat from the inside of the tightening tube when viewed from the bottom of the receiving tube.

The tightening pipe is located inside the receiving tube on the detachable member and faces parallel to the receiving tube and is screwed with the receiving tube, and on the reducer, the detachable member and the tightening tube are inclined with respect to each other. To face each other, the thickness may be increased or decreased in a shape opposite to that of the detachable member.

The tightening pipe, when gradually entering the interior of the accommodation pipe, enables the gradual entry of the detachable member toward the inside of the tightening pipe in a pressurized state of the detachable member, so that the detachment from the bottom of the accommodation pipe is possible. When the detachable member is spaced apart and the detachable member is in close contact with the outer circumferential surface of the reducer to a face-to-face, and gradually retreats from the inside of the receiving pipe, in the loosened state of the detachable member, from the inside of the tightening pipe By enabling the gradual retreat of the detachable member, the detachable member may be in close contact with the bottom of the receiving tube and the detachable member may be spaced apart from the outer peripheral surface of the reducer.

The pipe accommodating structure includes a through hole of the first semi-elliptic plate and the pipe position adjusting shim of the second semi-elliptic plate in the reducer, and a square pillar fixed to the ceiling or ceiling structure in the building In the state where the holes for the square pillars of the first semi-elliptic plate and the second semi-elliptic plate are inserted, the first semi-elliptic plate or the second semi-elliptic plate is inserted between the first semi-elliptic plate and the second semi-elliptic plate. In order to hinder the relative vertical movement of the square pillar with respect to the semi-elliptical plate, it is possible to have a butterfly bolt that is inserted into a hole for a butterfly bolt of the square fragment and contacts the square pillar.

The pipe position adjustment shim may be spaced apart from the square pillar.

The pipe accommodating structure includes a through hole of the first semi-elliptic plate and the pipe position adjusting shim of the second semi-elliptic plate in the reducer, and a circular column fixed to the ceiling or ceiling structure in the building In a state in which the hole for the circular column of the first semi-elliptic plate and the second semi-elliptic plate is inserted, the first semi-elliptic plate or the second semi-elliptic plate is inserted between the first semi-elliptic plate and the second semi-elliptic plate. In order to hinder the relative vertical movement of the circular column with respect to the semi-elliptic plate, it is possible to have a butterfly bolt that is inserted into the hole for the butterfly bolt of the rectangular fragment and contacts the circular column.

The pipe position adjustment shim may be spaced apart from the circular column.

In the tube receiving structure, a through hole of the first semi-elliptic plate and the tube position adjusting shim of the second semi-elliptic plate are inserted into the reducer, and a square bar fixed to the ceiling or the ceiling structure in the building is provided. , The first semi-elliptic plate or the second semi-elliptic plate between the first semi-elliptic plate and the second semi-elliptic plate in a state surrounded by the first semi-elliptic plate, the second semi-elliptic plate, and the rectangular fragment In order to hinder the relative horizontal movement of the square bar with respect to the plate, a butterfly bolt may be inserted into the hole for exclusive use of the butterfly bolt of the square piece and in contact with the square bar.

The pipe position adjustment shim may be in contact with the square bar.

Fire fighting apparatus according to the present invention,

Pipe positioning bracket prepared in a'C' shape, a pipe positioning shim that fits in a donut shape at the upper free end of a'C' shape in the pipe positioning bracket, and a'C' letter in the pipe positioning bracket Through the lower free end of the shape, the through-fastening unit penetrates the pipe position adjustment shim and is screwed to the pipe position adjustment shim,

Along with a reducer that passes through the inside of the through fastening unit and makes surface contact with the through fastening unit, a square column or a circular column passing through the lower and upper free ends of the pipe positioning bracket is accommodated around the reducer, or It accommodates a square bar located between the lower free end and the upper free end,

In order to firmly position the cylindrical reducer on the ceiling of the building, firefighting facilities can be quickly installed on the ceiling by freely using the shape of the ceiling structure or structures around the ceiling based on the pipe positioning bracket and pipe positioning shims and through fastening units. Can be built up.

