KR101805791B1 - Joist Coupler And Ceiling Frame Having The Same - Google Patents

Abstract

Disclosed is a semi-conductor coupler supported by a semi-mass mount and coupling the semi-mass mount to the semi-mass mount and a ceiling mount having the same. The semi-conductor coupler includes: a first coupling piece for restraining the semi-magnetized band; and a second coupling piece coupled to the first coupling piece, A half-width hanger which can be mounted on a stand; And a fastening member for fastening the second coupling piece to the first coupling piece. And the first coupling piece locally supports the semi-mass band; The second coupling piece is coupled to the first coupling piece by the coupling member so that the second coupling piece is mounted to the semicondrocy bed with the first coupling piece.
According to the present invention, since the semicylindrical coupler can firmly fix the semicircular stand to the carrying channel (semicondroic stand), it is possible to prevent the semicircular stand from deviating and / or wobbling and prevent the ceiling finish from falling and flowing have.

Description

{Joist Coupler And Ceiling Frame Having The Same}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a semi-conductor coupler and a ceiling frame having the same. More particularly, the present invention relates to a semi-conductor coupler for fixing a semi-conductor rod to a semi-

In general, a ceiling of a building such as an apartment or the like is provided with a ceiling panel (ceiling finish panel) that shields a concrete slab and prevents exposure of various wiring and ventilation ducts installed on the ceiling.

The ceiling material is supported by a ceiling frame fixed to the slab, and an example of the ceiling frame is a lightweight steel frame. The ceiling box includes a ceiling box in which a ceiling joist is directly connected to a plurality of hangers fixed to a ceiling slab and a ceiling box in which a ceiling slab is directly connected to a ceiling and a carring channel, And can be classified as an indirect suspension type ceiling frame.

The semi-cylindrical bases are classified into an M-bar, a T-bar, and a clip-bar according to the cross-sectional shape of the semi-mass band, and the semi-cylindrical bases are classified into the carrying channel ) And fixed to the carrying channel by a half-pitch coupler called a half-size clip.

In recent years, since earthquakes have occurred in various countries including Japan, the importance of earthquake-resistant design has been emphasized in response to natural disasters such as earthquakes. However, in the case of conventional ceiling frames, for example, It is difficult to support the ceiling material firmly and the resistance against the deformation and the impact absorbing force are weak. Therefore, when the ceiling is collapsed or the ceiling material falls, Lt; / RTI >

Korean Registered Patent No. 10-1274568, registered on June 7, 2013 Korean Patent Publication No. 10-2015-0120791, October 28, 2015

An object of the present invention is to provide a semi-cylindrical stand-by coupler for a ceiling frame capable of firmly securing the semi-cylindrical stand to the semi-manufactured stand and a ceiling frame having the same.

Another object of the present invention is to provide a semi-automatic coupler for a ceiling box capable of enhancing the binding force of a semi-automatic band and a ceiling box having the same.

It is still another object of the present invention to provide a ceiling frame in which resistance to vibration is improved.

One aspect of the present invention is a semi-conductor coupler which is supported by a semi-conductor support and which connects the semi-conductor support to the support, comprising: a first coupling piece for restraining the semi-conductor assembly; And a second coupling piece coupled to the coupling piece, wherein the second coupling piece is attachable to the tray; And a fastening member for fastening the second coupling piece to the first coupling piece, wherein the first coupling piece locally supports the semi-mass part; The second coupling piece is coupled to the first coupling piece by the coupling member so that the second coupling piece is mounted to the semicondrocy bed together with the first coupling piece.

The first coupling piece and the second coupling piece may form a semicompartment holder for locally supporting one side and the other side of the semispherical band to confine the semispherical band.

The semi-conductor coupler is applicable to a clip-bar semi-bar or a T-bar semi-bar.

The first coupling piece has a first support portion for supporting one side of the semi-mass portion; The second coupling piece may include a second support portion facing the first support portion to support the other side of the semi-mass band.

The first coupling piece and the second coupling piece are each formed with a channel groove penetrating by the semi- The channel groove dividing the first receiving portion and the second receiving portion, respectively; The lower end of the channel groove may be open and the both sides and the upper side of the channel groove may be clogged. A plurality of screw holes may be formed in the first coupling piece and the second coupling piece.

An upper portion of the first coupling piece and an upper portion of the second coupling piece have a plate shape perpendicular to the semi- A lower portion of the first coupling piece may form the first receiving portion, and a lower portion of the second coupling piece may form the second receiving portion.

The semicomponent coupler may be fixed to the semicondrock plate so as to be orthogonal to the longitudinal direction of the semicondroic plate.

The semi-conductor coupler may be applied to a channel-shaped semi-conductor such as an M-bar on which a valley is formed in the longitudinal direction of the semi-conductor band above the semi-conductor band.

Said first coupling piece comprising: And a first support unit provided on the first fixing unit to support the engaging jaws formed on both sides of the bones by being fitted to the bones of the semi- .

The first bearing unit includes: A first fulcrum base provided in the width direction of the first fusing unit so as to transmit the load of the semi-mass unit to the first fusing unit, and a second fulcrum base protruding upward from both sides of the first fulcrum base to support the engaging jaw And a pair of first projections.

The first support base is vertically provided to the first fixing unit; The first projecting base may be provided at one side edge and the other side edge of the first base base so as to be perpendicular to the first base base.

The second coupling piece comprising: A second fusing unit coupled to the first fusing unit so as to be connected to the semicondrocy bed, and a second fusing unit provided in the second fusing unit to support the engaging jaw.

The first fusing unit is mounted on one side of the tray; The second fusing unit is mounted on the other side of the tray; The first and second receiving portions may be provided in opposite directions to face the outside of the semi-conductor coupler.

Wherein the first fixing unit and the second fixing unit are plates that can be mounted on one side and the other side of the semi- The first fixing unit and the second fixing unit may be mutually opposed to each other.

Said half-to-half coupler comprising: And a semi-cylindrical fastening unit provided in the semi-hanging hanger for fastening the semi-cylindrical base.

Said semi-cylindrical fastener comprises: In order to bring the semi-mass band into close contact with the lower end of the semi-mass plate, the height of the semi-mass plate coupler can be adjusted.

The semiperipheral hanger may further comprise a collar supporting part disposed on the upper side of the semi- The semicylindrical fastener may include at least one height adjusting bolt threaded into the elevation support portion so as to pass through the elevation support portion and abut the upper surface of the semi-

Wherein the fastening member includes a screw that passes through the first coupling piece, the semicondrocer plate, and the second coupling piece to fasten the first coupling piece and the second coupling piece to the semi- ≪ / RTI > In order to adjust the height of the half-width coupler, each of the first coupling piece and the second coupling piece may have a long hole extending in the longitudinal direction through the screw.

The first coupling piece may be surface-symmetrical to the second coupling piece. The first coupling piece and the second coupling piece may be symmetrical.

The fastening member screws and couples the first coupling piece and the second coupling piece to each other such that the semiautomatic hangers are mounted on the tray.

Another aspect of the present invention provides a ceiling panel comprising a suspension frame for supporting a ceiling panel. The suspension frame comprising: A hanger installed vertically in the ceiling slab; A semiaxis supporter coupled to the timber and supported by the timber; A semicircular plate coupled to the semicondrock and intersecting the semicondrocer; And a half-to-half coupler as described above.

Wherein the fastening member comprises: The first coupling piece and the second coupling piece are screwed and coupled to each other so that the semi-mass hangers are mounted on the semi-mass mount and are supported by the semi-mass mount.

The semi-cylindrical band is a clip bar, the first coupling piece supports one side surface of the right and left side inclined surfaces of the clip bar, and the second coupling piece supports the other side surface of the right and left side surfaces of the clip bar.

Wherein the semi-mass band is a tiba having an engaging head engaged with the half-mass band coupler; The first coupling piece supports one side of the latching head, and the second coupling piece can support the other side of the latching head. The semicircular zone may be an M-bar.

The ceiling frame may further include an anti-vibration member having at least one of a brace and a damper provided in the suspension frame. The brace may be adjustable in length.

The ceiling frame may further include a brace provided to the suspension frame and an anti-vibration member having a damper coupled to the brace.

The ceiling panel and the seismic member therefor according to the present invention have the following advantages.

