JP2012087483A - In-plane shear reinforcement structure of deck plate, roof structure and shear reinforcement metallic material - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an in-plane shear reinforcement structure of a deck plate, a roof structure and a shear reinforcement metallic material for the deck plate.SOLUTION: In the reinforcement structure of the deck plate for which an upper flange and a lower flange are formed through webs, a shear reinforcement metallic material 13 for increasing the in-plane shear stiffness of the deck plate is arranged in a dent part formed between the webs facing each other at an interval on the upper surface side of the lower flange, the shear reinforcement metallic material 13 includes a rising part 14 which is fitted so as to match the dent part 12 and extends over the webs 4 facing each other in the dent part 12, the rising part 14 is provided with an overhang part 15 overhung integrally in a transverse direction, and the overhang part 15 is fixed to the deck plate 1. In the roof structure, a heat insulation plate made of a foam resin and a waterproof sheet are successively provided on the deck plate 1 and the shear reinforcement metallic material 13.

Description

  The present invention relates to an in-plane shear reinforcement structure for a deck plate used in a roof structure of a building or factory, and more particularly to an in-plane deck plate in which a horizontal upper flange and a lower flange are formed via a web. The present invention relates to a shear reinforcement structure, a roof structure including the reinforcement structure, and a shear reinforcement hardware for a deck plate.

  In general, from the viewpoint of securing shear rigidity and proof stress in the in-plane direction, there has been proposed a method for realizing this by arranging braces 30 as shown in FIGS. 22 (a) and 22 (b), for example. 22A is a side view of the roof structure, and FIG. 22B shows a plan view of the brace 30. FIG. The roof structure is arranged on the ceiling 31 and the field edge 32 as shown in FIG. 22 (a), and the beam 19 for supporting the roof 33 is installed. It will be arranged in the space 34 surrounded by the beam 19.

However, this space 34 is generally provided with facilities such as an air conditioner and a ventilation fan. In this space 34 divided into two upper and lower spaces by the brace 30, the space 34 is arranged from the position where the brace 30 is disposed. Only the lower space can be used as the so-called equipment space 35, and the entire space cannot be used more effectively. In addition, there is a problem that the installation labor and cost are increased by installing the brace 30.

Conventionally, as shown in FIGS. 23A, 23B, and 24A, a bent plate 36 such as a deck plate is joined to a beam 19 via a support member 37 such as a square steel pipe. It is known that the folding plate 36 is supported (see, for example, Patent Document 1).
In the case of the technique shown in FIGS. 23A, 23B, and 24A, the height of the support member 37 is smaller than the height of the folding plate 36, so the lower flange 39 of the folding plate 36 is The level difference G is located below the upper flange 38 of the beam 19. For this reason, as shown in FIGS. 23A, 23B, and 24A, the equipment space below the folding plate 36 is pressed, and the equipment space 35 below the folding plate 36 is narrowed. There is.

  As a technique for improving the point that the equipment space 35 becomes narrow as described above, there are the following techniques that have been filed and published by the present applicant.

As shown in FIGS. 20 to 21 (or shown in FIG. 2 of Patent Document 2), even the deck plate 1 in which the horizontal upper flange 3 and the lower flange 2 are formed via the web 4, If the ratio of the width (2e) of the lower flange 2 and the width (f) of the upper flange 3 satisfies 2e / f (= β) ≧ 1, in-plane without using braces on the deck plate 1 A deck plate capable of ensuring shear rigidity and yield strength is known, and a roof structure using such a deck plate 1 is known (see, for example, Patent Document 2).
Further, in FIG. 7 of Patent Document 2, assuming that the thickness (t) of the deck plate 1 is 2e / f = β, (2e / t) / ((βt / (1 + β)) ^0.5 ≦ 437 It is also disclosed that by satisfying the above, local buckling of the deck plate 1 is suppressed and the in-plane shear strength is improved.
Further, in Patent Document 2, ribs are provided on the lower flange of the deck plate 1, and the width between adjacent ribs and between the ribs and the web is (2e / t) / ((βt / (1 + β)) ^0.5. It is also disclosed that the local buckling of the deck plate 1 is suppressed and the in-plane shear strength is improved by satisfying the expression ≦ 437.
When the deck plate 1 does not require the use of braces, dead space due to the braces does not occur. Therefore, the equipment space 35 on the lower side of the deck plate is wider than when the braces are arranged on the lower side of the deck plate. There are advantages you can do.

  As shown in FIG. 25, when a horizontal force F is applied to the deck plate 1, the deck plate 1 is made of a thin steel plate having a thickness of about 1 mm or 1.2 mm. 2, the upper flange 3, and the web 4 connecting them 2, a warping deformation H is generated.

Japanese Patent Laid-Open No. 10-121634 JP 2008-2240 A

In the conventional case, the ratio of the width (2e) of the lower flange 2 to the width (f) of the upper flange 3 (2e / f (= β) ≧ 1 is satisfied, or (2e / t) / (( βt / (1 + β)) ^0.5 ≦ 437 Since the form of the deck plate is limited so as to satisfy the expression, it was not possible to deal with various forms of the deck plate. There is a demand for a structure that can be applied to a deck plate that does not satisfy the above equations, and a reinforcing metal that suppresses the deformation as described above is desired.
It is an object of the present invention to provide a deck plate in-plane shear reinforcement structure and a roof structure, and a shear reinforcement hardware for the deck plate, which can solve the above-mentioned problems.

