JP6001408B2 - Seismic clip - Google Patents

Description

  The present invention relates to a clip that joins a field edge that supports a ceiling panel and a field edge support that supports the field edge.

  A ceiling panel may be provided on the ground side of a fence installed outdoors to make it eave sky. In this case, the folded plate is attached to the brace extending from the wall surface of the frame, and the hanging bracket attached to the folded plate suspends the ceiling panel, the field edge that supports the ceiling panel, and the field edge support that supports the field edge. . The ceiling panel is connected to the field edge by screws, and the field edge is fixed to the field edge receiver by two clips. In order to firmly fix the field edge and the field edge receiver, the two clips have a thickness of 1.2 mm, and are clamped to each other with bolts and nuts after sandwiching the field edge receiver. Bolted to the edge. Thereby, a clip secures the maximum load of 470 kg and respond | corresponds to a wind load etc. (nonpatent literature 1).

Sawata Corporation Product Catalog 2012. CAT. No. 49 Page 41, bottom right "TTWBB / W clip"

However, a general ceiling panel is provided indoors. Therefore, when determining the maximum load of the clip provided in the room, it is not necessary to consider the wind load, and it is sufficient to consider the dynamic load of the ceiling panel. For example, when installing a ceiling board having a weight of 20 kg / ^{m 2} in one clip per 1 m ^2, statutory, only to be clip withstand the dynamic load the static load and 44 kg / ^{m 2} of 20 kg / ^{m 2.} As can be seen from the above, a maximum load of 470 kg / m ² is not required by law and practically for a clip installed indoors. In addition, since the work to fix the field edge and the field edge receiver is performed at a high place, complicated work such as fixing two clips with bolts and nuts is to avoid an increase in man-hours and poor work leading to an increase in cost. Should not be done. If the plate thickness of the clip is 1.2 mm, the material cost increases, and the processing becomes complicated and the processing cost may increase. In other words, the clip described in Non-Patent Document 1 has excessive performance and may cause construction failure and cost increase.

  The present invention has been made in view of these problems, and an object of the present invention is to obtain an earthquake-resistant clip that securely fixes a field edge and a field edge receiver with simple work while ensuring earthquake resistance.

  The seismic clip according to the present invention is a seismic clip that joins a field edge and a field edge receiver, and extends at a predetermined angle from a plate-shaped main body and a first end that constitutes one end of the main body. A receiving angle portion, a field edge angle portion extending at a predetermined angle from a second end portion which is an end portion different from the first end portion, a second end portion and a second end portion And a field edge engaging part that supports the field edge and is formed on the third end part that faces the field edge, and the field edge receiving angle part can be bent along the field edge receiver. To do. The field edge and the field edge receiver can be securely fixed by simple work while ensuring earthquake resistance.

  The field receiver comprises a web and a flange extending from the web, the first end engages with one end of the flange, and the field receiving angle part is bendable at a portion that contacts the other end of the flange. And it is preferable to have the bending hole opened in the site | part. By bending the edge receiving angle portion at the bending hole, the seismic clip can be easily fixed to the field receiving.

  The main body has a first field receiving hole that is open at a portion in contact with the web and loosely fits with the tapping screw. In combination, the edge receiving angle portion may be fixed to the web. The seismic clip can be firmly fixed to the field guard.

  The angle receiving corner portion has a second field receiving hole that is open at a portion in contact with the web and is loosely fitted to the tapping screw. The tapping screw is loosely fitted to the second field receiving hole. Then, it may be screwed with the web and the edge receiving angle portion may be fixed to the web. The seismic clip can be firmly fixed to the field guard.

  The field edge receiver is a C-shaped channel, and the C-shaped channel is composed of a web and two flanges extending from the web at a substantially right angle, and the first end engages with the end of the flange, Preferably extends perpendicularly from the first end. Seismic clip can be fixed to C-shaped channel.

  The field edge is a C-shaped channel, and the C-shaped channel is composed of a field edge web and two field edge flanges extending substantially perpendicularly from the field edge web, and the field edge angle portion extends perpendicularly from the second end. In addition, it is preferable to have a field edge hole that engages with the field edge flange and opens at a portion to be engaged, and the field edge hole is loosely fitted to the tapping screw. The seismic clip can be firmly fixed to the edge.