1 is an image showing a firefighter restraint apparatus according to embodiments of the present invention and supporters for fastening that can be adopted in the apparatus.
FIG. 2 is an image showing a pipe positioning bracket and a pipe positioning shim in the fire fighting pipe restraint device of FIG. 1.
3 is a schematic view showing the tube positioning bracket of FIG. 2.
4 is a cross-sectional view showing a coupling state of the pipe positioning bracket of FIG. 2 and the pipe positioning shim.
5 is a schematic diagram showing a through fastening unit and a reducer in the fire fighting apparatus of FIG. 1.
6 is a cross-sectional view showing a coupled state of the through fastening unit of FIG. 5 and a reducer.
FIG. 7 is an image showing a firefighter restraint apparatus according to a first embodiment of the present invention in FIG. 1 and a first fastening supporter adopted in the apparatus.
FIG. 8 is an image showing a firefighter restraint apparatus according to a second embodiment of the present invention in FIG. 1 and a second fastening supporter adopted in the apparatus.
FIG. 9 is an image showing a firefighter restraint apparatus according to a third embodiment of the present invention in FIG. 1 and a third fastening shutter adopted in the apparatus.
10 and 11 are schematic diagrams illustrating a method of manufacturing the fire fighter restraint device of FIG. 1.

For a detailed description of the present invention to be described later, reference is made to the accompanying drawings, which illustrate specific embodiments in which the present invention may be practiced. These embodiments are described in detail sufficient to enable a person skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different from each other, but need not be mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the present invention in relation to one embodiment. In addition, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the detailed description to be described below is not intended to be taken in a limiting sense, and the scope of the present invention, if appropriately described, is limited only by the appended claims, along with all ranges equivalent to those claimed by the claims. In the drawings, similar reference numerals refer to the same or similar functions over various aspects, and the length, area, thickness, and the like may be exaggerated and expressed for convenience.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to enable those of ordinary skill in the art to easily implement the present invention.

1 is an image showing a firefighter restraint device according to embodiments of the present invention and a fastening supporter that can be adopted for the device, and FIG. 2 is a pipe positioning bracket and a pipe position in the firefighter restraint device of FIG. It is an image showing an adjustment shim, and FIG. 3 is a schematic view showing the tube positioning bracket of FIG. 2.

In addition, FIG. 4 is a cross-sectional view showing the coupling state of the pipe positioning bracket of FIG. 2 and the pipe positioning shim, and FIG. 5 is a schematic view showing a through fastening unit and a reducer in the fire tube restraint device of FIG. 1, and FIG. 6 Is a cross-sectional view showing a coupled state of the through fastening unit and the reducer of FIG. 5.

1 to 6, the fire fighting apparatus 110 is configured to place a cylindrical reducer on the ceiling of a building in a fire fighting facility of a building. In more detail, the fire tube restraint device 110, as shown in Figure 1, the pipe positioning bracket 20, the pipe position adjustment shim 40, and the through fastening unit 100 Includes. The pipe positioning bracket 20, the pipe positioning shim 40, and the through fastening unit 100 surround the reducer 120.

The tube positioning bracket 20 includes a first semi-elliptic plate 13 and a second semi-elliptic plate 19 positioned on the first semi-elliptic plate 13, as shown in FIGS. 2 to 4. ), and a square connecting the straight edges of the first semi-elliptic plate 13 and the second semi-elliptic plate 19 on the opposite side of the curved edges of the first semi-elliptic plate 13 and the second semi-elliptic plate 19 It has a fragment 16.

