KR20230171516A - Seismic isolation device for dry wall reinforcement - Google Patents

Abstract

The present invention combines the first seismic isolation pad, which is fixed to both ends of the reinforcement bar to which various appliances such as boilers are attached, to the second seismic isolation pad attached to the side of the stud, thereby fundamentally blocking vibration transmitted to the stud and providing excellent constructability. This is about a seismic isolation device for wall reinforcement.
The present invention is a seismic isolation device for a drywall reinforcement bar, which is installed horizontally between neighboring studs of the drywall and is for combining a reinforcement bar on which a fixture fixed to the drywall is fixed with the stud, and includes a first unit fixed to both sides of the reinforcement bar. seismic isolation pad; and a second seismic isolating pad fixed to a side of a stud at a position corresponding to the reinforcement and coupled to the first seismic isolating pad. It is characterized by being composed of.

Description

Seismic isolation device for dry wall reinforcement}

The present invention is a dry type with excellent constructability while fundamentally blocking vibration transmitted to the stud by combining the first seismic isolation pad fixed to both ends of the reinforcement bar to which various appliances such as boilers are attached to the second seismic isolation pad coupled to the side of the stud. This is about a seismic isolation device for wall reinforcement.

In existing reinforced concrete apartment buildings, the walls within the unit are constructed together with the exterior wall and are constructed using a wet method of pouring concrete inside the form, or using a masonry or ALC method.

However, the wet construction method increases construction costs due to the high labor cost, has difficulty in securing uniform quality, and has concerns about construction delays during winter construction. The masonry or ALC method is highly dependent on manpower, so labor costs are high and a lot of air is required, and ALC blocks are weak against moisture, making them difficult to use in spaces that use water, such as bathrooms.

Accordingly, recently, there has been an increasing number of cases of applying dry methods instead of wet methods, masonry, or ALC methods when constructing walls within households.

Dry wall is constructed by installing runners on the upper part of the lower slab and lower part of the upper slab, constructing studs in the vertical direction between the upper and lower runners, and then attaching lightweight wall panels to the front and back of the studs.

When installing a device such as a boiler on a dry wall, a reinforcing material such as a square pipe is placed horizontally between a pair of studs, and the device is fixed and installed on the reinforcing bar.

However, when the boiler is attached to drywall, the vibration noise from the boiler is transmitted to the floor through the reinforcement bars and studs of the drywall, causing discomfort to residents in the household.

Therefore, conventionally, as shown in FIG. 1, the base plate 30 is coupled to the lower part of the stud 20, and the vibration isolation pad 40 is attached to the lower part of the base plate 30 to transmit vibration caused by the operation of appliances such as boilers. was blocked.

In this case, the base plate 30 is joined to the lower part of the stud 20 by welding.

However, when welding work is done on-site, the time and cost increase due to the input of a separate welding process, it is difficult to secure uniform quality, and there is a risk of fire occurring due to on-site hot work.

In addition, when the base plate 30 is welded to the lower part of the stud 20 in advance at the factory and brought to the site, it is difficult to respond to changes in floor height or construction errors on site.

In addition, the front and rear width of the stud 20 is manufactured to be the same as the internal width of the runner 10. When the base plate 30 is welded to the lower part of the stud 20, the base plate 30 is attached to the outer side of the stud 20. Since it protrudes, the runner 10 of the base plate 30 had to be cut off.

In order to solve the above problems, the present invention aims to provide a seismic isolation device for drywall reinforcement that fundamentally blocks vibration transmitted to the studs and has excellent constructability because there is no separate welding process or runner cutting process.

The present invention according to a preferred embodiment is for combining a reinforcing bar installed in the horizontal direction between neighboring studs of dry wall to which a fixture fixed to the dry wall is fixed with the stud, and a first base isolation fixed to both sides of the reinforcing bar. pad; and a second seismic isolating pad fixed to a side of a stud at a position corresponding to the reinforcement and coupled to the first seismic isolating pad. It provides a seismic isolation device for dry wall reinforcement, characterized in that it consists of.