  It is preferable that the field edge engaging portion has a J-shape. The field edges can be easily engaged and fixed.

  According to the present invention, it is possible to obtain an earthquake-resistant clip that securely fixes the field edge and the field edge receiver with simple work while ensuring the earthquake resistance.

It is the perspective view which illustrated the state where the 1st seismic clip by this invention is used from the ceiling slab side. It is a perspective view of the 1st seismic clip. It is a front view of the 1st seismic clip. It is the perspective view which showed the state in which the 1st seismic clip is used. It is a perspective view of the 2nd seismic clip.

  Hereinafter, a first embodiment according to the present invention will be described with reference to the drawings. First, the state where the ceiling board 20 is installed using the first seismic clip 100 which is a so-called double clip will be described with reference to FIG.

  The ceiling board 20 is suspended by a plurality of hardware from a ceiling slab (not shown). The plurality of hardware is mainly composed of a field edge receiver 30, a field edge 40, and a suspension bolt 50. The suspension bolt 50 is suspended from the ceiling slab and screwed with one end of the hanger 51. The hanger 51 receives and supports the field receiver 30 at the other end. The field edge receiver 30 is fixed to the field edge 40 via the first seismic clip 100. The first seismic clip 100 is provided so that its orientation is staggered with respect to the longitudinal direction of the field edge receiver 30. A plurality of the field edges 40 are provided below the field edge receiver 30 so as to be orthogonal to the field edge receiver 30. The field edge 40 is a C channel, and a plurality of the field edges 40 are provided at equal intervals on the ceiling board 20 and fixed to the ceiling board 20.

  Next, the first seismic clip 100 that couples the field edge 40 and the field edge receiver 30 will be described with reference to FIGS.

  The first seismic clip 100 is manufactured by forming a steel plate having a thickness of 0.5 mm, and includes a plate-like first main body 110 and a first field edge receiving angle portion 120 extending from the first main body 110. And a field angle portion 130 extending from the first main body 110 and a field engagement portion 140 formed at the end of the first main body 110.

  The first main body 110 is made of one rectangular steel plate and has a first convex portion 111 at the center. A first field receiving hole 112 penetrates above the first convex portion 111. The diameter of the first field edge receiving hole 112 is slightly larger than the outer diameter of the tapping screw described later, and the first field edge receiving hole 112 is loosely fitted to the tapping screw. The top side of the first body 110 forms a first end 113, and the right side surface of the first end 113 in FIGS. 2 and 3 forms a second end 114, and the first end A side surface on the left side of 113 that faces the second end portion 114 forms a third end portion 115. The first end 113, the second end 114, and the third end 115 are connected to form a right angle. In the present embodiment, the width of the first seismic clip 100, that is, the length of the first end 113 is 50 mm, the height of the first seismic clip 100 is 50.6 mm, and the first main body. The height of 110, that is, the length of the second and third ends 114, 115 is 46.8 mm. The diameter of the first field receiving hole 112 is 5 mm, and the distance between the center of the first field receiving hole 112 and the first end 113 is 7 mm.

  The first edge receiving angle portion 120 forms an angle of 90 degrees with the first main body 110 and extends from the first end portion 113 in the direction opposite to the protruding direction of the first convex portion 111. In the first field edge receiving angle portion 120, one circular hole and two oval holes penetrate and open. The circular hole forms a second field edge receiving hole 121, and the oblong hole forms a bent hole 122. The diameter of the second field edge receiving hole 121 is slightly larger than the outer diameter of the tapping screw described later, and the second field edge receiving hole 121 is loosely fitted with the tapping screw. The second field edge receiving hole 121 is provided at the front end side of the first field edge receiving angle part 120 with respect to the ellipse and at the center in the width direction of the first field edge receiving angle part 120. The two bent holes 122 have a shape in which two semicircles having the same diameter are continuously connected by a straight line, and are provided so that the long axes are on the same straight line. The distance between the center of the second field edge receiving hole 121 and the first end 113 and the distance between the long axis of the bent hole 122 and the first end 113 depend on the shape of the field edge receiver 30. It is determined. In the present embodiment, the width of the first field edge receiving angle portion 120 is 50 mm, the length in which the first field edge receiving angle portion 120 extends is 30 mm, and the second field edge receiving hole. The diameter of 121 is 5 mm, the length of the bent hole 122 is 15.5 mm, and the width is 5 mm. The distance between the center of the second field edge receiving hole 121 and the first end 113 is 24.8 mm, and the distance between the major axis of the bent hole 122 and the first end 113 is 13.1 mm. . And the space | interval of the bending holes 122 is 5 mm.