First, according to the present invention, since the semi-mass coupler can firmly fix the semi-mass bar to the carrying channel (the semi-mass bar), it is possible to prevent the demagnetization and / or shaking of the semi-mass bar, .

Secondly, according to the present invention, since the semi-mass band can be tightly fixed to the semi-mass band by the semi-mass band coupler, the bonding force to the semi-mass band can be firmly maintained and the binding force to the semi-mass band can be loosened The binding force can be reinforced.

Third, according to the present invention, the resistance of the ceiling structure can be strengthened from the vibration applied to the building due to an earthquake, a typhoon, or an exhibition, and falling or collapse of the ceiling can be prevented or delayed.

Fourthly, according to the present invention, since the length of the brace can be adjusted, it is possible to easily and quickly construct the brace in the field, and the ceiling construction cost can be reduced because the air for ceiling construction can be shortened.

Fifth, according to the present invention, it is possible to easily connect the brace to the lunar base, shorten the time required to fix the brace to the lunar base, and adjust the length and installation direction of the brace variously and easily according to the requirements of the ceiling design .

BRIEF DESCRIPTION OF THE DRAWINGS The features and advantages of the present invention will become better understood with reference to the following description taken in conjunction with the following detailed description of embodiments of the invention,
1 is a perspective view of a ceiling panel according to an embodiment of the present invention;
FIG. 2 is a perspective view showing a state in which a half of a half-width band applicable to a ceiling frame according to an embodiment of the present invention is installed in a carrying channel; FIG.
3 is an exploded perspective view of the half-disk coupler shown in FIG. 2;
FIG. 4 is a cross-sectional view showing the construction of the half-width band shown in FIG. 2;
FIG. 5 is a perspective view showing a state where another example of a semi-automatic band applicable to a ceiling box according to an embodiment of the present invention is installed on a carrying channel; FIG.
FIG. 6 is an exploded perspective view of the half-width coupler shown in FIG. 5; FIG.
FIG. 7 is a cross-sectional view showing the construction of the half-width band shown in FIG. 5;
FIG. 8 is a perspective view showing a state in which another example of a half band applicable to a ceiling box according to an embodiment of the present invention is installed on a carrying channel; FIG.
FIG. 9 is an exploded perspective view of the half-width coupler shown in FIG. 8; FIG.
10 is a cross-sectional view showing the construction of the workpiece shown in Fig. 8;
11 is a perspective view showing an embodiment of a brace member applicable to a ceiling box according to an embodiment of the present invention;
12 is a cross-sectional view of the brace body shown in FIG. 11;
13 is an assembled view of an end portion of a brace applicable to a ceiling box shown in an embodiment of the present invention;
FIG. 14 is a perspective view of a brace bracket applicable to a ceiling box according to an embodiment of the present invention, and FIG. 13 is a sectional view showing one end of the brace shown in FIG. 13;
Fig. 15 is a perspective view showing a state where one end of the brace shown in Fig. 14 is connected to the lunar calendar;
16 is a perspective view showing a damper applicable to a ceiling box according to an embodiment of the present invention;
FIG. 17 is a side view showing an example of setting the damper shown in FIG. 16;
18 is a side view showing another example of the damper shown in Fig. 16;
19 is a side view showing still another example of the damper shown in Fig. 16;
FIG. 20 is a sectional view showing a construction state of a ceiling-mount molding applicable to a ceiling box according to an embodiment of the present invention; FIG.
21 is a perspective view of a ceiling panel according to another embodiment of the present invention; And
FIG. 22 is a side view showing a state in which a half-pitch coupler is applied to the ceiling box shown in FIG.

Best Mode for Carrying Out the Invention Hereinafter, preferred embodiments of the present invention in which the object of the present invention can be specifically realized will be described with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and additional description thereof will be omitted in the following.

1 to 4, an embodiment of a ceiling box according to the present invention and an embodiment of a semi-cylindrical coupler for the same will be described. FIG. 2 is a perspective view showing a state in which a half of the half-width band applicable to a ceiling box according to an embodiment of the present invention is installed on a carrying channel; FIG. 2 is a perspective view FIG. 3 is an exploded perspective view showing the half-pitch coupler shown in FIG. 2, and FIG. 4 is a cross-sectional view showing the construction of the half-pitch band shown in FIG.

1 to 4, an embodiment of a ceiling frame according to the present invention includes a suspension frame 100 supporting a ceiling finish material. The ceiling frame may further include an anti-vibration member 200.

The suspension frame 100 includes a hanger 110 and a counterweight 120 and supports a ceiling finishing material or ceiling panel installed on the ceiling to close the ceiling. The ceiling panel covers the various wires and / or ducts installed in the ceiling to prevent exposure of the wires and ducts.

One embodiment of the present invention is a ceiling panel provided on a ceiling slab and supporting the ceiling panel, and the ceiling panel 110 is vertically installed on the ceiling slab to support a load of the ceiling panel. The vanadium platform 120 is supported by the lunar platform 110, and the ceiling panel 120 is installed on the vanadium platform 120.

The ceiling frame according to the present embodiment may be directly connected to the pan 110 while the pan 120 may be fixed to the pan 130 or the carrying channel 130, to be. A longitudinal member called a so-called " month bar bolt " may be applied as the bar 110, and the bar 120 may be an M-bar, a T-bar, and a clip bar.

The semicircular platform 120 is a joist intersecting the carrying channel 130 and supported by the carrying channel. The carrying channel 130, that is, the semiaxis supporter, is supported by the calendar 110 by hanging from the calendar 110. The semi-mass 120 is fixed to the semi-mass receiving or carrying channel 130 by a semi-mass coupler 140 called a semi-massive clip.

A plurality of the timetable 110 are installed in parallel with each other in accordance with a ceiling frame design condition, and the semicircular platform 120 and the carrying channel 130 are also installed in a plurality of the ceiling design conditions. The function and basic structure of the calendar 110, the semi-automatic bar 120, and the carrying channel 130 are well known, and detailed description of these configurations will be omitted.

The semi-mass part 120 is fixed to the carrying channel 130 by the semi-mass part coupler 140 as described above. However, the conventional half-width coupler has a limitation in the fixing force and the supporting force for the half-width band, and the rigidity is weak, so that it is difficult to firmly fix the half-width band.

In the present specification, embodiments of a half-pitch coupler capable of enhancing a holding force, a fixing force, and a holding force with respect to the semi-cylindrical base 120 and further preventing a swaying of the semi-base band will be described. However, the semi-conductor coupler according to the present invention is not limited to the shape shown in the following embodiments or drawings.

Referring to FIGS. 2 to 4, the embodiment of the semi-conductor coupler according to the first embodiment of the present invention is configured to couple a semi-conductor band 120A to the semi- A semi-hanging jig 140A mounted on the semi-tray table 130 to support the semi-table 120A and a fastening member 143 coupled to the semi-hanging jig 140A.

The hanger 140A includes a plurality of pieces that are coupled to each other by the fastening member 143. [ More specifically, the transverse hanger 140A includes a first coupling piece 141 (first coupling piece) for restraining the semicircular can 120A and a second coupling piece 141 And a second coupling piece (142) fastened to the coupling piece (141).

In this specification, the terms 'first' and 'second' are merely terms used for convenience in distinguishing the components to which the same name is applied. For example, the positions and the numbers of the components, It does not.

The first coupling piece 141 locally supports the semimonomical band 120A. The second coupling piece 142 is coupled to the first coupling piece 141 and is mounted on the tray 140 together with the first coupling piece 141.

In this embodiment, the first coupling piece 141 and the second coupling piece 142 are formed of a semispherical piece 120B that locally supports one side and the other side of the semi- Thereby forming a holder.

The second coupling piece 142 is coupled to the first coupling piece 141 to confine the semi-cylindrical table 120A together with the first coupling piece 141. The semispherical holder 120 is coupled to the first coupling piece 141 and the second coupling piece 142 so that the semispherical stand 120A is engaged with the semispherical holder 120A. Thereby forming a channel fixing portion.

To be more specific, the half-piece embodiment 120A is not limited to the inverted triangle or the cross-sectional shape in cross section perpendicular to the axial direction of the clip bar. The lower end of the semi-cylindrical table 120A can be elastically opened, and the clip bar type semi-cylindrical table 120A forms an elastic gripper for binding and restraining the ceiling panel. Since the clip bar type semi-magnet 120A itself is a well-known technique, a further description of the semi-magnet unit of the first embodiment is omitted.