The deck plate in-plane shear reinforcement structure according to the first aspect of the present invention is a deck plate reinforcement structure in which an upper flange and a lower flange are formed via a web, and the web is opposed to the upper surface of the lower flange at an interval. A shear reinforcement metal for increasing the in-plane shear rigidity of the deck plate is disposed in the valley formed between the two, and the shear reinforcement metal fits in the valley while being in contact with the web and is opposed to the valley. A rising portion extending between the webs is provided, and the rising portion is provided with a protruding portion extending horizontally in the rising portion, and the protruding portion is fixed to the deck plate.
According to a second aspect of the present invention, in the in-plane shear reinforcement structure for a deck plate according to the first aspect of the invention, a plurality of the shear reinforcement hardware are disposed at intervals in the longitudinal direction of the valley portion in the deck plate.
In the third invention, in the in-plane shear reinforcement structure for the deck plate of the first invention or the second invention, the shear reinforcement hardware is arranged in a straight line in the width direction of the deck plate, respectively, in the valley portions arranged in parallel in the deck plate. It is characterized by being installed.
In the fourth invention, in the in-plane shear reinforcement structure of the deck plate according to any one of the first invention to the third invention, the shear reinforcement hardware is an upper projecting portion projecting in the deck plate width direction above the rising portion and a deck at the lower portion. A lower projecting portion projecting in the plate extending direction is provided, and the upper projecting portion and the lower projecting portion are fixed to the deck plate.
In the roof structure having the deck plate of the fifth invention, the deck plate is installed across the beam, and the deck plate is in-plane shear reinforcement of the deck plate of any of the first to fourth inventions. It is reinforced by a structure, a heat insulating plate and / or a fireproof material is installed on the deck plate and the shear reinforcement metal, and a waterproof sheet is provided on the heat insulating plate and / or the fireproof material.
In the shear reinforcement hardware for a deck plate according to the sixth aspect of the invention, in order to increase the in-plane shear rigidity of the deck plate in which the upper flange and the lower flange are connected via the web and are alternately formed with a crest and a trough. A shear reinforcement hardware to be installed, wherein the shear reinforcement hardware is provided with a rising portion that fits in the valley portion while being in contact with the web and extends between opposing webs in the valley portion; And a projecting portion for projecting in the horizontal direction and fixing to the deck plate.
According to a seventh aspect of the present invention, in the shear reinforcement hardware for a deck plate according to the sixth aspect of the invention, the shear reinforcement hardware comprises rising portions spaced apart in the longitudinal direction of the groove in the deck plate, and each rising portion is integrally connected to the overhanging portion. It is characterized by being.
According to an eighth aspect of the present invention, in the shear reinforcement hardware for a deck plate according to the sixth aspect of the present invention, the overhanging portion is provided at one or both of the lower end portion and the upper end portion of the rising portion.

According to the first aspect of the present invention, there is provided a reinforcing structure for a deck plate in which an upper flange and a lower flange are formed via a web, and a trough portion formed between webs facing each other at an interval on the lower flange upper surface side. A shear reinforcement metal for increasing the in-plane shear rigidity of the deck plate is disposed, and the shear reinforcement metal fits in the valley while contacting the web and extends between the opposing webs in the valley In the case where the horizontal force acts on the deck plate in the event of an earthquake, etc. The deck plate can be prevented from being distorted and deformed by the shear reinforcement metal. Further, since the main part of the rising portion is arranged in the groove portion of the deck plate and is in contact with the web, the shear reinforcing metal fitting fits in the valley portion, so that it does not protrude greatly from the deck plate, and on the deck plate. When a heat insulating member or the like is placed, the upper surface of the heat insulating member or the like directly above the shear reinforcement metal member does not protrude, and a flat upper surface can be formed.
Also, since the shear reinforcement hardware is a hardware with a simple structure, the in-plane rigidity of the deck plate can be easily improved, and the shear reinforcement hardware should be installed from the top side of the deck plate, so installation work is also easy. Effects such as being easy can be obtained.
According to the second invention, since the plurality of shear reinforcement hardware is installed at intervals in the longitudinal direction of the valleys in the deck plate, just by arranging a plurality at intervals in the groove longitudinal direction of the deck plate, Even if horizontal force is applied to the deck plate during an earthquake, the deck plate's in-plane rigidity is prevented by preventing deformation of the web or upper and lower flanges of the deck plate along the longitudinal direction of the groove in the deck plate. The effect that can be reinforced is obtained.
According to the third invention, since the shear reinforcement hardware is installed in parallel in the width direction of the deck plate in each of the troughs in parallel in the deck plate, in each trough in the parallel trough, By simply installing the shear reinforcement hardware in parallel at the same position, the warp deformation of the web and upper and lower flanges in each valley in the deck plate width direction can be prevented, and each valley in the deck plate can be placed in the width direction of the deck plate. The effect of being able to reinforce uniformly over the range is obtained.
According to a fourth aspect of the present invention, the shear reinforcement hardware includes an upper projecting portion projecting in the deck plate width direction at the upper portion of the rising portion and a lower projecting portion projecting in the deck plate extending direction at the lower portion, and the upper projecting portion and the lower projecting portion. Is fixed to the deck plate, so that the shape of the shear reinforcement hardware can be simplified simply by providing a horizontal extension area at the top and bottom of the rising part, and the upper or lower extension part of the shear reinforcement hardware. The effect that it can be easily fixed to the deck plate using is obtained.
According to the fifth invention, the deck plate is installed across the beam, and the deck plate is reinforced by the in-plane shear reinforcing structure of the deck plate according to any one of the first to fourth inventions, Since a heat insulating plate and / or fireproof material is installed on the deck plate and the shear reinforcement hardware, and a waterproof sheet is provided on the heat insulating plate and / or fireproof material, in-plane shear rigidity without using braces, In particular, it is possible to form a deck plate group that has a large effect of preventing deformation of the web and the flanges at the top and bottom of the deck plate. Therefore, it has high resistance to warping deformation when a horizontal force is applied during an earthquake, etc. It can be set as the roof structure provided with the deck plate.
According to the sixth invention, the upper flange and the lower flange are connected via the web, and the shear reinforcement hardware is installed to increase the in-plane shear rigidity of the deck plate in which the crest and trough are alternately formed. The shear reinforcement metal fitting is provided with a rising portion that fits in the valley portion while being in contact with the web and extends between opposing webs in the valley portion, and the rising portion projects in a horizontal direction integrally therewith. Since the overhanging portion for fixing to the deck plate is provided, it is possible to provide a shear reinforcing metal fitting for a deck plate having a simple structure, and it is possible to easily fix the deck plate to the deck plate.
According to the seventh aspect of the present invention, the shear reinforcement hardware includes rising portions spaced apart in the longitudinal direction of the groove in the deck plate, and each rising portion is integrally connected to the overhanging portion, so the rising portions are spaced apart. Even if there are a plurality of parts, the manufacturing cost can be reduced because of the simple structure integrated by the overhanging part. Moreover, since it is an integrated structure, it is possible to obtain an effect such as a strong shear reinforcement hardware.
According to the eighth aspect of the invention, since the overhanging portion is provided at either or both of the lower end portion and the upper end portion of the rising portion, the overhanging portion is provided at either one or both of the lower end portion or the upper end portion of the rising portion. It is possible to obtain an effect such as a simple structure-reinforced shear reinforcement hardware.