According to another preferred embodiment of the present invention, the first seismic isolation pad includes a first fixing part fixed to the side of the reinforcement and a first horizontal support part protruding from the top of the first fixing part toward the stud, and the first seismic isolation pad includes a first fixing part fixed to the side of the reinforcement. The two-base isolation pad is a dry wall characterized in that it includes a second fixing part fixed to the side of the stud and a second horizontal support part that protrudes from the bottom of the second fixing part toward the reinforcement bar and on which the first horizontal support part is mounted. A seismic isolation device for reinforcement is provided.

The present invention according to another preferred embodiment further includes a first locking portion that protrudes downward and is mounted on the upper surface of the second horizontal support portion of the second seismic isolating pad outside the first horizontal support portion of the first seismic isolating pad, and the second seismic isolating pad Provided is a seismic isolation device for a drywall reinforcement, characterized in that a second locking portion is further provided inside the second horizontal support portion of the pad and protrudes upward to support the lower surface of the first horizontal support portion of the first seismic isolation pad.

According to another preferred embodiment of the present invention, the outer surface of the first fixing part of the first seismic isolation pad and both sides of the first engaging part are formed to be inclined in an upper-lower narrow shape, and the inner surface of the second fixing part of the second seismic isolating pad and the 2. Provided is a seismic isolation device for a dry wall reinforcement bar, wherein both sides of the locking portion are formed to be inclined in an upward-to-below beam shape so as to be in close contact with the corresponding surface of the first seismic isolation pad.

The present invention according to another preferred embodiment provides a seismic isolation device for a dry wall reinforcement, wherein uneven portions are formed on the joint surface of the first seismic isolation pad and the second seismic isolation pad to engage with each other and limit out-of-plane movement.

The present invention according to another preferred embodiment provides a seismic isolation device for a drywall reinforcement bar, wherein the first seismic isolation pad and the second seismic isolation pad are formed in the same cross-sectional shape.

According to the present invention, by coupling the first seismic isolation pad fixed to both ends of the reinforcement bar to which various appliances such as boilers are attached to the second seismic isolation pad coupled to the side of the stud, vibration transmitted from the reinforcement bar to the stud is blocked and vibration is transmitted to the floor. and a seismic isolation device for dry wall reinforcement that can prevent noise from being transmitted.

Accordingly, the present invention can provide a seismic isolation device for drywall reinforcement with excellent constructability while fundamentally blocking vibration transmitted to the stud without a separate welding process or cutting process of the runner.

Figure 1 is a perspective view showing the vibration reduction structure of a conventional dry wall.
Figure 2 is a perspective view showing the installation state of the seismic isolation device for dry wall reinforcement of the present invention.
Figure 3 is a perspective view showing the front of the reinforcement.
Figure 4 is a perspective view showing the back of the reinforcement.
Figure 5 is a perspective view showing a reinforcement bar to which fixing bolts are coupled.
Figure 6 is a perspective view showing the connection relationship between first and second base isolation pads according to the first embodiment.
Figure 7 is a perspective view showing a coupled state of first and second base isolation pads according to the first embodiment.
Figure 8 is a perspective view showing the connection relationship between first and second base isolation pads according to the second embodiment.
Figure 9 is a perspective view showing a coupled state of first and second base isolation pads according to the second embodiment.
Figure 10 is a perspective view showing the connection relationship between first and second base isolation pads according to the third embodiment.
Figure 11 is a perspective view showing a coupled state of first and second base isolation pads according to the third embodiment.
Figure 12 is a perspective view showing the coupling relationship between first and second seismic isolation pads having concavo-convex portions formed thereon.
Figure 13 is a perspective view showing the cutting line of the seismic isolation pad for forming the first seismic isolation pad and the second seismic isolation pad.