The first semi-elliptic plate 13 and the second semi-elliptic plate 19, as shown in FIG. 2 or 3, extend horizontally in a distant direction starting from the rectangular fragment 16 and face each other in the same shape. do. The first semi-elliptic plate 13 and the second semi-elliptic plate 19 have a through hole 3 near the curved edge of the respective semi-elliptic plate 13 or 19 as shown in Fig. 2 or 3, and In the vicinity of the straight edge of the semi-elliptic plate 13 or 19, the hole 5 for exclusive use of the square pillar and the hole 7 for exclusive use of the circular pillar are provided at both edges as shown in FIG. 2.

The second semi-elliptic plate 19 has a tube position adjustment shim 40 in the through hole 3 of the second semi-elliptic plate 19. The square fragment 16 is a butterfly bolt that is opened at a right angle to the hole 5 for exclusive use of a square column and the hole 7 for exclusive use of a circular column between the first semi-elliptic plate 13 and the second semi-elliptic plate 19 It has a dedicated hole (9).

The first semi-elliptic plate 13, the through-hole 3, the square-pillar-only hole 5, and the circular-pillar-only hole 7 are the second semi-elliptic plate 19 when considering FIGS. 1 to 3 ) Of the through-hole 3 and the square pillar-only hole 5 and the circular pillar-only hole 7 face each other. The through hole 3 of the first semi-elliptic plate 13 and the through hole 3 of the second semi-elliptic plate 19 are formed by using a reducer (Fig. 1 or 7 or 120 of Fig. 8 or 9). Penetrate.

The first semi-elliptic plate 13 and the second semi-elliptic plate 19 are, as shown in Fig. 2 or 3, a through hole 3 near the curved edge of the individual semi-elliptic plate 13 or 19 And a plurality of position fixing grooves 1 along the circumference of the through hole 3 of the second semi-elliptic plate 19. The pipe position adjustment shim 40 is inserted into the second semi-elliptical plate 19 in a ring shape, and the first semi-elliptic plate 13 is externally inserted through the ring-shaped interior, as shown in FIG. 2. Expose.

The tube position adjustment shim 40 is fixed to the second semi-elliptical plate 19 as shown in FIG. 2. In more detail, the pipe position adjustment shim 40 includes a cylindrical wall (34 in Fig. 2) and a second half positioned between the first semi-elliptical plate 13 and the second semi-elliptic plate 19. Includes a circular flange 38 positioned on the elliptical plate 19, and penetrates the reducer 120 through the cylindrical wall 34 and the circular flange 38 as shown in FIG. 1 or 7 or 8 or 9 Let it.

The cylindrical wall 34 extends from the circumference of the through hole 3 of the second semi-elliptical plate 19 toward the first semi-elliptical plate 13. The circular flange 38 is stretched around the through hole 3 of the second semi-elliptical plate 19 and is in close contact with the circle of the through hole 3 of the second semi-elliptic plate 19 and has a plurality of position fixing grooves. It is pressed against (1) and crushed, and is fitted into a convex shape (36 in FIG. 2 or 4).

The convex portion shape 36 is illustrated in a circular shape in FIG. 1 or 2, but may be illustrated as an elliptical convex portion shape 37 as shown in FIGS. 7 to 9. Accordingly, the plurality of position fixing grooves 1 may be deformed from an approximately semi-circular shape in FIG. 3 to an approximately semi-elliptic shape, which is not shown.

The pipe position adjustment shim 40 has a female thread (32 in Fig. 2) along the inner circumferential surface of the cylindrical wall 34, and the outer circumferential surface of the pipe receiving structure 100 (= of the receiving pipe 68 in Fig. 6) The female thread 32 of the cylindrical wall 34 is coupled to the male thread 66 located on the outer circumferential surface).

The through fastening unit 100 passes through the first semi-elliptic plate 13 and the second semi-elliptic plate 19 and is threadedly coupled to the pipe position adjustment shim 40. The through fastening unit 100 includes a watering structure (70 in FIG. 5 or 6), a detachable member (80 in FIG. 6), and a tightening pipe (90 in FIG. 5 or 6).

