KR20120030224A - Holder of building equipment with vibration proof - Google Patents

Abstract

PURPOSE: An earthquake-resistant and earthquake-isolating stand for construction equipment is provided to minimize damage to construction equipment by employing a buffer device and a fixing unit to prevent the shaking of the construction equipment. CONSTITUTION: An earthquake-resistant and earthquake-isolating stand for construction equipment comprises horizontal upper and lower fixing bars(110,120), vertical fixing bars(130), fasteners(112,122,123), and earthquake-isolating springs(121). The upper and lower fixing bars fix the top and bottom of construction equipment, respectively. The vertical fixing bars pass through holes of the upper and lower fixing bars. The fasteners fix the upper and lower fixing bars to the vertical fixing bars. The earthquake-isolating springs are formed between the lower fixing bar and the fasteners and reduce the vibration of construction equipment set on the lower fixing bar.

Description

Building of building equipment with vibration proof

The present invention relates to a seismic seismic and seismic stand for building equipment, and more particularly, to form an earthquake, a strong shock, or a building equipment, ie, a duct by forming a fixing means simultaneously with a shock absorber in fixing the building equipment to a ceiling and a wall. The present invention relates to a seismic and seismic isolator for building equipment, which can prevent damage to building equipment by absorbing minute vibrations caused by the flow of air, while protecting the secondary hazards caused by the damage of building equipment.

In the present invention, the building equipment refers to a facility that is spaced apart from the ceiling and walls of a building such as a duct and a wire tray by a predetermined interval. A duct means a square tube or a cylindrical tube whose cross section is used for air conditioning or intake and exhaust, and is used for ventilation, cooling, heating, and humidification of air inside and outside of a building. Therefore, an exhaust fan is formed at the inlet of the duct to discharge indoor polluted air into the atmosphere, and a heat exchanger may be installed to save energy.

Wire trays (including wire sheaths) are also called cable trays, and are used as a means for multiple wires to supply power to the interior of the building to guide the wiring and for branching at desired locations to connect to outlets for power connections. do.

The main frame of the wire tray has a structure in which an upper flange and a lower flange are formed at the upper and lower ends of the web, and the support frame is formed in a channel shape and a curling portion is formed at the end so that the main frame can be assembled to the main frame by bolts. In a state where the frame is fixed to a ceiling or a wall of a building or the like, the wires may be seated on the support frame and guided.

As shown in Fig. 1, the duct of the conventional building equipment is installed according to the shape of the ceiling or the wall of the building, and then the building equipment is wrapped with a band, and the band is connected to an iron wire to hang from the ceiling. It has a structure, or as shown in Figure 2, has a structure that is installed by coupling the section steel to the anchor bolt and the building equipment on the section steel.

In addition, the wire tray is formed with an anchor bolt embedded in the ceiling at the top so as to be fixed to the ceiling as shown in Figure 3, the connection bar having a plurality of fastening holes forming equal intervals in the lower portion of the anchor bolt protrudes The fixed pin is formed and connected to the fixing pin so that the height can be adjusted, the installation hole is connected to the guide groove and the plurality of fastening holes and the plurality of fastening holes to be connected to the connecting bar is inserted into the upper mounting holes to the height adjustment screw The receiving tube is formed, and a pair of "c" shaped coupling frame symmetrical to each other in the lower portion of the receiving tube and the front and rear so that the connection can be installed between the pair of coupling frame and the pair of coupling frame A square groove is formed in which an end of the coupling frame is inserted, and a plurality of first fastening holes penetrating up and down are formed at both sides, and an electric wire cable is formed at the bottom of the coupling frame. The first wire connector made of metal and provided with a plurality of semicircular first inflow grooves spaced at equal intervals and opened downward to cover the upper surface of the inflow and the lower surface of the wire cable introduced into the first inflow groove. It is connected to the lower portion of the first wire connector so that the wire cable can be seated, and the second fastening hole is formed to communicate with the first fastening hole on both sides so that the bolt can be fastened, the upper surface is in communication with the first inlet groove And a second inflow groove having a circular shape identical to the outer diameter of the wire cable, and having a second wire connector formed of a metal material having a “T” slit groove open downward, and the first inflow groove and the second inflow hole. When there are more wire cables than the number of grooves, the second wire connector is installed to connect the remaining wire cables, and the "T" type guide stones are inserted into and connected to the "T" type slit grooves at the top. The first extension of the metal material having a plurality of semi-circular first wiring grooves spaced at equal intervals and protruding from each other, and having a plurality of first coupling holes formed at both sides thereof, and opening downward to allow a wire cable to flow into the bottom surface thereof. Power connector and

 It is connected to the lower part of the first extension wire connector to surround the lower surface of the wire cable introduced into the first wiring groove so that the wire cable can be seated; A coupling hole is formed, and a second extension wire connector made of metal having a second wiring groove communicating with the first wiring groove on the upper surface thereof and having the same circular shape as the outer diameter of the wire cable is provided.

As described above, in the case of building equipment, the wires or anchor bolts are usually maintained at a constant distance from the ceiling and walls, and also the horizontal state or branching can be prevented, thereby preventing the building equipment from loosening or sagging. .

However, in the case of the building equipment is suspended by the steel wire as shown in Figure 1, if the earthquake, etc. occurs severely shaken up, down, left and right, the connection state of the building equipment is intact, as shown on Figure 2 In the case of the building equipment to be installed is also a structure that is severely shaken up, down, left and right inside the anchor bolt and the section steel when an earthquake occurs, the building equipment is damaged or can not be separated from the fixing means.