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

Figure 2 is a perspective view showing the installation state of the seismic isolation device for dry wall reinforcement of the present invention. And Figure 3 is a perspective view showing the front of the reinforcement, Figure 4 is a perspective view showing the back of the reinforcement, and Figure 5 is a perspective view showing the reinforcement with fixing bolts combined.

As shown in FIG. 2, etc., the seismic isolation device for the drywall reinforcement of the present invention is installed in the horizontal direction between neighboring studs (2) of the drywall and includes a reinforcement (3) on which the fixture (O) fixed to the drywall is fixed. A first seismic isolation pad (4) for coupling with the stud (2) and fixed to both sides of the reinforcing bar (3); and a second seismic isolation pad (5) fixed to the side of the stud (2) at a position corresponding to the reinforcing bar (3) and coupled to the first seismic isolation pad (4); It is characterized by being composed of.

The present invention is intended to provide a seismic isolation device for a dry wall reinforcement bar that fundamentally blocks the vibration of the fixture (O) coupled to the reinforcement bar (3) from being transmitted to the stud (2) and has excellent constructability.

In drywall, a plurality of studs (2) are installed on the runner (1).

The runners (1) are installed to be spaced apart from each other vertically, and the studs (2) are installed in a vertical direction between the upper and lower runners (1).

The reinforcing bar (3) is installed horizontally between the studs (2) on both sides at the installation position of the boiler or other appliance (O).

The seismic isolation device for the dry wall reinforcement of the present invention is provided between the reinforcement (3) and the stud (2) installed to attach the fixture (O) to the dry wall.

The seismic isolation device for dry wall reinforcement includes a first seismic isolation pad (4) and a second seismic isolation pad (5).

The first seismic isolation pad (4) is fixedly coupled to both ends of the reinforcing bar (3), and the second seismic isolating pad (5) is fixedly coupled to the side of the stud (2) at the position where the reinforcing bar (3) is to be joined.

In a state where first seismic isolation pads (4) are provided on both sides of the reinforcing bar (3) and second seismic isolation pads (5) are provided on the sides of the stud (2), the first seismic isolation pad (5) is fixedly coupled to the end of the reinforcing bar (3). The reinforcement bar (3) can be installed by combining the seismic isolation pad (4) with the second seismic isolation pad (5).

The seismic isolation device for drywall reinforcement of the present invention blocks vibration transmitted from the reinforcement (3) to the stud (2), thereby preventing vibration and noise from being transmitted to the floor.

The first seismic isolation pad 4 and the second seismic isolation pad 5 can be fixed to the reinforcement bar 3 and the stud 2, respectively, with adhesive or pieces.

The first seismic isolating pad 4 and the second seismic isolating pad 5 can be made of anti-vibration rubber with excellent vibration absorption ability, such as polyamide, polyester, polycarbonate, polyether, or polyurethane.

When manufacturing the first seismic isolation pad (4) and the second seismic isolation pad (5) from a material with some degree of elasticity, even if there are some manufacturing or construction errors between the studs (2) and the reinforcement bar (3), these errors must be avoided. It can be absorbed.

The reinforcement (3) may be composed of a front fixing plate (31) on which the fixture (O) is fixed and a side coupling plate (32) that is vertically bent from both ends of the front fixing plate (31) to the rear side (FIG. 3). .

The reinforcement bar (3) can be manufactured by bending a single metal plate.

That is, the side coupling plate 32 can extend from the front fixing plate 31 and be bent.

Therefore, it is possible to manufacture the reinforcement bar (3) simply by bending the metal plate without a separate welding process or bolt fastening, thereby improving productivity and reducing costs.

The front fixing plate 31 is a part where fixing bolts 35 for fixing an appliance (O) such as a wash basin or boiler are coupled, and a bolt hole 311 for fastening the fixing bolt 35 may be formed.

The front fixing plate 31 can determine its vertical height depending on the weight of the fixture (O).

A first seismic isolation pad (4) is fixed to the side coupling plate (32).