The through fastening unit 100 comprises a structure for watering 70, a detachable member 80, and a tightening tube 90 as a set as shown in FIG. 5 or 6 to form a first semi-elliptic plate 13 ) And the through hole 3 of the second semi-elliptic plate 19, the irrigation structure 70, the detachable member 80, and the tightening tube 90 with FIG. 1 or 7 or 8 or 9 Inserted together and screwed the irrigation structure (70) to the pipe position adjustment shim (40).

The detachable member 80 and the tightening pipe 90 are relative to the irrigation structure 70 along the length direction of the reducer 120 along the first direction D1 and the second direction D2 of FIG. 6. Moves to. In more detail, the irrigation structure 70 penetrates the reducer 120 as shown in FIG. 5 or 6 while in contact with the pipe position adjustment shim 40.

The irrigation structure 70 protrudes from the irrigation structure 70 at the lower side of the irrigation structure 70 when the pipe position adjustment shim 40 is screwed together and the first semi-elliptic plate 13 When in contact with the first semi-elliptic plate 13 and the pressing flange 64 in close contact as shown in FIG. 7 or 8 or 9, when screwed with the pipe position adjustment shim 40, the irrigation structure 70 ) On the upper side of the detachable member 80 and the receiving tube 68 surrounding the tightening tube 90 as shown in FIG. 5 or 6.

The accommodation tube 68 has a male thread 66 that is located on the outer circumferential surface of the accommodation tube 68 and engages with the female thread 32 of the tube position adjustment shim 40, and the inner circumferential surface of the accommodation tube 68 It is located in and has a female thread 67 that engages with a male thread (not shown in the drawing) of the tightening tube 90. When considering FIGS. 5 and 6, the detachable member 80 is located inside the irrigation structure 70 and surrounds the reducer 120.

The detachable member 80 has a thickness gradually thinning from the bottom of the receiving pipe 68 toward the tightening pipe 90, and when viewed from the outer circumferential surface of the detachable member 80, the length of the reducer 120 It is cut to a predetermined width vertically along the direction.

The detachable member 80 moves along the length direction of the reducer 120 through a relative movement (D1 or D2) of the tightening tube 90 with respect to the accommodation tube 68 to reduce the cut width while reducing the incision When viewed from the bottom of (68), gradually entering the inside of the tightening pipe (90), or moving along the length direction of the reducer (120) to restore the cut width while viewed from the bottom of the receiving pipe (68) tightening pipe (90) gradually retreat from the inside.

The tightening pipe 90 is located between the irrigation structure 70 and the detachable member 80 and surrounds the reducer 120. The tightening tube 90 is located inside the receiving tube 68 on the detachable member 80 and faces parallel to the receiving tube 68 and is screwed with the receiving tube 68, and the reducer 120 Above, the thickness is increased or decreased in a shape opposite to that of the detachable member 80 so as to obliquely face the detachable member 80 and the tightening pipe 90 with respect to each other.

When the tightening pipe 90 gradually enters the interior of the receiving pipe 68 (= moves to'D1'), in a pressurized state of the detachable member 80, it is detachable toward the inside of the tightening pipe 90 The detachable member 80 is separated from the bottom of the receiving tube 68 by allowing the member 80 to gradually enter, and the detachable member 80 is in close contact with the outer circumferential surface of the reducer 120 to the face-to-face surface.

In addition, when the tightening pipe 90 is gradually retracted from the inside of the receiving pipe 68 (= moves to'D2'), in the loosened state of the detachable member 80, from the inside of the tightening pipe 90 The detachable member 80 is in close contact with the bottom of the receiving tube 68 by allowing the detachable member 80 to be gradually retracted, and the detachable member 80 is separated from the outer circumferential surface of the reducer 120.

FIG. 7 is an image showing a firefighter restraint apparatus according to a first embodiment of the present invention in FIG. 1 and a first fastening supporter adopted in the apparatus. Here, FIG. 7 will be described with reference to FIGS. 1 to 6.