The half-pitch coupler according to the present embodiment is configured such that it is mounted on the carrying channel 130 to couple the clip bar or the semicircular band 120A to the carrying channel 130, as described above.

In this embodiment, the first coupling piece 141 has a receiving portion 141b for supporting one side of the semimajor band 120A, and the second coupling piece 142 supports the other side of the semi- And has a receiving portion 142b. For convenience of explanation, the receiving portion 141b of the first coupling piece is referred to as a first receiving portion, and the receiving portion of the second coupling piece is referred to as a second receiving portion 142b.

More specifically, the first receiving portion 141b and the second receiving portion 142b face each other, and the first receiving portion 141b includes a first receiving portion 141b and a second receiving portion 142b, which are coupled to the second coupling piece 142, The second fusing part 142b is provided in the second fusing part 142a coupled to the first fusing part 141a.

The first fusing unit 141a and the second fusing unit 142a are coupled to each other by the fastening member 143 and are supported by the carrying channel 130, Thereby forming the semi-mass hangers 140A.

The receiving portion 141b is formed integrally with the first fixing portion 141a and the first coupling piece 141 is formed of a metal plate having a predetermined rigidity such as steel, However, the material and manufacturing method of the first coupling piece are not limited thereto, and materials having appropriate rigidity are sufficient. The second coupling piece 142 can also be manufactured by the above-described sheet metal working.

More specifically, the first coupling piece 141 is formed with a channel groove 141c having a closed shape on both sides so that the carrying channel 130 passes through the first coupling piece 141, and the channel groove 141c Are disposed on both sides of the carrying channel 130 and the upper side of the channel groove 141c is disposed on the upper side of the carrying channel 130. [

The lower end of the channel groove 141c is opened to form an entrance of the carrying channel 130. In this embodiment, the channel groove 141c divides the first receiving portion 141b into left and right sides.

The second coupling piece 142 may be formed with a channel groove 142c having a shape in which the both sides and the upper side are clogged in the vertical direction so that the carrying channel 130 penetrates through the second coupling piece 142 as in the present embodiment.

The channel groove 141c formed in the first coupling piece 141 is referred to as a first channel groove and the channel groove 142c formed in the second coupling piece 142 is referred to as a first channel groove 142c. The upper side of the second channel groove 142c is located on the upper side of the carrying channel 130. The upper side of the second channel groove 142c is located on the upper side of the carrying channel 130, . The lower end of the second channel groove 141c is opened to form an entry port of the carrying channel 130. In the present embodiment, the second channel groove 142c is formed in the left and right sides of the second receiving portion 142b .

An upper portion of the first coupling piece 141, more specifically, the first fixing portion 141a is provided with a plate shape (not shown) disposed perpendicularly to the axis of the carrying channel 130 And a lower portion of the first coupling piece 141 is bent to form the first receiving portion 141b. In this embodiment, the first receiving portion 141b has a cross section of 'C' shape, but the shape of the first receiving portion 141b is not limited thereto.

More specifically, the second fusing unit 142a may be disposed on the plate 130 perpendicular to the axis of the carrying channel 130, that is, the pan receiver base, rather than the upper portion of the second coupling piece 142. [ And the lower portion of the second coupling piece 142 is bent to form the second receiving portion 142b. In this embodiment, the second bearing portion 142b has a cross-section of 'C' shape, but the shape of the second bearing portion 142b is not limited thereto.

As described above, in the present embodiment, the first coupling piece 141 locally supports one side of the semimajor table 120A, and the second coupling piece 142 supports the semi- And the semimajor band 120A is coupled to the semiconducting band coupler 140A to be coupled to the carrying channel 130. The semi-

More specifically, the first receiving portion 141b of the first coupling piece supports one side inclined surface (reverse surface) of the semimajor table 120A, and the second coupling piece 142 supports the semi- And supports the other side slope surface (reverse slope side) of the stage 120A.

The first coupling piece 141 and the second coupling piece 142 are symmetrically joined to each other and are mounted on the carrying channel 130. In this embodiment, . More specifically, in this embodiment, the first coupling piece 141 and the second coupling piece 142 have the same design.

The second fusing unit 142a has the same design as the first fusing unit 141a and is surface-symmetrical to the first fusing unit 141a, Symmetrical to the first bearing portion 141b in the same design as the first bearing portion 141b.

The first coupling piece 141 and the second coupling piece 142 may be formed to be symmetrical in the left and right direction, and the semicomponent coupler may be formed in the longitudinal direction of the semi- Direction) perpendicular to the surface of the workpiece.

As described above, in the present embodiment, the first coupling piece 141 and the second coupling piece 142 are coupled by the coupling member 143 so as to mutually have a mutual plane symmetry, and are more specific than the above- Thereby forming a semi-hanging hanger 140A having a bottom opening. Accordingly, the components constituting the half-to-face coupler, more specifically, the first coupling piece 141 and the second coupling piece 142 can be simplified to one design, and the first coupling piece 141 and the second coupling piece 142 can be used as one component without discrimination in a different installation direction, so that the compatibility of parts can be ensured.

In this embodiment, the fastening member 143 is screwed to the first coupling piece 141 and the second coupling piece 142, and more specifically, the fastening member 143 is screw- And at least one screw hole for fastening the screw is formed in each of the first fixing part 141a and the second fixing part 142a.

The semi-conductor coupler according to the present embodiment may further include a semi-cylindrical fastener 140B provided in the semi-hangers 140A to fasten the semi-manufactured stand 120A.

In the present embodiment, the semicycle hangers 140A are height-adjustable on the carrying channel 130 to apply a lift force to the semi- More specifically, the semi-automatic replenishment term 140B can control the height of the semi-manufactured bed 120A and the semi-manufactured bed 120A is brought into close contact with the lower end of the carrying channel 130, that is, Thereby strengthening the binding force with respect to the semispherical table 120A.

In other words, the semicomponent coupler strongly adheres to the lower end of the carrying channel 130, thereby firmly fixing the semimantal band 120A and preventing the semimantial band 120A from shaking And can also reinforce the grip force (i.e., the force to support the ceiling panel P) of the semi-cylindrical table 120A.

More specifically, in the present embodiment, the semiautomatic band, that is, the clip bar type semi-magnetized band 120A, can spread over time and deteriorate the gripping force, so that the risk that the ceiling panel P will fall .

Since the semi-cylindrical coupler 140A according to the present embodiment supports both side inclined surfaces of the semi-manufactured stand 120, when the semi-manufactured stand 120A is raised, the semi- 120A can be urged by the semi-hanging hangers 140A. Therefore, the grip force of the semispherical band 120A can be reinforced by raising the semispherical hanger 140A more specifically than the semispherical coupler.

The semitransparent fastening period 140B is a lifter for lifting the semi-transverse hangers 140A. In the present embodiment, the semitransplanted fastening period 140B includes at least one height adjusting bolt, It is sufficient that the apparatus can lift the semi-hanging jig 140A so as to firmly bring the semimajor table 120A into close contact with the carrying channel 130. [

The transverse hanger 140A further includes elevation support portions 141d and 142d disposed on the upper side of the carrying channel 130, i.e., the semi- And reference numerals are used) are screwed to the elevation support portions 141d and 142d so as to penetrate the elevation support portions 141d and 142d in the vertical direction. The lower end of the height adjusting bolt 140B is in contact with the upper surface of the tray.

In the present embodiment, the elevation support portions 141d and 142d are formed at least in the upper portion of the first fixing portion 141a and the upper portion of the second fixing portion 142a As a flange type formed in either one, the flange is penetrated by the height adjusting bolt 140B.

To this end, at least one tapped hole (141e, 142e) is formed in the flange, that is, the elevation support portion (141d, 142d) to allow the height adjustment bolt (140B) to move forward and backward. (130). The first fusing unit 141a and the second fusing unit 142a are coupled in an interview state and the flanges 141d and 142d are coupled to the first fusing unit 141a and the second fusing unit 142a 142a.

Therefore, when the height adjusting bolt 140B is rotated to enter the tapped holes 141e and 142e, the height adjusting bolt 140B presses the upper surface of the carrying channel 130, And the semispherical table 120A rises by the semispherical coupler and is brought into close contact with the lower end of the semispherical table 130.