In addition, damage to building equipment caused by failure to absorb vibrations caused by external shocks such as earthquakes or vibrations threatens survival because ducts cannot supply external clean air to the room. Due to this, there is a high risk of occurrence of secondary damage.

The present invention is to protect the building equipment from the impact applied to the building, such as earthquakes or severe vibration, and to prevent the shaking of the building equipment with a shock absorber in the fixing device for fixing the building equipment to the ceiling or wall. By forming the fixing means to minimize the damage and damage of the building equipment.

As described above, the present invention can buffer shocks against earthquakes or strong impacts on buildings by forming shock absorbers and building equipment fixing means in fixing building equipment to ceilings and walls, and also allows air flow or other minute vibrations to flow inside the building equipment. It is a very useful invention having the effect of preventing damage to the building equipment due to.

1-reference diagram showing a fixing device of a duct of a conventional building equipment.
Figure 2-reference diagram showing another fixing device of a conventional duct.
3 is a reference diagram showing a fixing device of a conventional wire tray.
Figure 4-An exploded perspective view showing an embodiment of the fixing device of the present invention building equipment.
5 is an exploded perspective view showing another embodiment of the fixing device of the present invention building equipment.
6-5 are cross-sectional views of the coupled state.
7-Reference state of use of the present invention.

Accordingly, the configuration of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce.

The present invention is an upper fixing stand 110 of the horizontal state for fixing the upper portion of the building equipment (C), a lower fixing stand 120 of the horizontal state for fixing the lower portion of the building equipment (C), and the upper fixing stand 110 ) And a vertical fixture 130 penetrating through the through holes (110a, 120a) perforated in the lower fixture 120, and fasteners (112, 113) for fixing the upper fixture 110 to the vertical fixture (130), Fasteners 122 and 123 for fixing the lower fixture 120 to the vertical fixture 130 and the lower fixture 120 to cushion the vibration of the building equipment (C) mounted on the lower fixture 120 It is composed of a surface isolation spring 121 formed between the fasteners (122,123).

At this time, the upper fixing unit 110 and the lower fixing unit 120 is preferably used, such as L-shaped and c-type, ㅁ -shaped steel (形 鋼), vertical bracket 130 is also L-shaped and c-type, ㅁ -shaped steel (形Iii) can be used, but it is preferable to use a threaded rod formed on the outer circumferential surface to facilitate fastening of the fasteners 112, 113, 122, and 123. In this case, the fastener refers to the washers 112 and 122 and the nuts 113 and 123, and the washers 112 and 122 support the seismic spring 111, and the nuts 113 and 123 are coupled to the vertical fixing unit 130 and the upper fixing unit 110. And the lower fixture 120 is fixed.

It is preferable that the socket 140 for coupling to the anchor bolt A embedded in the ceiling B is formed at the upper end of the vertical holder 130.

In another aspect, the present invention is formed between the upper fixing stand 110 and the fasteners (112, 113) by forming a seismic spring 111 to allow the upper fixing stand 110 to act elastically in the lower direction of the building equipment mounted on the lower fixing 120 ( To mitigate the vibration of C) and to cushion the shock.

In this case, in order to more effectively alleviate vibrations and cushion shocks, the base isolation pad 150 may be padded on the bottom surface of the upper fixing stand 110 and the upper surface of the lower fixing stand 120.

As the material of the base isolation pad 150, it is preferable to use rubber and urethane, and other synthetic resin materials effective for shock absorbing.

As described above, the present invention has been described by means of a limited embodiment, but the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains to the technical spirit of the present invention and claims to be described below. Various modifications and variations are possible within the scope of equivalents.

100: the present invention building equipment seismic and seismic isolation mount
110: upper stand 110a: through hole
111: isolation spring
112: washer 113: nut
120: lower holder 110a: through hole
121: isolation spring
122: washer 123: nut
130: vertical holder 140: socket
150: isolation pad
A: Anchor Bolt B: Ceiling
C: building equipment

Claims (6)

Horizontal upper fixing stand 110 for fixing the upper portion of the building equipment (C), horizontal lower fixing stand 120 for fixing the lower portion of the building equipment (C), the upper fixing stand 110 and the lower Vertical holder 130 penetrating the through holes (110a, 120a) perforated in the holder 120, fasteners (112, 113) for fixing the upper holder 110 to the vertical holder 130, and the lower holder Fasteners 122 and 123 for fixing the 120 to the vertical fixture 130 and the lower fixture 120 and the fastener (120) to cushion the vibration of the building equipment (C) mounted on the lower fixture 120 ( A seismic isolation and seismic isolating building equipment, characterized in that consisting of a seismic spring (121) formed between the 122,123.
According to claim 1, wherein the upper fixing stand 110, the lower fixing stand 120, the vertical fixing stand 130 is seismic and seismic stand according to the building equipment, characterized in that any one of the L-shaped, c-type, ㅁ type steel selectively used. .
According to claim 1, wherein the vertical fixture 130 is seismic and seismic stand for building equipment, characterized in that using a spiral bar.
According to claim 1, wherein the seismic isolation spring 111 is formed between the upper fixing stand 110 and the fasteners 112, 113, the seismic construction equipment, characterized in that the upper fixing stand 110 is configured to act elastically in the downward direction And base isolation.
According to claim 1, The seismic and seismic stand for building equipment, characterized in that the socket 140 for coupling to the anchor bolt (A) embedded in the ceiling (B) is formed on the upper end of the vertical fixture 130 .
According to claim 1, Seismic and seismic stand of the building equipment, characterized in that the bottom of the upper fixing (110) and the upper surface of the lower fixing (120) to the pad (150) is configured by the construction.

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