Referring to FIG. 7, according to the use of the fire tube restraint device 110, the pipe accommodating structure 20 is provided with the through hole 3 of the first semi-elliptic plate 13 and the first semi-elliptic plate 13 in the reducer 120. 2 Insert the pipe position adjustment shim 40 of the semi-elliptic plate 19, and in the square pillar 140 fixed to the ceiling or ceiling structure in the building, the first semi-elliptic plate 13 and the second semi-elliptic plate In the state of inserting the hole 5 dedicated to the square column of (19), between the first semi-elliptic plate 13 and the second semi-elliptic plate 19, the first semi-elliptic plate 13 or the second semi-elliptic plate ( 19), in order to prevent the relative vertical movement of the square pillar 140, a butterfly bolt (8 in FIG. 7) in contact with the square pillar 140 is inserted into the hole 9 for exclusive use of the butterfly bolt of the square fragment 16. Have.

Here, the pipe position adjustment shim 40 is spaced apart from the square pillar 140 in the irrigation structure 20. In addition, the square pillar 140 is fixed to the ceiling or the ceiling structure through a connection end 135 positioned at one end of the square pillar 140.

FIG. 8 is an image showing a firefighter restraint apparatus according to a second embodiment of the present invention in FIG. 1 and a second fastening supporter adopted in the apparatus.

Referring to FIG. 8, according to the use of the fire fighting tube restraint device 110, the tube receiving structure 20 includes a through hole 3 of the first semi-elliptic plate 13 in the reducer 120 and Insert the pipe position adjustment shim 40 of the second semi-elliptic plate 19, and in the circular column 150 fixed to the ceiling or ceiling structure in the building, the first semi-elliptic plate 13 and the second semi-elliptic The first half-ellipse plate 13 or the second half-ellipse plate between the first half-ellipse plate 13 and the second half-ellipse plate 19 with the hole 7 for the circular column of the plate 19 inserted In order to hinder the relative vertical movement of the circular column 150 with respect to (19), it has a butterfly bolt 8 that is in contact with the circular column 150 by being inserted into the hole 9 dedicated to the butterfly bolt of the square piece 16.

Here, the pipe position adjustment shim 40 is spaced apart from the circular column 150 in the irrigation structure 20. In addition, when the circular column 150 is made of a full threaded bolt, it may be screwed with an anchor nut (not shown in the drawing) positioned on a ceiling or ceiling structure.

FIG. 9 is an image showing a firefighter restraint apparatus according to a third embodiment of the present invention in FIG. 1 and a third fastening shutter adopted in the apparatus.

Referring to FIG. 9, according to the use of the fire tube restraint device 110, the pipe accommodating structure 20 is provided with the through hole 3 of the first semi-elliptic plate 13 and the first semi-elliptic plate 13 in the reducer 120. 2 Insert the pipe position adjustment shim 40 of the semi-elliptic plate 19, and insert the square bar 160 fixed to the ceiling or ceiling structure in the building, and the first semi-elliptic plate 13 and the second semi-elliptic plate (19) and a state surrounded by a square fragment (16), between the first semi-elliptic plate (13) and the second semi-elliptic plate (19), the first semi-elliptic plate (13) or the second semi-elliptic plate (19) In order to hinder the relative horizontal movement of the square bar 160 relative to the square bar 160, a butterfly bolt 8 is inserted into the hole 9 for exclusive use of the butterfly bolt of the square piece 16 and contacts the square bar 160.

Here, the pipe position adjustment shim 40 is in contact with the square bar 160 in the irrigation structure 20.

10 and 11 are schematic diagrams illustrating a method of manufacturing the fire fighter restraint device of FIG. 1.

Referring to FIGS. 10 and 11, a first semi-elliptic plate 13, a square fragment 16, and a second semi-elliptic plate 19 may be formed on the elliptical metal plate 20A. The first semi-elliptic plate 13, the square fragment 16, and the second semi-elliptic plate 19 are partitioned on a metal plate through dimension measurement. The first semi-elliptic plate 13 and the second semi-elliptic plate 19 have a through hole 3, a hole 5 for a square column, and a hole 7 for a circular column.