(A) is a partially longitudinal perspective view showing the roof structure provided with the deck plate of the first embodiment of the present invention, (b) is an enlarged perspective view showing a part of (a). (A)-(e) is a perspective view which shows the various forms of a shear reinforcement metal fitting. (A)-(d) shows the shear reinforcement metal fitting of 1st form, Comprising: (a) is a top view, (b) is a rear view, (c) is a front view, (d) is a left side surface. FIG. (A)-(d) shows the shear reinforcement metal fitting of a 2nd form, (a) is a top view, (b) is a rear view, (c) is a front view, (d) is a left side. FIG. (A)-(d) shows the shear reinforcement metal fitting of 3rd form, Comprising: (a) is a top view, (b) is a rear view, (c) is a front view, (d) is a left side surface. FIG. (A) is a front view which shows the state which connected the adjacent deck plates, (b) is a front view which expands and shows a part of (a). (A)-(d) shows the shear reinforcement metal fitting of 5th form, Comprising: (a) is a top view, (b) is a rear view, (c) is a front view, (d) is a left side surface. FIG. It is a perspective view which shows the 1st example of joining of a shear reinforcement metal fitting, a deck plate, and a beam. It is a perspective view which shows the 2nd example of joining of a shear reinforcement metal fitting, a deck plate, and a beam. It is a perspective view which shows the 3rd example of joining of a shear reinforcement metal fitting, a deck plate, and a beam. (A)-(c) shows the top view of the test body at the time of changing the joining location of a shear reinforcement metal, (a) is the form which fixed each overhang | projection part of the upper and lower parts to the deck plate (B) is a form in which the upper projecting part is fixed to the deck plate, and (c) is a form in which the lower projecting part is fixed to the deck plate. (A)-(b) shows the top view of the test body at the time of changing the length of a shear reinforcement metal fitting, Comprising: (a) is the length of a shear reinforcement metal fitting in FIG. 11 (a). (B) is a form in which the length of the shear reinforcing metal piece is three times longer than the form shown in FIG. 11 (a), and the protruding portions of the upper and lower parts of the shear reinforcing metal piece are both shown. It is a top view which shows the form fixed to the deck plate. (A)-(c) shows the top view of the test body at the time of changing the arrangement | positioning form of the shear reinforcement hardware with respect to a deck plate, (a) is the edge part of the trough longitudinal direction of a deck plate 120 mm, (b) is 500 mm, and (c) is 1000 mm. It is a schematic plan view which shows the state which installed the test body in the horizontal load-force apparatus (bending shear test apparatus), and has arrange | positioned the displacement meter to each part. (A)-(e) shows the shear reinforcement metal fitting of another form, (a) is a perspective view, (b) is a top view, (c) is a rear view, (d) is a front. FIG. 4E is a left side view. (A)-(e) shows an example of the shear reinforcement metal fitting of the form which is not provided with the upper overhang | projection part, (a) is a perspective view, (b) is a top view, (c) is a rear view. , (D) is a front view, and (e) is a left side view. (A)-(e) shows the other example of the shear reinforcement metal | metal | money of the form which is not equipped with an upper overhang | projection part, (a) is a perspective view, (b) is a top view, (c) is A rear view, (d) is a front view, and (e) is a left side view. It is a graph which shows the relationship with a rigid increase rate by making ratio of the length of the shear reinforcement metal | frame with respect to the span of a deck plate into a horizontal axis. It is a graph which shows the relationship with a rigid increase rate by making ratio of the length between the shear reinforcement metal fittings with respect to the span of a deck plate into a horizontal axis. It is a perspective view of the conventional deck plate which shows the form which set the ratio of the width dimension of the lower flange in the deck plate, and the width dimension of the upper flange to the predetermined range. It is explanatory drawing which shows that an installation space becomes large when the deck plate of the form which does not use a brace is used for a roof structure. It is a figure which shows the conventional roof structure, Comprising: It is a figure which shows the form which equipment space becomes small by requiring a brace. (A) is a longitudinal front view showing a roof structure in a form in which a support member is interposed, and (b) is a side view of (a). (A) is sectional drawing which shows the relationship between the form shown in FIG. 23, and installation space, (b) is sectional drawing which shows the relationship between the form of the roof structure of this invention, and installation space, (c) is (b). It is a figure which expands and shows a part. It is a figure which shows the state which is carrying out distortion deformation, when an in-plane shear force acts on a deck plate by a horizontal force, (a) is a top view, (b) is a front view. It is a figure which shows the roof structure of the form which provides a heat insulating material and a waterproof sheet one by one on the deck plate constructed over the beam. The dimension of the deck plate used for the test body is shown, Comprising: (a) is a top view, (b) It is a front view. The state which attached the deck plate to the attachment part by the side of a shear bending test apparatus is shown, Comprising: (a) is a top view, (b) is a front view. It is explanatory drawing which shows the force direction which acts on a shear reinforcement metal fitting by the distortion deformation of a deck plate. The form of the shear reinforcement metal fitting which matches the bent corrugated deck plate and its trough part or peak part is shown, (a) is a front view, (b) is a top view of a shear reinforcement metal object. (A) is a front view of the deck plate of the other form used in this invention, (b) is a front view of the state which engaged the joint of the deck plate of another form used in this invention.