The hanging bar 140A is fixed to the semicondrock plate or carrying channel 130 without moving vertically by the height adjusting bolts 140B.

The first coupling piece 141 is disposed on the semimanufacturing base 130 so as to support one side of the semimantal band 120A in order to fasten the semimantial band 120A to the semi- .

The second coupling piece 142 is disposed on the pan tray 130 to support the other side of the vanadium platform 120A and the first coupling piece 141 and the second coupling piece The first coupling piece 141 and the second coupling piece 142 are coupled to each other by the coupling member 143 in a state where the first coupling piece 141 and the second coupling piece 142 are disposed on the semi-

Next, when the height adjusting bolt 140B is tightened, the hanging hanger 140A is fixed to the pan holder 130 and the pan holder 120A is fixed to the pan holder 130 Lt; / RTI >

Next, another embodiment (second embodiment) of the above-described semi-conductor pair (120B, second embodiment) and another embodiment (second embodiment) of the semi-conductor pair coupler will be described with reference to Figs. 5 to 7.

5 to 7, the second embodiment of the semi-conductor coupler according to the second embodiment of the present invention is configured to couple the second embodiment 120B to the semi- And a fastening member 153 coupled to the semi-hanging hanger 150A. The fastening member 153 is attached to the fastener hangers 150A and 150B.

The half-hangers 150A include a plurality of pieces that are coupled to each other by the fastening members 153. More specifically, the transverse hanger 150A includes a first coupling piece 151 for restraining the semi-cylindrical table 120B, and a second coupling piece 151b for fastening the first coupling piece And a second coupling piece (152) fastened to the first coupling piece (151).

The first coupling piece 151 locally supports the semimonomical band 120B. The second coupling piece 152 is coupled to the first coupling piece 151 and mounted to the semicondrocy bed 130 together with the first coupling piece 151. In this embodiment, the first coupling piece 151 and the second coupling piece 152 are provided with a semi-cylindrical support 150B for locally supporting one side and the other side of the semi- Thereby forming a holder. The ceiling panel P described above is fixed to the semi-magnet table 120A.

The second coupling piece 152 is coupled to the first coupling piece 151 and the second coupling piece 152 is coupled with the first coupling piece 151, (120B). The semispherical holder 120 is coupled to the first coupling piece 151 and the second coupling piece 152 so that the semispherical band 120B is engaged with the semispherical holder 120B. Thereby forming a channel fixing portion.

More specifically, the second embodiment 120B of the half mirror unit comprises a panel support 121B having a T-shaped cross section having a cross section perpendicular to the axial direction and having a substantially inverted T-shape, And a latching head 122B which is integrally provided on the upper side of the latching plate 122 and hooked to the semi-conductor coupler.

In this embodiment, the first coupling piece 151 locally supports one side of the engagement head 122B and the second coupling piece 152 locally supports the other side of the engagement head 122B . Since the tiba type semi-magnet 120B itself is a well-known technique, a further description of the semi-magnet unit of the second embodiment is omitted.

The first coupling piece 151 has a receiving part 151b for supporting one side of the semimajor band 120B and the second coupling piece 152 is for supporting the other side of the semi- And has a receiving portion 152b. For convenience of explanation, the receiving portion 151b of the first coupling piece is referred to as a first receiving portion, and the receiving portion of the second coupling piece is referred to as a second receiving portion 152b.

The first receiving portion 151b and the second receiving portion 152b face each other and the first receiving portion 151b is connected to the first fixing portion 151a coupled to the second coupling piece 152 And the second receiving portion 152b is provided in the second fixing portion 152a coupled to the first fixing portion 151a. The first fusing unit 151a and the second fusing unit 152a are coupled to each other by the fastening member 153 to form the semicircular hanger 150A supported by the carrying channel 130 .

The receiving portion 151b may be formed integrally with the first fixing portion 151a and the first coupling piece 151 may be manufactured by a metal process using a metal, , The material and the manufacturing method of the first coupling piece are not limited thereto and a material having suitable rigidity is sufficient.

More specifically, the first coupling piece 151 is formed with a channel groove 151c having a shape in which the both sides and the upper side are clogged so as to penetrate the carrying channel 130, and the channel groove 151c Are disposed on both sides of the carrying channel 130 and the upper side of the channel groove 151c is disposed on the upper side of the carrying channel 130. [

The lower end of the channel groove 151c is opened to form an entry port of the carrying channel 130. In the present embodiment, the channel groove 151c divides the first receiving portion 151b into left and right sides.

In addition, the second coupling piece 152 is formed with a channel groove 152c having a closed shape on both sides and the upper side so as to pass through the carrying channel 130 in the vertical direction. The channel groove 151c formed in the first coupling piece 151 is referred to as a first channel groove and the second coupling piece 152 The channel groove 152c formed in the second channel groove 152c is referred to as a second channel groove and both sides of the second channel groove 152c are disposed on both sides of the carrying channel 130, Is disposed above the carrying channel (130). The lower end of the second channel groove 151c is opened to form an entry port of the carrying channel 130. In the present embodiment, the second channel groove 152c is formed at the left and right sides of the second receiving portion 152b .

An upper portion of the first coupling piece 151, more specifically, the first fixing portion 151a is provided with a plate shape (not shown) perpendicular to the axis of the carrying channel 130 And the lower part of the first coupling piece 151 is bent to form the first receiving part 151b. In this embodiment, the first receiving portion 151b has a cross section of 'C' shape, but the shape of the first receiving portion 151b is not limited thereto.

More specifically, the second fusing unit 152a is disposed on the plate 130 perpendicular to the axis of the carrying channel 130, that is, the pan receiver base, rather than the upper part of the second coupling piece 152. [ And a lower portion of the second coupling piece 152 is bent to form the second receiving portion 152b. In this embodiment, the second bearing portion 152b has a "C" -shaped cross section, but the shape of the second bearing portion 152b is not limited thereto.

In this embodiment, the distance between the first bearing portion 151b and the second bearing portion 152b is substantially equal to the width of the engagement head 122B.

As described above, in the present embodiment, the first coupling piece 151 locally supports one side of the semi-magnet table 120B, particularly, the lower side of the engaging head 122B, The engaging head 152 locally supports the other side of the antiferromagnetic layer 120B and particularly the lower side of the engaging head 122B and the engaging head 122B of the antiferromagnetic layer 120B is biased to the antiferromagnetic coupler 150A And is coupled to the carrying channel 130.

The first coupling piece 151 and the second coupling piece 152 are mutually opposed to each other to form a plane symmetry as shown in the first embodiment of the semi- And the first coupling piece 151 and the second coupling piece 152 may be manufactured in the same design. The first coupling piece 151 and the second coupling piece 152 may be formed to be symmetrical in the left and right direction, respectively, and the semicomponent coupler may be formed in the longitudinal direction (axial direction) of the semi- And is mounted to the above-described semi-

As described above, in the present embodiment, the first coupling piece 151 and the second coupling piece 152 are coupled by the coupling member 153 so as to mutually have a mutual plane symmetry, and are more specific than the above- Thereby forming a semi-hanging hanger 150A having a bottom opening.

In this embodiment, the fastening member 153 is screwed to the first coupling piece 151 and the second coupling piece 152, and more specifically, the fastening member 153 is screwed into the threaded fastening element And at least one screw hole for fastening the screw is formed in each of the first fixing part 151a and the second fixing part 152a.

Further, the half-width coupler according to the present embodiment further comprises a semi-counterweight fastener 150B provided in the half-hangers 150A to fasten the semi-permanent table 120B.

In the present embodiment, the width hanger 150A is height-adjustable in the carrying channel 130 so as to apply a lift force to the vanadium platform 120B. More specifically, the height of the semi-manufactured stand 120B can be adjusted by adjusting the height of the semi-manufactured stand 120B, and the semi-manufactured stand 120B is brought into close contact with the lower end of the carrying channel 130 Thereby strengthening the binding force with respect to the semispherical table 120B.

In other words, the semicomponent coupler pulls up the semicircular can 120B and tightly attaches it to the lower end of the carrying channel 130, thereby firmly fixing the semicompetric band 120B and moving the semicomponent band 120B .