In addition, the second semi-elliptic plate 19 has a plurality of grooves 1 around the through hole 3 as shown in FIG. 3. The square piece 16 has holes 9 exclusively for butterfly bolts. Next, a preliminary pipe position adjustment shim 40A may be prepared. The preliminary pipe position adjustment shim 40 may be formed in a donut shape as shown in FIG. 11.

In more detail, the preliminary pipe positioning shim 40 has a cylindrical wall 34 and a cylindrical frame 38A that are sequentially stacked. Here, the cylindrical wall 34 and the cylindrical frame 38A have a diameter gradually decreasing along the length direction of the preliminary pipe positioning shim 40 when viewed along the outer circumferential surface of the preliminary pipe positioning shim 40 And has a stepped portion 35 between the cylindrical wall 34 and the cylindrical frame 38A.

The cylindrical wall 34 has a female thread 32 of FIG. 2. Next, a preliminary pipe position adjustment shim 40 may be fitted in the through hole 3 of the second semi-elliptic plate 19 along the third direction D3 of FIG. 10. Here, the preliminary pipe position adjustment shim 40 may contact the stepped portion 35 between the cylindrical wall 34 and the cylindrical frame 38A under the second semi-elliptic plate 19.

The cylindrical frame 38A may protrude from the second semi-elliptic plate 19. Next, after an external force is applied to the second semi-elliptic plate 19 and the cylindrical frame 38A in a fourth direction (D4 in Fig. 11), the cylindrical frame 38A is a second semi-elliptic plate 19 It can be transformed into a circular flange (38 in Fig. 2) on top. The circular flange 38 is in close contact with the second semi-elliptic plate 19 around the through hole 3 of the second semi-elliptic plate 19.

The cylindrical wall 34 and the circular flange 38 constitute a pipe position adjustment shim 40 as shown in FIG. 2. Subsequently, the elliptical metal plate 20A is folded as shown in FIG. 11 along the boundary line between the first semi-elliptic plate 13, the rectangular fragment 16, and the second semi-elliptic plate 19, so that the tube positioning bracket 20 ) Can be transformed.

Subsequently, the through fastening unit 100 may be fitted to the pipe positioning bracket 20 and the pipe positioning shim 40 as shown in FIG. 1 or 7 or 8 or 9. The pipe positioning bracket 20, the pipe positioning shim 40, and the through fastening unit 100 constitute a fire fighting pipe restraint device 110.

In addition, the square pillar 140 or the circular pillar 150 is inserted into the hole 5 or the circular pillar 7 of the tube positioning bracket 20 as shown in FIGS. 7 or 8, or A square bar 160 may be fitted into the tube positioning bracket 20 as shown in FIG. 9.

8; Butterfly bolt, 20; Pipe positioning bracket
40; Pipe positioning shims, 100; Through fastening unit
110; Firefighter restraint device, 120; Reducer
140; Square column, 150; Circle pillar
160; Square bar

Claims (20)