    Next, the present invention will be described in detail based on the illustrated embodiment.

  First, with reference to FIG.6 and FIG.27, the deck plate 1 which consists of one form of a folding plate with a joint used in this invention is demonstrated. The deck plate 1 formed of a folded plate with a joint in the form shown in the figure is integrally bent by a web 4 in which a horizontal lower flange 2 and a horizontal upper flange 3 are inclined by being continuously bent in the width direction of the strip steel plate. Each arm portion 5 is provided on both sides and parallel to the same surface as the lower flange 2, and a fitting joint is provided on a side edge of each arm portion 5. The fitting joint is a female fitting joint 6 that opens downward, and the other fitting joint is a male fitting joint 7 that projects upward, and has a trapezoidal square waveform as a whole.

  As shown in an enlarged view of FIG. 6 (b), the female fitting joint 6 includes an inner side plate 6a that rises from the arm portion 5, and is integrally bent with the inner side plate 6a. And an upper surface plate 6b parallel to the arm portion 5, and an inclined outer surface plate 6c that is integrally refracted integrally with the upper surface plate 6 and is inclined downward so as to approach the arm portion 5. A dovetail groove 10 opened downward is formed by the inner side surface plate 6a, the upper surface plate 6b, and the inclined outer surface plate 6c.

  The male fitting joint 7 includes an inclined side plate 7a that rises in an inclined manner so as to approach the folded plate main body side from the arm portion 5, and is refracted integrally with and separated from the folded plate main body. An upper surface plate 7b parallel to the arm portion 5, and the upper end level of the upper surface plate 7b is substantially equal to or slightly higher than the level of the bottom surface of the upper surface plate 6b in the female fitting joint 6. The level position.

  The deck plate 1 composed of a folded plate with a joint as described above is installed over a support beam, a support beam, or the like, and in the state where the folded plate 1 with one joint is installed, the male plate in the folded plate 1 with one joint is installed. The dovetail groove 10 of the female fitting joint 6 in the other folded plate 1 is disposed so as to cover the mold fitting joint 7 from above, and the male fitting joint 7 in the one folded plate 1 and The female fitting joint 6 in the other folded plate 1 with the joint is engaged so as to be engaged, and the joint fitting portion 8 is formed as shown in FIG.

  As shown in FIG. 25, when a horizontal force F acts on the deck plate 1 as described above, if the in-plane shear rigidity of the deck plate 1 is not large, as shown in FIG. The flange 3 and the lower flange 2 or the web 4 are distorted and deformed in a wave shape or the like and cannot exhibit the expected rigidity.

  Therefore, as shown in FIG. 1, in the embodiment of the present invention, the deck plates 1 made of folded plates with joints are arranged in parallel, and the male fitting joint 7 in one adjacent deck plate 1 and the other are connected. In the form of fitting the female fitting joints 6 in the deck plate 1 or the like, the upper trough 12 formed by the lower flange 2 in each deck plate 1 and between the webs 4 on both sides of the lower flange 2. Are effectively used or the valleys 12 formed between the webs 4 of the adjacent deck plates 1 are effectively used, and the valleys 12 in the individual deck plates 1 or the joint fitting portions of the adjacent deck plates 1 are used. In-plane shear rigidity of deck plate 1 when a horizontal force is applied during an earthquake or the like by installing shear reinforcement hardware 13 in trough 12 including 8 And so as to increase.

As the deck plate 1, in the illustrated form, the horizontal upper flange 3, the inclined web, and the horizontal lower flange 2 are in the form of a trapezoidal square waveform in a form in which the horizontal upper flange 3 and the horizontal lower flange 2 are provided continuously. Instead of the web 4, it may be in the form of a rectangular rectangular waveform with a vertical web 4, or it may be in the form of a sectional waveform in which unevenness is continuously curved.
Accordingly, the upper flange 3 and the lower flange 2 may be arc-shaped or arc-shaped in cross section, and the web 4 connecting them may be linear or curved. The reinforcement hardware 13 is arranged so as to match the outer surface of the trough 12 side, particularly the outer surface of each web 4, and so as to contact the upper surface of the lower flange 2 and the upper surface of the upper flange 3 in the deck plate 1. A side edge portion in the width direction of the rising portion 14 in the shear reinforcement hardware is formed, and an overhanging portion 15 in the shear reinforcement hardware 13 is provided.