The semi-cylindrical fastening period 150B is a lifter for lifting the semi-hanging hanger 150A, and may include at least one height adjusting bolt, such as a half-width coupler according to the first embodiment.

The width hanger 150A further includes elevation support portions 151d and 152d disposed on the upper side of the carrying channel 130, that is, the semi- (The reference numerals are used) are screwed to the elevation support portions 151d and 152d so as to penetrate the elevation support portions 151d and 152d in the vertical direction. The lower end of the height adjusting bolt 150B is in contact with the upper surface of the semi-

The elevation support portions 151d and 152d are formed on at least one of the upper end of the first fixing portion 151a and the upper end of the second fixing portion 152a more specifically than the upper end of the semi- As a flange type, the flange is penetrated by the height adjusting bolt 150B.

To this end, at least one tapped hole (151e, 152e) is formed in the flange, that is, the elevation support portion (151d, 152d) to allow the height adjustment bolt (150B) to move forward and backward. (130).

The function of the height adjusting bolt 150B and the assembling method of the half-width coupler according to the present embodiment are the same as those of the first embodiment of the half-width coupler, and thus a repetitive description thereof will be omitted. Since the second embodiment of the half mirror coupler is similar to the first embodiment of the half mirror coupler described above, the contents of the half mirror coupler according to the first embodiment can be commonly applied.

Next, another embodiment (third embodiment) of the semi-conductor assembly (120C, third embodiment) and another embodiment (third embodiment) of the semi-conductor coupler for this will be described with reference to Figs. 8 to 10.

8 to 10, a third embodiment of the half-pitch coupler according to the third embodiment of the present invention is configured to couple the third embodiment 120B to the semi- And a fastening member 163 coupled to the semi-hanging hanger 160A. The fastening member 163 is attached to the semi-

The half-hangers 160A include a plurality of pieces that are coupled to each other by the fastening members 163. More specifically, the transverse hanger 160A includes a first coupling piece 161 for restraining the semi-cylindrical table 120C and a second coupling piece 161 for fastening the first coupling piece And a second coupling piece (162) fastened to the second coupling piece (161).

The third embodiment 120C is a channel-shaped semi-mass band, for example, an embroidered semi-mass band on which an upper side is formed. An upper side of the semi-mass band 120C is provided with a long- .

In addition, the third embodiment of the half-mass coupler supports the semi-magnet base 120C by being caught by the bone of the semi-magnet base 120C. Since the embossing type antiferromagnetic layer 120C itself is a known technique, detailed description of the third embodiment of the antiferromagnetic layer is omitted.

More specifically, the first coupling piece 161 locally supports the semimonomical band 120C. The second coupling piece 162 is coupled to the first coupling piece 161 and mounted to the semicondrocy bed 130 together with the first coupling piece 161. The ceiling panel P is fixed to the semi-cylindrical table 120C.

The first coupling piece 161 includes a fusing unit 161a supported by the semicondrocyberring or carrying channel 130 and a fusing unit 161b provided in the first fusing unit 161a .

In this embodiment, the fusing unit 161a is connected to the spinneret 130, and the fusing unit 161b is fitted in the valley of the spinneret 120C to move the spinneret 120C upward . More specifically, the support portion 161b supports the engagement protrusions 122c formed on both side walls 121c of the valley.

The support portion 161b includes a support base 161b-1 for transmitting a load of the semi-magnet table 120C to the fusing portion 161a, and a protrusion base 161b-1 provided on both sides of the support base 161b- (161b-2).

The support base 161b-1 is provided in the width direction of the fixing unit 161a, that is, in the width direction of the semimajor table 120C. More specifically, the support base 161b-1 is integrally formed on the lower side of the fixing unit 161a, It accomplishes. In the present embodiment, the base 161b-1 is bent at a lower end of the fixing unit 161a so as to be perpendicular to the fixing unit 161a.

The protruding supports 161b-2 are protruded upward from both sides of the supporting base 161b-1. More specifically, the projecting support 161b-2 is orthogonal to the support base 161b-1 and is formed at both side edges of the support base 161b-1.

The second coupling piece 162 is coupled to the first coupling piece 161 and the second coupling piece 162 is coupled with the first coupling piece 161, (120C).

The second coupling piece 162 includes a fixing part 162a supported by the semiaxplanet or carrying channel 130 and a receiving part 162b provided in the fixing part 162a, .

In other words, it can be seen that the receiving portion 162b may be provided in the second coupling piece. However, when the receiving portion is applied to only one of the coupling pieces 161 and 162, It becomes a coupling piece. As a result, if at least one of the coupling pieces 161 and 162 belonging to the present embodiment of the present invention is formed with only one supporting part, the above-described semi-permanent hanger 160A can be mounted.

Hereinafter, for convenience of explanation, the fusing unit 161a and the receiving unit 161b of the first coupling piece are referred to as a first fusing unit and a first fusing unit, respectively, and the fusing unit of the second coupling piece 162a and the receiving portion 162b are referred to as a second fusing portion and a second fusing portion, respectively.

The second fixing unit 162a is connected to the semi- The second receiving portion 162b is fitted in the valley of the semi-mass portion 120C and supports the semi-mass portion 120C upward together with the first receiving portion 161b. More specifically, the second bearing portion 162b supports the engagement protrusions 122c formed on both side walls 121c of the valley.

The second support portion 162b also includes a support base 162b-1 for transferring the load of the semimajor table 120C to the second fusing portion 162a and a second support portion 162b-1 on both sides of the support base 162b- And a protrusion receiving portion 162b-2. The structure of the second bearing portion 162b may be the same as that of the first bearing portion 161a, so that further explanation is omitted.

In this embodiment, the first fixing unit 161a is mounted on one side of the semispherical table 130, for example, and the second fixing unit 162a is provided on the other side of the semispherical table 130 Is mounted on the right side.

The first receiving portion 161b and the second receiving portion 162b are formed outside the semi-conductor coupler so as to be opposite to each other. Therefore, the first receiving portion 161b and the second receiving portion 162b are formed to be flush with each other.

The first fixing unit 161a and the second fixing unit 162a are coupled by the coupling member 163. The first receiving portion 161b is formed integrally with the first fixing portion 161a and the second receiving portion 162b is formed integrally with the second fixing portion 162a, The ring piece 161 and the second coupling piece 162 may be manufactured by a sheet metal working method using a metal having a predetermined stiffness, for example, steel, but the first coupling piece and the second coupling piece The material and the manufacturing method of the coupling piece are not limited to these, and it is sufficient if a material having appropriate rigidity is used.

The upper portion of the first coupling piece 161, more specifically, the first fixing portion 161a is in the form of a plate mounted on one side of the carrying channel 130, that is, The lower portion of the first coupling piece 161 is bent to form the first receiving portion 161b.

More specifically, the second fixing portion 162a is in the form of a plate to be mounted on the other side of the carrying channel 130, that is, the semicondrock plate, rather than the upper portion of the second coupling piece 162 And the lower portion of the second coupling piece 162 is bent to form the second receiving portion 162b.

In the present embodiment, the carrying channel 130 is coupled between the first fixing unit 161a and the second fixing unit 162a.

As in the first embodiment and the second embodiment of the above-described semi-conductor coupler, also in the case of the half-pitch coupler according to the third embodiment, the first coupling piece 161 and the second coupling piece 162 are formed in the casing The first coupling piece 161 and the second coupling piece 162 can be manufactured in the same design. The first coupling piece 161 and the second coupling piece 162 may be formed symmetrically with respect to each other.

As described above, in the present embodiment, the first coupling piece 161 and the second coupling piece 162 are coupled by the coupling member 163 so as to mutually have a mutual plane symmetry, and are more specific than the above- Thereby forming a semi-massager hanger 160A having a structure in which it is caught in a half-size band.

In this embodiment, the fastening member 163 screws the first coupling piece 161 and the second coupling piece 162, and more specifically, the fastening member 163 is screwed into the threaded fastening element And at least one screw hole for fastening the screw is formed in each of the first fixing part 161a and the second fixing part 162a.

Further, the half-pitch coupler according to the present embodiment further comprises a half-pitch blanking period 160B which is provided in the half-width hangers 160A and is used to clamp the half-pit 120C.