  The field edge angle portion 130 forms an angle of 90 degrees with the first main body 110 and is in the same direction as the protruding direction of the first convex portion 111, that is, the direction opposite to the first field edge receiving angle portion 120. The second end 114 extends a predetermined length, then bends at a right angle, and extends below the first body 110 along the second end 114. One circular hole penetrates the field edge portion 130. The circular hole forms a field edge 131. The field edge hole 131 is provided in a portion of the field edge angle portion 130 that extends downward from the first main body 110. The positional relationship between the center of the field edge hole 131 and the first main body 110 is determined according to the shape of the field edge 40. In the present embodiment, the length of the field edge angle portion 130 extending from the second end portion 114, that is, the width is 10 mm, the length in the vertical direction is 39.6 mm, and the diameter of the field edge hole 131 is Is 4 mm.

  The field edge engaging portion 140 has a J shape formed at the second end portion 114 and the third end portion 115. The field edge engaging portion 140 formed at the third end portion 115 will be described. A first recess 141 is formed from substantially the center of the third end 115 downward, and a protrusion 142 is provided so as to draw a curve upward from the lower end of the third end 115. The length from the first recess 141 to the protrusion 142 in the direction perpendicular to the third end 115, the protrusion length of the protrusion 142, and the width of the protrusion 142 are determined according to the shape of the field edge 40. Is done. The field edge engaging portion 140 has substantially the same shape at the second end portion 114 and the third end portion 115, but the shape of the second recessed portion 143 formed at the second end portion 114 is the third shape. This is different from the shape of the first concave portion 141 formed in the end portion 115. That is, the first concave portion 141 is formed to form an obtuse angle from the third end portion 115, while the second concave portion 143 is formed to form a right angle from the second end portion 114 (FIG. 3). reference).

  Next, the first seismic clip 100 attached to the field edge 40 and the field edge receiver 30 will be described with reference to FIG.

  The field receiver 30 is a so-called C-shaped channel, and includes a web 31 and first and second flanges 32 and 33 extending from the web 31 at a substantially right angle. The field edge 40 is a so-called double field edge, and includes a field edge web 41 and first and second field edge flanges 42 and 45 extending from the field edge web 41 at a substantially right angle. The field edge web 41 is provided with a plurality of irregularities running in the longitudinal direction to ensure the strength of the field edge 40. First and second barbs 44 and 46 are provided at the tips of the first and second field flanges 42 and 45, respectively, and the first and second barb ends 43 and 47, which are barb tips, are provided. , Extending towards the field edge web 41 along the first and second field edge flanges 42, 45.

  The first seismic clip 100 is attached to the field edge 40 and the field edge receiver 30 in two ways. First, the attachment method shown on the right side of FIG. 4 will be described.

  The field edge engaging portion 140 engages with the first and second barbs 44 and 46. In this state, the projecting portion 142 is inserted inside the first and second barbs 44 and 46, the first barb 44 is fitted with the first recess 141, and the second barb 46 is the second barb 46. The recess 143 is fitted. The field edge angle portion 130 is in contact with the outer surface of the second field edge flange 45. At this time, the position of the field edge hole 131 is on the outer surface of the second field edge flange 45. In this state, the installer screws the tapping screw 60 from the field edge hole 131 into the second field edge flange 45 using an electric screwdriver or the like. The steel constituting the field edge 40 has such a material and thickness that it is easy to screw the tapping screw 60 using an electric screwdriver or the like, so that the installer can easily attach the tapping screw 60 to the second field edge flange 45. Can be screwed into. Thereby, the first seismic clip 100 and the field edge 40 are firmly fixed.