In the fire fighting system for placing a cylindrical reducer on the ceiling of the building in a fire fighting facility of a building,
A first semi-elliptic plate, a second semi-elliptic plate positioned on the first semi-elliptic plate, and the first semi-elliptic plate on the opposite side of the curved edge of the first semi-elliptic plate and the second semi-elliptic plate And a tube positioning bracket having a rectangular segment connecting the straight edge of the second semi-elliptical plate;
A tube position adjustment shim inserted into the second semi-elliptic plate in a ring shape to expose the first semi-elliptic plate to the outside through the ring-shaped interior; And
It includes a through fastening unit that passes through the first semi-elliptic plate and the second semi-elliptic plate and is screwed with the pipe position adjustment shim,
The pipe positioning bracket, the pipe positioning shim, and the through fastening unit surround the reducer,
The first semi-elliptic plate and the second semi-elliptic plate are horizontally extended in a distant direction starting from the rectangular fragment to face the same shape,
The pipe position adjustment shim is fixed to the second semi-elliptic plate, fire fighting pipe restraint device.
The method of claim 1,
The first semi-elliptic plate and the second semi-elliptic plate,
With through-holes close to the curved edges of the individual semi-elliptic plates,
The individual semi-elliptic plate has a circular column dedicated hole at both edges with a square column dedicated hole in the central area near the straight edge,
The second semi-elliptic plate,
Having the pipe position adjustment shim in the through hole of the second semi-elliptic plate,
The square fragment,
A fire fighting device restraint apparatus having a hole for exclusive use of a butterfly bolt that is opened at a right angle to the hole for exclusive use of the square column and the hole for exclusive use of the circular column between the first half-elliptical plate and the second semi-elliptic plate.
The method of claim 2,
The through-hole of the first semi-elliptical plate and the hole for exclusive use of a square pillar and a hole for exclusive use of a circular column face each of the through-holes of the second semi-elliptic plate and the hole for exclusive use of a square column and a hole for exclusive use of a circular column,
The through-hole of the first semi-elliptic plate and the through-hole of the second semi-elliptic plate penetrate the reducer, fire fighting apparatus restraint.
The method of claim 1,
The first semi-elliptic plate and the second semi-elliptic plate,
With through-holes close to the curved edges of the individual semi-elliptic plates,
Has a plurality of position fixing grooves along the circumference of the through hole of the second semi-elliptic plate,
The pipe position adjustment shim,
A cylindrical wall positioned between the first semi-elliptic plate and the second semi-elliptic plate and a circular flange positioned on the second semi-elliptic plate,
The fire extinguisher restraint device through which the reducer is passed through the cylindrical wall and the circular flange.
The method of claim 4,
The cylindrical wall,
Extending from the circumference of the through hole of the second semi-elliptical plate toward the first semi-elliptic plate,
The circular flange,
A firefighter restraint device that is draped around the through-hole of the second semi-elliptical plate and is in close contact with the circumference of the through-hole of the second semi-elliptic plate and crushed by being pressed into the plurality of position fixing grooves.
The method of claim 4,
The pipe position adjustment shim,
Having a female thread along the inner circumferential surface of the cylindrical wall,
Combining the female thread of the cylindrical wall with a male thread located on the outer circumferential surface of the pipe accommodating structure.
The method of claim 1,
The through fastening unit,
An irrigation structure that penetrates the reducer while in contact with the pipe position adjustment shim,
A detachable member located inside the irrigation structure and surrounding the reducer,
It is located between the irrigation structure and the detachable member and includes a tightening pipe surrounding the reducer,
The detachable member and the tightening pipe are moved relative to the irrigation structure along the length direction of the reducer.
The method of claim 7,
The through fastening unit,
The irrigation structure, the detachable member, and the tightening pipe are configured as one set, so that the irrigation structure, the detachable member, and the through-hole of the first semi-elliptic plate and the second semi-elliptic plate are formed, and the Inserting a tightening pipe and screwing the watering structure to the pipe position adjustment shim, a fire fighting pipe restraint device.
The method of claim 7,
The irrigation structure,
When the pipe position adjustment shim is screwed together, at a lower side of the irrigation structure, it protrudes from the irrigation structure, contacts the first semi-elliptical plate, and has a pressure flange that is in close contact with the first semi-elliptic plate,
When the pipe position adjustment shim and the screw thread are coupled, on the upper side of the irrigation structure, having a receiving pipe surrounding the detachable member and the tightening pipe, fire fighting pipe restraint device.