In the present embodiment, the semi-hanging jigger 160A is height-adjustable in the carrying channel 130 to apply a lift force to the semi- More specifically, the height of the semi-cylindrical stage 120C can be adjusted by adjusting the height of the semi-cylindrical stage 120C, and the semi-cylindrical stage 120C is brought into close contact with the lower end of the carrying channel 130 Thereby strengthening the binding force with respect to the semispherical table 120C.

In other words, the semitransparent coupler firmly secures the semimajor table 120C to the semimanufacture stand 120C by pulling up the semimantial stage 120C and pressing it strongly against the lower end of the carrying channel 130, 120C can be prevented from being shaken.

The semi-cylindrical fastening unit 160B is a lifter for lifting the semi-hanging hangers 160A. Like the half-pillar coupler according to the first embodiment and the second embodiment, at least one height adjusting bolt, Of the height adjustment bolts.

The transverse hanger 160A further includes elevation support portions 161d and 162d disposed on the upper side of the carrying channel 130, that is, the semi- And reference numerals are used) are screwed to the elevation support portions 161d and 162d so as to penetrate the elevation support portions 161d and 162d in the vertical direction. The lower end of the height adjusting bolt 160B is in contact with the upper surface of the semi-

The elevation support portions 161d and 162d are formed on at least one of the upper end of the first fixing portion 161a and the upper end of the second fixing portion 162a more specifically than the upper end of the semi- As a flange type, the flange is penetrated by the height adjusting bolt 160B.

To this end, at least one tapped hole is formed in the flange, that is, the elevation support portions 161d and 162d, to which the height adjusting bolt 150B can be retractably engaged. The flange is disposed on the upper side of the semi- As shown in FIG.

In this embodiment, the elevation support portion 161d of the first coupling piece is formed on the side of the second coupling piece 162, and the elevation support portion 162d of the second coupling piece is formed on the side of the first coupling piece 161 side.

The fastening member 163 passes through the first coupling piece 161, the semispherical boss 130, and the second coupling piece 162, so that the first coupling piece 161, And at least one first screw 163a for fastening the second coupling piece 162 to the semi-

The first coupling piece 161 and the second coupling piece 162 are connected to the first screw 163a to adjust the height of the semi- The long holes 161c and 162c may be elongated in the longitudinal direction.

An upper end portion of the first coupling piece 161 and an upper end portion of the second coupling piece 162 are formed with piece fastening portions 161e and 162e that are in mutual contact with each other and screwed together by a screw 163b . Therefore, the fastening force between the first coupling piece 161 and the second coupling piece 162 can be further strengthened.

According to the present embodiment, the first coupling piece 161 is disposed on one side of the semispherical table 130 so as to be caught by the semimajor table 120C, and the second coupling piece 162 is disposed on the semi- The first coupling piece 141 and the second coupling piece 142 are coupled to each other by the fastening member 143 in a state where the first coupling piece 141 and the second coupling piece 142 are disposed on the other side of the semi- And is assembled to the pan holder base 130. At this time, the first screw 163a is loosely fastened so that the semiautomatic hangers 160A can be moved upward from the semi-

Next, when the height adjusting bolt 160B is tightened, the semi-hangers 150A are elevated so that the semi-metal stands 120A are tightly bound to the semi- When the lifting of the hanger 160A is completed, the first screw 163a is tightly fastened and the hanger 160A is securely fastened to the tray 130. [

Meanwhile, the ceiling frame may further include the above-described vibration-proof member 200.

Referring to FIGS. 1 and 11 to 15, the vibration proof member 200 includes at least one of a brace 200A and a damper 200B mounted on the suspension frame 10.

The brace 200A is provided in an oblique direction with respect to the lunar month. The brace 200A is a structure for preventing deformation and shaking of the suspension frame. The brace 200A is a structure for preventing the deformation and shaking of the suspension frame. The brace 200A can withstand an external force, To prevent or at least delay the drop.

The brace 200A includes a brace body 210 disposed obliquely to the suspension frame 100 in an oblique direction. The brace body 210 is fixed to the suspension frame 100 by the brace body 220 and the brace body 220 is fixed to the suspension frame 100.

The brace body 210 may have brace brackets of the same structure at one end and at the other end thereof and brace brackets of different structures may be provided. However, in order to facilitate installation and simplify parts, Brace brackets 220 having the same structure are provided at both ends of the brace body 210.

The ceiling frame according to the present embodiment may further include a damper (a damper) 200B mounted on the suspension frame 100. The damper 200B is a vibration damping device, and one side of the damper 200B may be connected to the suspension frame 100 or may be connected to the brace 200A.

Referring to FIGS. 11 and 12, the brace 200A may include a support bar, for example, a stretchable brace body 210 whose length can be adjusted. In the present embodiment, the brace body 210 is configured to include a plurality of segments 211 and 212 (Segments).

More specifically, the brace body 210 includes a first segment 211 constituting a part of the brace body 210 and a second segment (not shown) provided in the first segment 211 212).

The second segment 212 may be positioned in the axial direction of the brace body 210 with respect to the first segment 211. The length of the brace body 210 can be easily adjusted in the field by the relative movement between the first segment 211 and the second segment 212. After the length of the brace body 210 is adjusted , The first segment 211 and the second segment 212 may be mutually fixed.

For example, the second segment 212 may be fixed to a predetermined position of the first segment 211 by a fastening member such as a screw 213. [ In the present embodiment, the visible body 210 may be a two-step slant member, but the present invention is not limited thereto. The brace body 210 may be a three-step or more slant member including three or more segments.

In this embodiment, the segments 211 and 212 have a rod shape. In order to adjust the length of the brace body 210, any one of the segments of the first segment 211 and the second segment 212 However, the structure of the brace body is not limited to this, and a structure capable of adjusting the length is sufficient.

More specifically, in the present embodiment, the first segment 211 is hollow and the second segment 212 is inserted into the first segment 211. The first segment 211 and the second segment 212 may have a rectangular cross section (a cross section perpendicular to the axial direction), and the second segment 212 may be formed of a hollow hollow bar. However, the cross-sectional shapes of the first segment 211 and the second segment 212 are not limited thereto. For example, a circular cross-section may be used.

Thus, the first segment 211 is an enclosure and the second segment 212 is an interior. The second segment 212 extends in the axial direction of the brace body 210 at one end of the first segment 211 or enters the first segment 211, 210 can be varied.

In other words, the length of the brace body 210 may vary depending on the overlapping distance of the first segment 211 and the second segment 212. After the length of the brace body 210 is adjusted as described above, the first segment 211 and the second segment 212 are fixed to each other.

The first segment 211 may include an internal identification window 211a formed on a side surface of the first segment 211. [ The internal identification window 211a may include a slot formed on a side surface of the first segment 211. More specifically, the internal identification window 211a may include a slot Are formed along the longitudinal direction of the first segment (211).

Therefore, the operator can confirm the depth of entry of the second segment 212 when adjusting the length of the brace body 210. According to the present embodiment, since the worker can cut off the brace member in accordance with the installation length at the site, the time required for brace construction can be shortened and the work cost can be reduced.

13 to 15, the brace 200A includes a brace body 210 inclined obliquely with respect to the lunar plane 110, a brace bracket 220 provided on the brace body 210, As shown in FIG.

The brace bracket 220 is an example of the brace coupler described above and supports the brace body 210 by coupling the brace body 210 to the suspension frame 100.

For example, the lower end of the brace body 210 may be connected to the luggage 110 or may be connected to the carrying channel 130 in a configuration other than the luggage 110. In this embodiment, one end of the brace body 210 is connected to one of the plurality of lunar lanes 111, and the other end of the brace body 210 is connected to a plurality of lunar For example, one end of the brace body 210 is connected to the bracket 110, and the brace body 110 (hereinafter, referred to as " second bracket " 210 and the other end may be connected to the carrying channel 130.

In the present embodiment, the brace bracket 220 is mounted on the lunar wall 110 and connects the end of the brace body 210 to the lunar wall 110. The bracing bracket 220 is provided at one end and the other end of the bracing body 210 so that one end of the bracing body 210 is connected to the first lancet 111 And the other end of the brace body 210 is connected to the second month ladle 112 by the brace bracket 220. [

As described above, if the brace coupler having the same structure, that is, the brace bracket 220 is provided at both ends of the brace body 210, the angle of inclination of the brace body 210 may be changed, The installation of the brace 200A can be easily performed and the space restriction is reduced compared with the case where the brace 200A is fixed to the carrying channel 130 and the brace coupler, .