  The first seismic clip 100 is attached to the field receiver 30 such that the first end 113 is in contact with one end 34 of the flange, that is, in contact with the joint 34 between the flange and the web 31. Thereby, the first main body 110 is in surface contact with the web 31 and the first edge receiving angle portion 120 is in surface contact with the flange. At this time, the two bent holes 122 are provided so that their long axes are on the other end 35 of the flange. Therefore, the installer can easily bend the first field edge receiving angle portion 120 by 90 degrees or more along the other end 35 of the flange. When the first field edge receiving angle part 120 is bent 90 degrees or more, the first field edge receiving angle part 120 is bent to the inner peripheral side of the field edge receiver 30 along the field edge receiver 30, The first seismic clip 100 is fixed to the field receiver 30 and cannot be easily removed. In this state, the position of the first field edge receiving hole 112 is determined to be on the web 31. After making such a state, the installer screws the tapping screw 60 into the web 31 from the first field edge receiving hole 112 using an electric screwdriver or the like. Since the steel constituting the edge receiver 30 has such a material and thickness that it is easy to screw the tapping screw 60 using an electric screwdriver or the like, the installer can easily screw the tapping screw 60 into the web 31. it can. As a result, the first seismic clip 100 and the field receiver 30 are firmly fixed.

  Next, the attachment method shown on the left side of FIG. 4 will be described. The method of attaching the field edge angle portion 130 and the field edge 40 is the same as that shown on the right side of FIG.

  The field edge engaging portion 140 engages with the first and second barbs 44 and 46. In this state, the projecting portion 142 is inserted inside the first and second barbs 44 and 46, the first barb 44 is fitted to the second recess 142, and the second barb 46 is the first barb. It fits into the recess 141.

  The first seismic clip 100 is attached to the field receiver 30 such that the first end 113 is in contact with the other end 35 of the flange. Thereby, the first main body 110 is in surface contact with the other end 35 of the flange. At this time, the two bent holes 122 are provided so that their long axes are on one end 34 of the flange. Therefore, the installer can easily bend the first field edge receiving angle portion 120 along the one end 34 of the flange approximately 90 degrees. When the first field edge receiving angle part 120 is bent by approximately 90 degrees, the first field edge receiving angle part 120 is bent along the field edge receiver 30, and the first seismic clip 100 is connected to the field edge receiver 30. It cannot be easily removed when suspended. In this state, the position of the second field edge receiving hole 121 is determined to be on the web 31. Therefore, after this state is set, the installer screws the tapping screw 60 into the web 31 from the second edge receiving hole 121 using an electric screwdriver or the like. Since the steel constituting the edge receiver 30 has such a material and thickness that it is easy to screw the tapping screw 60 using an electric screwdriver or the like, the installer can easily screw the tapping screw 60 into the web 31. it can. As a result, the first seismic clip 100 and the field receiver 30 are firmly fixed.

  According to the present embodiment, since the tapping screw 60 can be driven into the field edge receiver 30 in any direction with respect to the field edge receiver 30, the first earthquake resistance clip 100 can be It can be easily and firmly fixed to the field edge receiver 30 to ensure earthquake resistance.

  Further, by bending the first field edge receiving angle portion 120 along the field edge receiver 30, the first field edge receiving angle section 120 can be easily fixed to the field edge receiver 30, and thereafter The tapping screw 60 can be driven in without fixing the first field edge receiving angle portion 120 and the field edge receiver 30 by the operator's hand.

  Next, the 2nd earthquake-resistant clip 200 by 2nd Embodiment is demonstrated using FIG. The same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  The second seismic clip 200 is a so-called single clip and has a half width compared to the first seismic clip 100. Then, a plate-like second main body 210, a second field edge receiving angle portion 220 extending from the second body 210, a field edge angle portion 130 also extending from the second body 210, and a second And a field engagement portion 140 formed at the end of the main body 210. Since the shape of the field edge angle portion 130 and the field edge engaging portion 140 is the same as that of the first embodiment, the description thereof is omitted.