At the top of the front fixing plate 31 of the reinforcement bar 3, there is an upper support plate 33 that is vertically bent toward the rear side and both ends are supported on the top of the side coupling plate 32, and a downward vertical direction at the rear end of the upper support plate 33. A bent rear fixing plate 34 may be provided (Figure 4).

Accordingly, the shape of the reinforcing bar 3 can be prevented from being deformed by forming the reinforcing bar 3 in a box shape with an overall open bottom. In addition, by attaching the fixing bolt 35 for attaching the device O through the front fixing plate 31 and the rear fixing plate 34, the load of the device O can be stably supported (FIG. 5).

The rear fixing plate 34 is for penetrating the fixing bolt 35, and a bolt hole 341 can be formed at a position corresponding to the bolt hole 311 provided in the front fixing plate 31.

The bolt holes (311, 341) have a wide central width to facilitate the insertion of the fixing bolt (35), and are formed to be long along the width direction of the reinforcement bar (3) to enable left and right sliding of the fixing bolt (35). can do.

FIG. 6 is a perspective view showing the coupling relationship between the first and second seismic isolation pads according to the first embodiment, and FIG. 7 is a perspective view showing the coupling state of the first and second seismic isolation pads according to the first embodiment.

As shown in FIGS. 6 and 7, the first seismic isolation pad 4 has a first fixing part 41 fixed to the side of the reinforcement bar 3 and a stud at the top of the first fixing part 41. 2) It is configured to include a first horizontal support part 42 protruding to the side, and the second seismic isolation pad 5 includes a second fixing part 51 fixed to the side of the stud 2 and the second fixing part ( It may be configured to include a second horizontal support portion 52 that protrudes from the bottom of the 51) toward the reinforcement bar 3 and on which the first horizontal support portion 42 is mounted.

The first seismic isolation pad 4 and the second seismic isolation pad 5 may be joined to each other using an adhesive or the like, but in this case, construction is cumbersome and installation time is long.

Accordingly, the first seismic isolation pad 4 is formed with an L-shaped cross section and the second seismic isolation pad 5 is formed with an L-shaped cross section, so that the first seismic isolation pad 4 can be mounted on the second seismic isolation pad 5. You can.

For this purpose, the first seismic isolation pad 4 includes a first fixing part 41 fixed to the side of the reinforcement bar 3 and a first horizontal support part protruding from the top of the first fixing part 41 toward the stud 2 ( 42) and can be configured to have an L-shaped cross section.

And the second seismic isolation pad (5) includes a second fixing part (51) fixed to the side of the stud (2) and a second horizontal support part (52) protruding from the bottom of the second fixing part (51) toward the reinforcement (3). ) and can be configured to have an L-shaped cross section.

The first horizontal support part 42 of the first seismic isolation pad 4 is mounted on the upper surface of the second horizontal support part 52 of the second seismic isolation pad 5 to support the reinforcement bar 3.

The first horizontal support part 42 and the second horizontal support part 52 are formed to have the same length, so that the first seismic isolation pads 4 on both sides of the reinforcement bar 3 are between a pair of second seismic isolation pads 5. It is desirable to ensure that it is inserted and fixed.

When the first seismic isolating pad (4) is coupled to the upper part of the second seismic isolating pad (5) from the top downward, the lower end of the first fixing part (41) or the first horizontal support part (42) or the second height is used to facilitate insertion. It is possible to form a chamfer on the upper edge of the top 51 or the second horizontal support 52.

FIG. 8 is a perspective view showing the coupling relationship between the first and second seismic isolation pads according to the second embodiment, and FIG. 9 is a perspective view showing the coupling state of the first and second seismic isolation pads according to the second embodiment.

As shown in Figures 8 and 9, on the outside of the first horizontal support part 42 of the first seismic isolation pad 4, it protrudes downward and is on the upper surface of the second horizontal support part 52 of the second seismic isolation pad 5. A first locking portion 43 is further provided, and the inside of the second horizontal support portion 52 of the second seismic isolation pad 5 protrudes upward to form a first horizontal support portion 42 of the first seismic isolation pad 4. ) A second locking portion 53 supporting the lower surface may be further provided.