Next, the shear reinforcement metal 13 used in the present invention will be described with reference to FIGS. 1 to 2 (a) to 2 (f). In the illustrated embodiment, the shear reinforcement metal 13 is the upper surface side of the deck plate 1. Therefore, the shape can be fitted to the valley 12. As shown in FIGS. 2 (a), 2 (b) and FIG. 3, the shear reinforcement hardware 13 is fitted into the valleys 12 on the upper surface side of the deck plate 1, and the webs 4 are opposed to each other at intervals in the valleys 12. And a protruding portion 15 (an upper protruding portion 15a and a lower protruding portion 15b) for fixing the shear reinforcement metal 13 to the deck plate 1.
More specifically, in the illustrated embodiment, the projecting portion 15 is connected to the upper portion of the rising portion 14 and has a width direction upper projecting portion 15a projecting in the width direction of the deck plate (waveform uneven direction), and a rising portion. 14 and a lower projecting portion 15b projecting in the extending direction of the deck plate.
The rising portion 14 is in a vertical (perpendicular) positional relationship with respect to the outer surface of the web 4 so that the rising portion 14 can be a member having the shortest dimension and is in contact with the outer surface of the web 4. When the protruding portion 15 (15a, 15b) includes the upper surface of the upper flange 3 or the upper surface of the lower flange 2 (in the case of a bending waveform, a part of the web 4 is disposed) 2 (c) and FIG. 4, a lower projecting portion 15b is provided on the lower side of the rising portion 14, as shown in FIG. 2 (d) and FIG. Further, upper and lower projecting portions 15a and 15b are provided on both upper and lower sides of the rising portion 14, respectively, or an upper projecting portion 15a is provided on the upper side of the rising portion 14 as shown in FIG. Kicking may be in the form.
In the case where the deck plate 1 has a bent waveform as described above, as shown in FIG. 30, the lower end side of the rising portion 14 and the lower projecting portion 15b are formed in accordance with the shapes of the valley 12 and the peak. (Or the form of the upper projecting portion 15a) may be an arcuate form such as an arcuate form.

Furthermore, in the illustrated shear reinforcement metal 13, for example, a steel sheet that has been cut into a predetermined shape is bent so that the lower ends of the parallel rising parts 14 are spaced apart from each other. A lower projecting portion 15b made of a flange extending horizontally outward is integrally bent and connected, and the rising portions 14 are connected to each other by an upper protruding portion 15 integrally bent and connected to each rising portion 14.
Depending on the cross-sectional shape of the valley portion 12, both end portions in the plate width direction of the rising portions 14 are in contact with the outer surface of the web 4 on the valley portion 12 side on the deck plate 1 side. Or it is set as the form which can be fitted from the edge part side of a groove | channel longitudinal direction. In the illustrated form, the rising portion 14 has a trapezoidal shape so that it gradually becomes wider from the bottom to the top.
The thickness of the shear reinforcing metal 13 is preferably the same as that of the deck plate 1 in terms of weight reduction. The shear reinforcement hardware 13 of the present invention is entirely (or substantially entirely) accommodated in the valley 12 of the deck plate 1, and the shear reinforcement hardware 13 (in the illustrated form, the rising portion 14 of the shear reinforcement hardware 13) is the deck plate. 1, even if the shear reinforcement metal piece 13 does not necessarily have a shape that matches the valley 12, the in-plane shear rigidity of the deck plate can be improved, and a horizontal force acts on the deck plate. In this case, an effect capable of preventing or suppressing distortion deformation of the deck plate 1 is obtained (this effect is the same effect in the above-described embodiment and all the forms described later). As the form in which the shear reinforcement metal 13 is in contact with the web 4 of the deck plate 1, point contact, line contact, or surface contact is conceivable, but line contact is better than point contact, the contact area is large, and the contact distance in the vertical direction. The longer the is, the higher the effect of preventing or suppressing the deformation of the deck plate 1.

The upper projecting portion 15a is a portion that is fixed to the upper flange 3 in the deck plate 1. Therefore, the upper projecting portion 15a is wider than the rising portion 14 and projects to the upper flange 3 side. The upper projecting portion 15a is fixed to the upper flange 3 of the deck plate 1 with a drill screw or the like. In the form in which the upper protruding portion 15a is provided with the rising portion 14 at an interval from the shear reinforcement metal 13, the upper protruding portion 15a is extended to the base flange side portion and the upper flange 3 side which are integrally provided to connect the rising portions 14 to each other. The overhanging portion 15 is integrally formed with the protruding upper end overhanging portion 15a (see FIG. 2a).
The lower projecting portion 15b is fixed to the lower flange 2 of the deck plate 1 with a drill screw or the like.

For example, the shear reinforcement hardware 13 is fitted and arranged so as to be in the same position on the end side in the longitudinal direction (extension direction) of each valley portion 12, and the drill plate 17 (see FIG. 1) or the like is used. By fixing a large number of shear reinforcement hardware 13 in a straight line, fixed to the flange 2 (3), the in-plane shear rigidity on each end side of the deck plate 1 is enhanced, and a horizontal force is applied during an earthquake or the like. In some cases, distortion deformation is suppressed.
When the shear reinforcement metal 13 is fixed, as shown in FIG. 29, when only the upper projecting portion 15 is fixed to the upper flange 3 in the deck plate 1, when the horizontal force F is applied, the shear reinforcement is performed. Since the lower overhanging portion 15 of the hardware 13 is not fixed, the shear reinforcement hardware 13 may be lifted by the distortion 16 of the upper flange 3, so that the shear reinforcement hardware 13 is the lower flange 2 in the deck plate 1. Fixing to the side is advantageous because it can prevent the shear reinforcement hardware 13 from being lifted. As a form for fixing the shear reinforcement metal 13, either one of the upper projecting portion 15a and the lower projecting portion 15b, or preferably both the upper and lower projecting portions 15a and 15b are fixed. When one of the upper projecting portion 15a and the lower projecting portion 15b is fixed, the other need not be provided.