  The width of the second body 210 is half the width of the first body 110. It consists of one rectangular steel plate, and has the 2nd convex part 211 in the center. The width of the second convex portion 211 is half or less than that of the first convex portion 111. Other configurations are the same as those in the first embodiment. In the present embodiment, the width of the second seismic clip 200 is 25 mm. The height of the second seismic clip 200 and the height of the second main body 210 are the same as in the first embodiment.

  One second field edge receiving hole 121 and one bent hole 122 are opened through the second field edge receiving angle part 220. The shapes of the second field edge receiving hole 121 and the bent hole 122 are the same as those in the first embodiment. The bent hole 122 is provided at the center in the width direction of the second field edge receiving angle portion 220.

  The means for attaching the second seismic clip 200, the field edge 40, and the field edge receiver 30 is the same as in the first embodiment, and a description thereof will be omitted.

  According to the present embodiment, it can be attached to the narrow field edge 40 and has the same effect as the first embodiment.

  In any of the embodiments, the angle formed between the first and second field edge receiving angle portions 120 and 220 and the main body is not limited to 90 degrees and can be changed according to the shape of the field edge receiver 30. is there.

  In any of the embodiments, the field edge 40 and the field edge receiver 30 may be members other than the C channel, and the dimensions of the respective members described above are examples and other dimensions may be used.

20 ceiling board 31 web 32 first flange 33 second flange 40 field edge 41 field edge web 42 first field edge flange 45 second field edge flange 50 suspension bolt 51 hanger 100 first seismic clip 110 first 1st convex part 112 1st field edge receiving hole 113 1st edge part 114 2nd edge part 115 3rd edge part 120 1st field edge receiving angle part 121 2nd field Edge receiving hole 122 Bent hole 130 Field edge angle portion 131 Field edge hole 140 Field edge engaging portion 141 First recess 143 Second recess

Claims (7)

A seismic clip that joins the field edge and the field edge receiver,
A plate-shaped body,
A field receiving angle portion extending at a predetermined angle from a first end portion forming one end of the main body;
A field angle portion extending at a predetermined angle from a second end which is an end different from the first end;
A field edge engaging portion formed on the second end and a third end facing the second end to support the field edge;
The field edge receiving angle portion is a seismic clip that can be bent along the field edge support.   The field edge receiver comprises a web and a flange extending from the web, the first end engages with one end of the flange, and the field edge receiving angle part contacts the other end of the flange. The seismic clip according to claim 1, wherein the seismic clip can be bent at a portion and has a bent hole opened at the site.   The main body has a first field receiving hole that is open to a portion that contacts the web and is loosely fitted to the tapping screw, and the tapping screw is loosely fitted to the first field receiving hole. The seismic clip according to claim 2, wherein the seismic clip is screwed to the web to fix the edge receiving angle portion to the web.   The field edge receiving angle portion has a second field edge receiving hole that is open at a portion in contact with the web and loosely fits with the tapping screw, and the tapping screw is used for the second field edge receiving hole. The seismic clip according to claim 2 or 3, wherein the seismic clip is loosely fitted into a hole and screwed into the web to fix the field receiving angle portion to the web.   The fringe receiver is a C-shaped channel, the C-shaped channel comprising a web and two flanges extending substantially perpendicularly from the web, the first end engaging the end of the flange, The seismic clip according to any one of claims 2 to 4, wherein the field edge receiving angle portion extends perpendicularly from the first end portion.   The field edge is a C-shaped channel, and the C-shaped channel includes a field edge web and two field edge flanges extending substantially at right angles from the field edge web, and the field edge angle portion has the second end. 6. A field edge hole extending at a right angle from a portion and engaging with the field edge flange and opening at a portion to be engaged, wherein the field edge hole loosely fits with a tapping screw. A seismic clip according to any of the above.   The seismic clip according to claim 1, wherein the edge engaging portion has a J shape.

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