In order to more firmly fix the first seismic isolating pad (4) and the second seismic isolating pad (5), a first locking portion (43) is provided at the outer bottom of the first horizontal support portion (42) of the first seismic isolating pad (4). By forming a second locking portion 53 at the inner upper end of the second horizontal support portion 52 of the second seismic isolation pad 5, the first and second locking portions 43 and 53 can be engaged with each other.

That is, the first locking portion 43 may be fixed by fitting into the space between the second locking portion 51 and the second locking portion 53 of the second seismic isolation pad 5.

The second locking portion 53 may be fixed by fitting into the space between the first locking portion 41 and the first locking portion 43 of the first seismic isolation pad 4.

When the first and second locking parts 43 and 53 are provided, the contact area between the first seismic isolation pad 4 and the second seismic isolation pad 5 increases. Accordingly, when vibration occurs, the energy caused by the vibration is dissipated by the frictional force between the contact surfaces of the first seismic isolation pad 4 and the second seismic isolation pad 5, thereby efficiently blocking the vibration.

FIG. 10 is a perspective view showing the coupling relationship between the first and second base isolation pads according to the third embodiment, and FIG. 11 is a perspective view showing the connection state of the first and second base isolation pads according to the third embodiment.

As shown in Figures 10 and 11, the outer surface of the first fixing part 41 and both sides of the first locking part 43 of the first seismic isolation pad 4 are formed to be inclined in an upper-lower narrow shape, and the second The inner surface of the second fixing part 51 and both sides of the second locking part 53 of the seismic isolation pad 5 may be formed to be inclined in an upward-to-downward shape so as to be in close contact with the corresponding surface of the first seismic isolation pad 4. .

The first seismic isolation pad (4) can be easily combined with the second seismic isolation pad (5) even when the gap between the reinforcement (3) and the stud (2) is not constant due to manufacturing or construction errors, etc. The vertical surface where (4) and the second seismic isolation pad (5) come into contact can be formed to be inclined.

Specifically, the outer surface of the first fixing part 41 and both sides of the first locking part 43 may be inclined in an upper-lower narrow shape so that the width becomes narrower toward the bottom. And the inner surface of the second fixing part 51 and both sides of the second locking part 53 are formed in a shape corresponding to the first seismic isolation pad 4, that is, slanted upward and downward so that the width becomes wider toward the bottom. can do.

Accordingly, when the first seismic isolating pad (4) is combined with the second seismic isolating pad (5), the width of the bottom of the first locking portion (43) of the first seismic isolating pad (4) is equal to that of the second seismic isolating pad (5). It is narrower than the space between the second fixing part 51 and the second locking part 53, so the first locking part 43 can be easily inserted between the second fixing part 51 and the second locking part 53.

Figure 12 is a perspective view showing the coupling relationship between the first and second seismic isolation pads on which concave-convex portions are formed.

As shown in FIG. 12, uneven portions 40 and 50 that engage with each other to limit out-of-plane movement may be formed on the joint surface of the first seismic isolation pad 4 and the second seismic isolation pad 5.

When the first seismic isolation pad (4) is simply coupled to the second seismic isolation pad (5), when an external force acts on the reinforcement bar (3), the first seismic isolation pad (4) is separated from the second seismic isolation pad (5). As it slides, the reinforcement (3) may deviate from its original position.

Therefore, by forming uneven portions 40 and 50 on the joint surfaces of the first seismic isolating pad 4 and the second seismic isolating pad 5 so that they engage with each other, the reinforcement bar 3 is prevented from sliding in the direction out of the wall. It can be configured to do so.

For this purpose, the uneven portions 40 and 50 can be formed in the longitudinal direction of the wall.

The uneven portions 40 and 50 may be formed on part or all of the joint surfaces of the first seismic isolation pad 4 and the second seismic isolation pad 5.