Further, as shown in FIG. 2 (a), when the rising portion 14 provided in a vertical or inclined state in parallel with an interval is integrally connected using the upper projecting portion 15a as a connecting portion, When the reinforcing hardware 13 becomes a three-dimensional shape and is disposed in the valley portion 12 of the deck plate 1, the reinforcing hardware 13 can be made independent in a stable state. When such a self-supporting shear reinforcement metal 13 is fixed by a fastener such as a drill screw, the shear reinforcement metal 13 can be disposed in a stable state, and attachment with the drill screw is facilitated.
Although not shown in the figure other than the form shown in FIG. 2, for example, in the form shown in FIGS. 2A and 2B, the lower end sides of the rising parts 14 are made longer in the depth direction in the depth direction. Then, you may connect.

As shown in FIGS. 1 and 24 (c), the shear reinforcement hardware 13 is fixed to the deck plate 1 by using a drill screw 17 so that the overhanging portion 15 is attached to the lower flange 2 or the upper flange 3 of the deck plate 1. Secure to. For example, since the drill screw 17 can be joined up to a total thickness of about 13 mm with a steel plate thickness, the deck plate 1 may be fixed to the beam flange 38 with the drill screw 17 in some cases.
As a method for fixing the shear reinforcing metal 13 to the deck plate 1, other than a drill screw, a known appropriate form may be used as long as bolts / nuts, welding, scissors and the like can be fixed.

  As shown in FIG. 2 (b), a male fitting joint 7 and a female fitting joint 6 are provided on the side of the lower flange 2 in the deck plate 1 adjacent in the lateral direction, and these fitting joints are fitted to each other. In the joint fitting portion 8 that has been made, it is necessary to straddle the joint fitting portion 8 below the lower projecting portion 15b and the rising portion 14 of the shear reinforcement metal 13, and accordingly, as shown in FIG. As described above, the notch recess 18 is appropriately provided in the lower projecting portion 15b or the rising portion 14 so as not to interfere with the joint fitting portion 8.

For example, the shear reinforcement hardware 13 is installed at both ends in the longitudinal direction (extension direction) of each valley 12 in the deck plate 1 and fixed to the deck plate 1 or fixed to the beam side together with the deck plate 1. Either case is acceptable. In the form fixed by a drill screw, you may make it provide the front hole 42 (refer FIGS. 2-5) in the shear reinforcement metal fitting 13 side as needed.
In addition, as the shear reinforcement metal piece 13, the shear reinforcement metal piece 13 of the form shown in FIGS.
The form shown in FIG. 15 has a plurality of rising portions 14, and these rising portions 14 are shear reinforcement hardware 13 connected by an upper projecting portion 15 (15 a), and the upper flange 3 in the deck plate 1 is provided on the upper flange 3. This is a form in which the shear reinforcing metal piece 13 is not fixed.
In the case of each of the above forms, the plurality of rising portions 14 are connected by the upper protruding portion 15 (15b), and the protruding portion 15 (15a, 15b) is formed at the upper and / or lower portion by one rising portion 14. Although it is a form which has, as a form other than the above, the form which is not provided with the upper overhang | projection part 15 (15a) like the form shown in FIG.16 and FIG.17, for example may be sufficient. The form shown in FIG. 16 is a form in which the two rising parts 14 are directly connected (or connected by welding or the like) at the upper part thereof, and may be substantially inverted V-shaped (or triangular) as a whole in a side view. Good. The angles θ1 and θ2 formed between the rising portions 14 and the extended surfaces of the lower projecting portions 15 (15b) viewed from the side may be different angles as shown in FIG. 17 (e). The same angle as shown in FIG. In the case of such a configuration, since the upper projecting portion 15 (15a) is not provided, the lower projecting portion 15 (15b) is an essential shear reinforcement metal piece 13 for fixing to the deck plate 1.
It may be a shear reinforcing metal piece 13 that does not include the upper projecting portion 15 (15a) as shown in FIGS. Regarding the reinforcing effect on the in-plane shear rigidity of the deck plate 1, the two rising portions 14 suppress the deformation of the deck plate 1 (the collapse of the web 4), and therefore, a plurality of rising portions 14 shown in FIGS. Since it is equal to or greater than the substantially square-shaped shear reinforcement hardware 13 in a side view, the shear reinforcement hardware 13 can obtain a reinforcement effect equivalent to or greater than that of the shear reinforcement hardware 13 having the form shown in FIGS. Yes. 16 and 17, the shear reinforcement hardware 13 can be made lighter and cheaper than the shear reinforcement hardware 13 having a plurality of rising portions 14 shown in FIGS. .

  Next, the fixing method of the deck plate 1 and the beam side will be described. For example, as shown in FIG. 8, the deck plate 1 has lower flanges 2 at both ends in the longitudinal direction of the valleys 12, respectively. 10 is fixed by a firing driving rod 20, or fixed by a burnout plug weld 21 as shown in FIG. 9, or a cross section laid on a support beam 19 as shown in FIG. The drill member 17 is fixed to the C-shaped raising member 22.

  Next, a comparative experiment with and without the shear reinforcement hardware 13 will be described.

  Influence due to the joining position of the shear reinforcement metal 13 to the deck plate 1 (A), influence due to the length (length in the longitudinal direction of the groove) of the upper overhanging portion 15a in the shear reinforcement metal 13 (B), shear in the longitudinal direction of the valley 12 As for the influence (C) due to the arrangement position of the reinforcement hardware 13, a comparison experiment was performed with the case where the shear reinforcement hardware 13 was not arranged on the deck plate 1.