The bracing bracket 220 includes a first fastening member 221 disposed on one side of the lancet 110 and a second fastening member 222 disposed on the other side of the lancet 110. The first fastening member 221 is coupled to the brace body 210 and the second fastening member 222 is coupled to the first fastening member 221, (110).

More specifically, a bracket insertion hole H is formed in the brace bracket 220 so as to penetrate through the bracket 110. The first fastening member 221 has a first month groove 221a forming one side of the month slot H and a second month slot 221a formed on both sides of the first month slot 221a, And a first wing portion 221b. The second fastening member 222 is fixed to the first wing portion 221b and is brought into contact with the first fastening member 221.

The second fastening member 222 includes a second month groove 222a that forms the other side of the month insertion hole H and a second month groove 222a that is provided on both sides of the second month groove 222a, And a pair of second wing portions 222b coupled to the wing portions 221b.

The first fastening member 221 and the second fastening member 222 are fixed to each other by screws such as bolts 223 but the present invention is not limited thereto and the bolts 223 may be provided with nuts 224, May be combined.

The first wing portion 221b and the second wing portion 222b are formed with fastening holes 221c and 222c through which the bolts 223 pass. The first wing portion 221b and the second wing portion 222b form the wing portions 220b of the bracket 220 described above. Therefore, the brace bracket 220 is divided into a center body portion 220a having the lunar insertion hole H and a pair of wing portions 220b provided on both sides of the center body portion 220a .

The first fastening member 221 and the second fastening member 222 are coupled to each other so as to be plane-symmetric with respect to an interface between the first fastening member 221 and the second fastening member 222. The brace bracket 220 supports the axis of the month- The first fastening member 221 and the second fastening member 222 are designed to be symmetrical with respect to the first fastening member 221 and the second fastening member 222. The first fastening member 221 and the second fastening member 222 have different designs And one component can be used independently of the first fastening member 221 and the second fastening member 222. [

The brace body 210 may be connected to the brace bracket 220 by a brace connector 230. That is, one side of the brace connector 230 is fastened to the brace body 210, and the other side of the brace connector 230 is fastened to the brace bracket 220.

In this embodiment, the angle between the brace body 210 and the brace bracket 220 can be adjusted by the brace connector 230. For this purpose, the brace connector 230 is connected to the brace bracket 220 in an angle adjustable manner.

More specifically, the brace connector 230 includes a brace connecting piece 231 and a bracket connecting piece 232, and the brace connecting piece 231 is screwed to an end of the brace body 210. The bracket connecting piece 232 is also screwed to the bracket 220.

In the present embodiment, the brace connecting piece 231 is fixed to the brace body 210 by a plurality of screws 235 so as not to rotate in the brace body 210. The bracket connecting pieces 232 are screwed into any one of the wings 220b of the bracket bracket.

The bracket connecting piece 232 may be formed with one screw such as the first wing portion 221b and the second wing portion 221b for adjusting the angle of the brace connector 230 and the brace bracket 220. [ Is coupled to the brace bracket 220 by any one of the bolts 223 fastening the bracket 222b.

The bracket connecting piece 232 is coupled to the outermost one of the bolts 223 coupled to the wing portion 220b of the bracket bracket 220. The bracket connecting piece 232 is connected to the bolt 223, A bolt fastening hole 232a for fastening the fastening bolt 223 is formed.

The brace connecting piece 231 and the bracket connecting piece 232 are in a plate shape and a stepped portion 233 is formed at the boundary between the brace connecting piece 231 and the bracket connecting piece 232, 233 are formed with reinforcing ribs 234 for increasing the strength of the brace connector 230.

The suspension frame 100 is provided with a plurality of bracings arranged at different positions in the same or different directions, and the bracing described in the present embodiment can be applied to the plurality of bracings. Of course, some of the plurality of braces may employ a brace coupler of a structure different from the brace bracket described above, and one end of both ends may be connected to the carrying channel 130.

The damper 200B is provided on the suspension frame 100 to improve vibration damping. The types of the damper 200B are various, and examples thereof include a hydraulic damper, a gas damper, a spring damper, and the like. The damper 200B may be applied to a case where the brace body 210 is not a length adjusting type, and may be applied to a brace with or without the brace.

16 to 19, the damper 200B may be installed in various directions. For example, the damper 200B may be inclined to the suspension frame 100, and may be provided in various directions such as a forward or backward direction, a left-right direction or a diagonal direction on a virtual horizontal plane perpendicular to the lifter 110 .

More specifically, the damper 200B may be provided in a diagonal direction with respect to the ladle 110, for example, parallel to the brace 200A, or may be provided perpendicular to the ladle 110 . At least one side of the damper 200B may be fixed to the suspension frame 100 and may be fixed to the brace 200A.

One side portion 241 of the damper is fixed to one side portion of the brace body 210, for example, the first segment 211, and the other side portion 242 of the damper is fixed to the other side portion of the brace body 210, And may be fixed to the second segment 212.

In this case, the damper 200B may be fixed to the outside of the brace body 210 (see FIG. 17) or may be inserted into the internal space of the brace body 210 when the brace body 210 is hollow. (See Fig. 18). Of course, one side portion 241 of the damper may be fixed to the brace 200A, and the other side portion 242 of the damper may be fixed to a wall, a slab, or the suspension frame 100.

In addition, the damper 200B may connect one of the timetables 110 (e.g., the first timetable) to another timetable (e.g., the second timetable). In other words, either one of the two sides of the damper 200B may be fixed to the first month 110 and the other side may be fixed to the second month 110. FIG.

The damper 200B may be inclined in an oblique direction as shown in FIG. 19A, or may be installed in a horizontal direction as shown in FIG. 19B. Of course, one side portion 241 of the damper may be fixed to the dial 110 or the brace 200A, and the other side portion 242 of the damper may be fixed (fixed) to the wall or the slab.

Referring to FIG. 19, damper brackets 250 are provided at both ends of the damper 200B to connect the damper 200B and the suspension frame 110, for example, Damper brackets having the same structure may be provided at one end and the other end of the damper 200B. Damper brackets having different structures may be provided. However, in order to facilitate installation and simplify parts, Damper brackets 250 having the same structure are provided at both end portions of the main body 200B.

When the damper bracket 250 and the brace bracket 220 have the same design, the damper bracket can be compatible with the brace bracket, and simplification of the parts can be realized as described above.

The damper bracket 250 is connected to the damper 200B through a damper connector 260. Commercially available products of the damper connector 260 may be used. The damper connector 260 is bolted to a fixing hole 243 formed at an end of the damper 200B and has at least one bracket fixing hole for connection with the damper bracket 250. [

In the present embodiment, the above-described seismic member 200 is applied to a lightweight steel frame ceiling frame more specifically than a ceiling frame, but the seismic member 200 is not limited to the seismic protection of a ceiling frame, It can also be applied to the protection of equipment.

The suspension frame 100 may include a plurality of dampers disposed at different positions in the same or different directions. At least some of the plurality of dampers may be fixed to the brace 200A as in the example shown in FIG. 17 or 18, and may be fixed to the suspension 200A separately from the brace 200A, The frame 100 may be fixed.

The suspension frame 100 may further include a ceiling frame molding 300 that secures a clearance space corresponding to the left / right swing of the suspension frame 100. The ceiling panel molding 300 is configured to close an edge of a ceiling structure implemented by the ceiling panel, and supports the edge of the ceiling panel P and forms a flow space of the ceiling panel P. [

20, the ceiling-mounted molding 300 includes a wall fixing plate 310 fixed to the wall W in an interviewed state, a molding base 320 supporting the ceiling panel P, . The molding base 320 forms an edge design of the ceiling structure, and a groove 321 is formed on the bottom surface of the molding base 320. The groove 321 is elongated in the longitudinal direction of the ceiling-mounted molding 300 to improve a sense of beauty.

The molding base 320 is a cantilever type supported by the wall fixing plate 310. The fixing end of the molding base 320 is connected to the wall of the molding base 320) and the wall (W).