Figure 13 is a perspective view showing a cutting line of the seismic isolating pad for forming the first seismic isolating pad and the second seismic isolating pad.

The first seismic isolation pad 4 and the second seismic isolation pad 5 may be formed to have the same cross-sectional shape.

If the shapes of the first seismic isolation pad 4 and the second seismic isolation pad 5 are different from each other, the efficiency of material production and management decreases.

Therefore, as shown in FIG. 13, the first seismic isolation pad 4 and the second seismic isolation pad 5 are formed into a single standard of the same shape and cut to an appropriate thickness according to the thickness of the stud 2 or the reinforcing bar 3. It can be used as the first seismic isolation pad (4) or the second seismic isolation pad (5).

The first seismic isolation pad 4 or the second seismic isolation pad 5 is made of synthetic resin or rubber and can be easily cut at a factory or on site.

1: Runner 2: Stud
3: Reinforcement bar 31: Front fixing plate
311: bolt hole 32: side coupling plate
33: upper support plate 34: rear fixing plate
341: bolt hole 35: fixing bolt
4: First seismic isolation pad 40: Concave-convex portion
41: first fixing part 42: first horizontal support part
43: first engaging portion 5: second seismic isolation pad
50: uneven portion 51: second fixing portion
52: second horizontal support 53: second locking portion
O: apparatus

Claims (6)

It is installed in the horizontal direction between neighboring studs (2) of the dry wall to couple the stud (2) with the reinforcing bar (3) to which the fixture (O) fixed to the dry wall is fixed,
A first seismic isolation pad (4) fixed to both sides of the reinforcement bar (3); and
a second seismic isolation pad (5) fixed to the side of the stud (2) at a position corresponding to the reinforcing bar (3) and coupled to the first seismic isolation pad (4); Seismic isolation device for dry wall reinforcement, characterized in that it consists of.
In paragraph 1:
The first seismic isolation pad (4) includes a first fixing part (41) fixed to the side of the reinforcement bar (3) and a first horizontal support part (42) protruding from the top of the first fixing part (41) toward the stud (2). ) and consists of,
The second seismic isolation pad (5) has a second fixing part (51) fixed to the side of the stud (2) and protrudes from the lower end of the second fixing part (51) toward the reinforcing bar (3) to protrude from the first horizontal support ( A seismic isolation device for a dry wall reinforcement, characterized in that it includes a second horizontal support portion 52 on which 42) is mounted.
In paragraph 2,
On the outside of the first horizontal support part 42 of the first seismic isolation pad 4, there is a first locking part 43 that protrudes downward and is mounted on the upper surface of the second horizontal support part 52 of the second seismic isolation pad 5. It is equipped,
Inside the second horizontal support part 52 of the second seismic isolation pad 5, a second locking part 53 is further provided that protrudes upward and supports the lower surface of the first horizontal support part 42 of the first seismic isolation pad 4. A seismic isolation device for dry wall reinforcement, characterized in that it is provided.
In paragraph 3,
The outer surface of the first fixing part 41 and both sides of the first locking part 43 of the first seismic isolation pad 4 are formed to be inclined in an upper-lower narrow shape,
The inner surface of the second fixing part 51 and both sides of the second locking part 53 of the second seismic isolating pad 5 are formed to be inclined in an upward-to-below shape so as to be in close contact with the corresponding surface of the first seismic isolating pad 4. A seismic isolation device for dry wall reinforcement, characterized in that.
In paragraph 2,
A seismic isolation device for a dry wall reinforcement, characterized in that uneven parts (40, 50) are formed on the joint surface of the first seismic isolation pad (4) and the second seismic isolation pad (5) to engage with each other and limit out-of-plane movement.
In paragraph 1:
A seismic isolation device for a dry wall reinforcement bar, characterized in that the first seismic isolation pad (4) and the second seismic isolation pad (5) are formed in the same cross-sectional shape.

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