The deck plate 1 used in the test has the dimensions (mm) shown in FIG. 27 in both the present invention and the comparative example. The main dimensions are the thickness of the deck plate 1 being 1.0 mm, and the deck plate. 1 has a length of 3000 mm, and the deck plate 1 and the mounting portion 23 in the bending shear test device 24 (see FIG. 14) are connected in series to the lower flange 2 and the arm portion 5 as shown in FIG. Two places were fixed with launching rods 20.
The bending shear test apparatus 24 shown in FIG. 14 has a base end side of a pair of rotating frames 26 attached to a fixed support frame member 25 so as to be parallel to the fixed side supporting frame member 25 with a space therebetween. A movable frame 27 is disposed over the distal end of 26 and connected by a vertical axis so that a horizontal force F is input to one end side of the movable frame 27 by a jack.
The deck plate 1 having the shear reinforcement structure of the present invention, or such a shear reinforcement structure, is mounted over the attachment part 23 fixed to the fixed side support frame member 25 and the attachment part 23 fixed to the movable frame 27. The deck plate 1 of the form which is not equipped was set, and the displacement meters D1-D5 were set as shown in FIG. D1 to D5 measure horizontal displacement. The displacement on the movable side is determined by the average value measured by the displacement meters D2 and D3, and the displacement on the fixed side is determined by the average value measured by the displacement meters D4 and D5.

  As test specimens of the deck plate 1 shear-reinforced using the shear reinforcement hardware of various lengths and uniform thickness according to the present invention, FIGS. 11A to 11C and FIGS. b) In the form shown in FIGS. 13A to 13C, as a comparative example, it is a form that is not reinforced by such a shear reinforcement hardware. Table 1 shows the main elements of each specimen.

(Explanation of specimen name)
In the test body names in Table 1, the grooves described are reinforced by arranging shear reinforcement hardware 13 in valleys 12 (grooves) formed by the lower flange and the webs on both sides of the deck plate 1. It means that it is a form. For the next number 44, 40 or 04, the number on the left side means the number of joints between the lower projecting portion 15b of the shear reinforcement metal 13 and the lower flange 2 of the deck plate 1 and the number of drill screws 17. ing. The numbers on the right side mean the number of joints between the upper projecting portion 15a of the shear reinforcement metal 13 and the upper flange 3 of the deck plate 1 and the number of drill screws 17 (in Table 1, the upper flange joint portion). [Number of places] or lower flange joint [number of places].
The next numeral 88 or 176 or 264 means the dimension (mm) of the length of the upper part of the shear reinforcement metal piece 13 in the longitudinal direction of the valley 12 (in Table 1, the upper metal piece length l and Noted).

11 (a) to 11 (c), in all three deck plates 1, the end portion of the lower projecting portion 15b is positioned at a position 120 mm away from the end portion of the deck plate 1 with the shear reinforcing metal piece 13. Arranged. Further, the length of the upper overhanging portion 15a (the length of the deck plate in the groove longitudinal direction) in the shear reinforcement metal 13 was 88 mm.
In the specimen of the deck plate 1 shown in FIG. 11A, the shear reinforcement hardware 13 is installed on both ends in the longitudinal direction of the lower flange of the deck plate 1, respectively. The overhanging portion of the upper overhanging portion 15a of each shear reinforcement metal 13 is fixed to the upper flange 3 of the deck plate 1 by a drill screw in a total of four locations, and the lower overhanging portion 15b and the lower flange 2 of the deck plate 1 are fixed. It is a form in which a total of four places are fixed with two drill screws 17 and eight places as a whole.
In the specimen of the deck plate 1 shown in FIG. 11 (b), the lower overhanging portions 15b are not fixed to the deck plate 1, and the upper overhanging portions 15a are provided in only two places, four in total, and the shear reinforcement metal piece 13 is attached to the deck plate 1. It is the test body of the deck plate 1 fixed to. Except this, it is the same as FIG.
In the specimen of the deck plate 1 in FIG. 11 (c), contrary to FIG. 11 (b), the shear reinforcement hardware 13 is fixed to the deck plate 1 at two places, that is, at two places, a total of four places. This is a test piece of the deck plate 1 in a form in which the upper projecting portion 15 a is not fixed to the deck plate 1. Except this, it is the same as the case of FIG.
Tests on the above-described three types of the test specimen of the deck plate 1 having the shear reinforcement structure of the present invention and the comparative specimen (without reinforcement) which is not provided with the shear reinforcement hardware 13 and has no shear reinforcement structure. The results (the test results when the joining position of the shear reinforcing metal piece is changed and the influence of the joining position of the shear reinforcing metal piece 13) are shown in Table 2 below. From this result, it can be seen that the initial rigidity of the reinforcing structure of the present invention reinforced by the shear reinforcing metal piece 13 is higher by about 10% or 20% than the case where it is not reinforced by the shear reinforcing metal piece 13.
Further, compared to the case where the shear reinforcement metal piece 13 is fixed only to the upper flange 3, the initial rigidity is higher by about 10% or more when the shear reinforcement metal piece 13 is fixed only to the lower flange 2. You can see that
The reason for this will be briefly described with reference to FIG. 29. When a horizontal force is applied to a form in which only the upper projecting portion 15a of the shear reinforcement metal 13 is fixed to the upper flange 3 of the deck plate 1, the upper flange 3 is distorted. This is because the upper projecting portion 15a is pushed up so as to be deformed and curved, and the shear reinforcing metal piece 13 rotates so as to float up with the corner portion of one upper flange 3 as a fulcrum. Therefore, in the shear reinforcing metal 13 of the above embodiment, when the deck plate 1 is not joined to the lower flange 2, the shear reinforcing metal 13 is indicated by the arrow X due to the deformation of the upper flange 3 in the deck plate 1. Rotate to get out of deck plate 1. In addition, the deformation of the web 4 in the deck plate 1 may also be pushed up so that the shear reinforcement hardware 13 comes out. Accordingly, when the shear reinforcement metal 13 is fixed to the deck plate 1, if the lower overhanging portion 15 b is joined to the lower flange 2, the deck plate 1 can be fixed to the deck plate 1 rather than joining the upper overhanging portion 15 a to the upper flange 3. It can be seen that the rigidity can be improved efficiently.