A free end of the molding base 320 is upwardly bent to form a spacer 322 and a support flange 323 on which the ceiling panel P is seated is formed at an upper end of the spacer 322 . The spacer 322 separates the ceiling panel P from the bottom surface of the molding base 320. In this embodiment, the free end of the molding base 320 has a free end 'Shaped cross section.

The ceiling panel molding 300 may be configured to block the gap between the ceiling panel P and the wall W and to secure the ceiling panel P to secure a clearance space corresponding to the left / right shake of the suspension frame 100 So as to be spaced apart from the wall (W), particularly the wall fixing plate (310).

Next, another embodiment of the ceiling frame will be described with reference to Figs. 21 and 22. Fig.

Another embodiment of the ceiling frame described below includes a month 110, a semi-automatic bed 120C, a semi-automatic bed 130A and a semi-automatic side coupler 160, 170, Or a damper, and a repetitive description of the same parts as those of the above-mentioned ceiling frame is omitted, and the same reference numerals are applied to the same components.

The semimajor table 120C is a semispherical table, for example, an embossing table having a longitudinally curved shape on an upper surface thereof. The semispherical table 130A is a sawtooth type semispherical table, A plurality of teeth 131 are formed on the base 130A along the longitudinal direction at predetermined intervals and on both sides of the teeth 131 a base 131a for supporting the base 120C is formed.

A plurality of opening holes 132 are formed on an upper surface of the semicondroic bed 130A along the longitudinal direction of the semicondroic bed 130A, And the lower end of the calendar 110 may be hooked on the opening hole 132. [ An example of a ceiling frame in which the toothed-type semiaxplain table 130A is used is an apartment ceiling frame, but the present invention is not limited thereto.

The semimonomical band 120C is pressed against the receiving base 130A side so that the engaging jaws (122c in FIG. 8) formed on the semimonomical band 120C are caught by the receiving jaws 131a of the teeth. do.

When the semi-cylindrical table 120C is fitted to the teeth 131a, the semi-cylindrical table 120C may be fixed to the receiving table. However, The fixing force of the semispherical table 120C is not stable and the semispheres 120C may be shaken.

In order to secure the fixing force (fixation force) of the semi-cylindrical table 120C, the semi-cylindrical table couplers 160 and 170 are mounted on the tray and the semi- The support member 120C can be fixed to the pan-mount base 130A in a more rigid and stable state.

The semi-conductor couplers 160 and 170 may be embodied more specifically as the semi-conductor coupler 160A than the semi-conductor coupler according to the third embodiment (see FIGS. 8 to 10) , The semimonomical band 120C can be strongly constrained by at least one height adjustment bolt more specifically than the above-described half-bar alternative period 160B.

22, the semi-cylindrical table 120C may be mounted at a portion where the desk 110 and the tray holder 130A are connected to each other. In this case, a lower end of the desk 110 and the half- The tray 120C and the tray 120A can be simultaneously engaged by the tray coupler 170 so that the tray 120C can be more firmly fixed to the initial tray.

The semicomponent coupler 170 for simultaneously fastening the lower end of the ladle 110 and the semimajor table 120C and the semicondroic bed 130A includes a first coupling piece 130A coupled to one side of the semi- And at least one of the coupling pieces may include a receiving portion (reference numerals 161b and 162b in FIG. 9) for catching the valleys of the semi-cylindrical table 120C, and a second coupling piece coupled to the other side of the semi- And the upper structure of one of the coupling pieces has a vertical surface to be in contact with the lower end (hangers) of the month laden. Then, screws are fastened through the semi-cylindrical coupler 170 and the lower end of the calendar 110 and the semi-cylindrical base 120C. Although not shown, a semitransparent fastening period, that is, a height adjusting bolt, may also be applied to the semitransparent coupler shown in FIG. That is, the semi-conductor coupler 170 for simultaneously fastening the lower end of the ladle 110, the semi-cylindrical base 120C and the semi-cylindrical base 130A has the same basic principle as that of the third embodiment of the semi-cylindrical base coupler But it can be changed to a shape.

As described above, according to the present invention, the present invention can be embodied in other specific forms without departing from the spirit and scope of the present invention. It is obvious to them.

Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

100: Suspension frame 110:
120, 120A, 120B, 120C: Semi-pile stand 130: Semi-
140, 140A, 150A, 160A:
140B, 150B, 160B: Semi-long term
141, 151, 161: first coupling piece
142, 152, 162: a second coupling piece
143: fastening member 200: seismic member
200A: Brace 200B: Damper
210: Brace body 211: First segment
212: second segment 220: brace bracket
230: Brace connector 241: One side of the damper
242: the other side portion of the damper 250: the damper bracket
260: Damper connector

Claims (27)

A half-to-half coupler that couples a half-width bracket to a half-width bracket:
A first coupling piece for restraining the semi-mass band, and a second coupling piece for being coupled to the first coupling piece, Large Hangers;
A fastening member for fastening the second coupling piece to the first coupling piece; And
And a semicycle fastener provided in the hanger for clamping the semi-
Said first coupling piece locally supporting said semi-mass band; The second coupling piece is coupled to the first coupling piece by the coupling member such that the second coupling piece is mounted to the semicondrock with the first coupling piece;
Wherein the semi-cylindrical fastener adjusts the height of the semi-cylindrical stand to closely contact the semi-stand with the lower end of the stand;
Wherein the semimanitor hanger further comprises a collar supporting portion disposed on the upper side of the semi-
Wherein said semicylindrical fastener includes at least one height adjusting bolt threaded into said elevation support to contact the upper side of said tray holder through said elevation support;
Wherein the fastening member includes a screw that passes through the first coupling piece, the semicondrocer plate, and the second coupling piece to fasten the first coupling piece and the second coupling piece to the semi- Configured;
Wherein the first coupling piece and the second coupling piece each have elongated slots formed in the longitudinal direction thereof to pass through the screws so as to adjust the height of the half-width coupler. delete delete delete delete delete delete delete The method according to claim 1,
Wherein said semi-cylindrical coupler is applied to a channel-shaped semi-cylindrical base having a valley formed in the longitudinal direction of said semi-massive band above said semi-massive band. 10. The method of claim 9,
Said first coupling piece comprising:
A first fixing unit connected to the semi-
And a first receiving part provided on the first fixing part so as to support the engaging jaws formed on both sides of the valley by being fitted in the semi-mass band. 11. The method of claim 10,
The first bearing unit includes:
A first base provided in a width direction of the first fixing unit to transmit the load of the semi-mass band to the first fixing unit,
And a pair of first protrusions protruding upward from both sides of the first support base to support the engagement protrusions. 12. The method of claim 11,
The first support base is vertically provided to the first fixing unit;
Wherein the first protrusion receiving portion is provided at one side edge and the other side edge of the first receiving base so as to be perpendicular to the first receiving base. 12. The method of claim 11,
The second coupling piece comprising:
A second fixing unit coupled to the first fixing unit to be connected to the semi-
And a second support portion provided on the second fixing portion to support the engagement protrusion. 14. The method of claim 13,
The first fusing unit is mounted on one side of the tray; The second fusing unit is mounted on the other side of the tray;
Wherein the first and second receiving portions are provided in opposite directions so as to face the outside of the semi-conductor coupler. 12. The method of claim 11,
Wherein the first fixing unit and the second fixing unit are plates that can be mounted on one side and the other side of the semi-
Wherein the first fixing unit and the second fixing unit are mutually opposed to each other. delete delete delete delete The method according to claim 1,
Wherein said first coupling piece is plane-symmetrical to said second coupling piece. 21. The method of claim 20,
Wherein the first coupling piece and the second coupling piece are respectively symmetrical in the left and right direction. delete A ceiling frame comprising a suspension frame for supporting a ceiling panel, comprising:
The suspension frame comprising:
A hanger installed vertically in the ceiling slab;
A semiaxis supporter coupled to the timber and supported by the timber;
A semicircular plate coupled to the semicondrock and intersecting the semicondrocer; And
A ceiling box comprising the half-to-face coupler according to any one of claims 1 to 9, 20 to 21, delete 24. The method of claim 23,
Further comprising an anti-vibration member having at least one of a brace and a damper provided on the suspension frame. 26. The method of claim 25,
Said brace comprising: The ceiling box is characterized by its adjustable length. 24. The method of claim 23,
Further comprising: a seismic member having a brace provided to the suspension frame and a damper coupled to the brace.

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