The method of claim 9,
The receiving tube,
It is located on the outer circumferential surface of the receiving tube and has a male thread that is coupled with the female thread of the tube position adjustment shim,
It is located on the inner circumferential surface of the receiving pipe and has a female thread coupled with the male thread of the tightening pipe, fire fighting pipe restraint device.
The method of claim 9,
The detachable member,
Has a thickness gradually thinning from the bottom of the receiving tube toward the tightening tube,
When viewed from the outer circumferential surface of the detachable member, it is cut to a predetermined width vertically along the length direction of the reducer, fire fighting equipment restraint device.
The method of claim 9,
The detachable member,
Through the relative movement of the tightening tube with respect to the receiving tube,
Moving along the length direction of the reducer to reduce the cut width while gradually entering the inside of the tightening tube when viewed from the bottom of the receiving tube, or
A firefighter restraint device that moves along the length direction of the reducer and is restored to the cut width while gradually retreating from the inside of the tightening pipe when viewed from the bottom of the receiving pipe.
The method of claim 9,
The tightening tube,
It is located inside the receiving tube on the detachable member and faces parallel to the receiving tube and is screwed with the receiving tube,
On the reducer, the thickness is increased or decreased in a shape opposite to that of the detachable member so that the detachable member and the tightening pipe obliquely face each other.
The method of claim 9,
The tightening tube,
When gradually entering the interior of the accommodation tube, in the pressurized state of the detachable member, allowing the gradual entry of the detachable member toward the inside of the tightening pipe to space the detachable member from the bottom of the accommodation pipe The detachable member is in close contact with the outer circumferential surface of the reducer with a face-to-face,
When gradually retreating from the inside of the receiving tube, in a state in which the detachable member is released, the detachable member is in close contact with the bottom of the receiving pipe by enabling the gradual retraction of the detachable member from the inside of the tightening pipe And spaced apart the detachable member from the outer circumferential surface of the reducer.
The method of claim 2,
The tube receiving structure,
Insert the through hole of the first semi-elliptic plate and the pipe position adjustment shim of the second semi-elliptic plate into the reducer, and in the square pillar fixed to the ceiling or ceiling structure in the building, the first half In the state where the hole for exclusive use of the square pillar of the elliptical plate and the second semi-elliptic plate is inserted,
In order to obstruct the relative vertical movement of the rectangular column with respect to the first semi-elliptic plate or the second semi-elliptic plate between the first semi-elliptic plate and the second semi-elliptic plate, a butterfly bolt-only hole of the rectangular piece Fitted in and having a butterfly bolt in contact with the square pillar, firefighter restraint device.
The method of claim 15,
The pipe position adjustment shim,
Spaced apart from the square pillars, fire fighter restraint device.
The method of claim 2,
The tube receiving structure,
Insert the through hole of the first semi-elliptic plate and the pipe position adjustment shim of the second semi-elliptic plate to the reducer, and to a circular column fixed to the ceiling or ceiling structure in the building, the first half In the state of inserting the elliptical plate and the hole for exclusive use of the circular column of the second semi-elliptic plate,
In order to obstruct the relative vertical movement of the circular column with respect to the first semi-elliptic plate or the second semi-elliptic plate between the first semi-elliptic plate and the second semi-elliptic plate, a butterfly bolt-only hole of the rectangular piece Fitted in and having a butterfly bolt in contact with the circular column, fire fighter restraint device.
The method of claim 17,
The pipe position adjustment shim,
A fire fighter restraint device that is spaced apart from the circular pillar.
The method of claim 2,
The tube receiving structure,
Insert the through hole of the first semi-elliptic plate and the pipe position adjustment shim of the second semi-elliptic plate to the reducer, and insert a square bar fixed to the ceiling or ceiling structure in the building, the first semi-elliptic In a state surrounded by a plate and the second semi-elliptic plate and the square fragment,
In order to obstruct the relative horizontal movement of the rectangular bar with respect to the first semi-elliptic plate or the second semi-elliptic plate between the first semi-elliptic plate and the second semi-elliptic plate, a butterfly bolt-only hole of the rectangular piece Fitted into and having a butterfly bolt in contact with the square bar, fire fighter restraint device.
The method of claim 19,
The pipe position adjustment shim,
In contact with the square bar, fire fighting equipment.

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