Next, the upper overhanging portion 15a and the lower overhanging portion 15b of the shear reinforcement hardware 13 are fixed to the upper flange 3 and the lower flange 2 of the deck plate 1 (fixed in the same manner as shown in FIG. 11a), respectively. In the case where the shear reinforcement hardware 13 with the upper length l of the shear reinforcement hardware 13 with respect to the plate set to an integral multiple of 88 mm, 176 mm (2 times), 264 mm (3 times) in sequence is similarly installed at both ends of the deck plate 1 Were tested. The distance away from the end of the deck plate 1 of the shear reinforcement metal 13 was made constant as in FIG. 11a. The fixing form and the number of the shear reinforcing hardware 13 with respect to the deck plate 1 by the drill screw are the same as described above.
Table 3 below shows the test results of the effect of the upper length l of the shear reinforcement hardware (test results when the length of the shear reinforcement hardware is changed). From Table 3, the deck plate 1 has a length of 3000 mm. It can be seen that when the upper length l of the shear reinforcing metal piece 13 is in the range of 88 mm to 264 mm, the initial rigidity is improved as the upper length l of the shear reinforcing metal piece 13 is longer.

From the above results, as shown in FIG. 18, the ratio of the upper length l of the shear reinforcement hardware 13 to the span (deck span) L _d of the deck plate 1 (l / L _d ) is taken on the horizontal axis, and the vertical axis In the case of the embodiment of the present invention in which the shear reinforcement hardware 13 is provided on the deck plate 1, the rigidity increase rate is improved by about 20 to 30% compared to the case where the shear reinforcement hardware 13 is not provided. I understand that.

また、図１９に示すように、デッキプレート１のスパン（デッキスパン）Ｌ_dに対するせん断補強金物１３間の距離ｌ´´の比（ｌ´´／Ｌ_d）を横軸にとり、縦軸に剛性増加率をとった場合、せん断補強金物１３間の距離ｌ´´が長いほうが（換言すると、各せん断補強金物１３がデッキプレート１の端部側寄りにあるほうが）、せん断補強金物１３間の距離が短い場合（換言すると、各せん断補強金物１３がデッキプレート１の中央部側にある場合に）に比べて、剛性増加率が、約２割程度向上していることがわかる。 Next, when the shear reinforcement hardware 13 is not installed on the deck plate and when the shear reinforcement hardware 13 is installed on the deck plate, the position away from the end of the deck plate in the longitudinal direction is changed. did.
When the above-mentioned shear reinforcement metal fitting 13 was installed, the test was performed in the same manner as described above when the distance from the end of the deck plate 1 to the shear reinforcement metal fitting 13 was changed to 120 mm, 500 mm, and 1000 mm. The fixing form and the number of the shear reinforcing hardware 13 with respect to the deck plate 1 by the drill screw are the same as described above. The test results are shown in Table 4 as the influence of the position l ′ of the shear reinforcement metal 13, and from Table 4, the initial rigidity is improved in the reinforcement form installed on the end side of the deck plate 1 of the shear reinforcement metal 13. It turns out that there is a tendency to do.

Further, as shown in FIG. 19, the ratio (l ″ / L _d ) of the distance l ″ between the shear reinforcement hardware 13 to the span (deck span) L _d of the deck plate 1 is taken on the horizontal axis, and the rigidity is taken on the vertical axis. When the rate of increase is taken, the distance l ″ between the shear reinforcement hardware 13 is longer (in other words, each shear reinforcement hardware 13 is closer to the end side of the deck plate 1), and the distance between the shear reinforcement hardware 13 It can be seen that the rate of increase in rigidity is improved by about 20% compared to the case where is short (in other words, when each shear reinforcement metal 13 is on the center side of the deck plate 1).

  From the above test results, in order to make the structure reinforced so as to increase the in-plane rigidity that can prevent distortion deformation, the shear reinforcement metal 13 fixes the lower projecting portion 15b to the lower flange 2 of the deck plate 1 and shears it. It is desirable to provide a relatively long form of the shear reinforcement metal 13 between the rising portions 14 by bringing the reinforcement metal 13 toward each end in the longitudinal direction of the valley 12 of the deck plate 1.

When a plurality of the shear reinforcing metal pieces 13 are installed at intervals in the longitudinal direction of the valley portion 12 in the deck plate 1 as in the embodiment, a plurality of arrangements are arranged at intervals in the groove longitudinal direction of the deck plate 1. Even if a horizontal force acts on the deck plate 1 at the time of an earthquake, the horizontal force is prevented by preventing the web 4 or the upper and lower flanges 2 and 3 from being distorted and deformed along the longitudinal direction of the groove in the deck plate 1. The rigidity in the in-plane direction of the deck plate 1 when acting can be reinforced.
In addition, as in the above-described embodiment, the shear reinforcement hardware 13 is arranged in a straight line in the width direction of the deck plate 1 in the parallel valley portions 12 in the deck plate 1 (installed at the same position in the parallel valley portions 12). ), The shear reinforcement hardware 13 is installed in parallel at each valley 12 in the parallel valley 12, and in each valley 12 in the deck plate width direction. It is possible to prevent the web 4 and the upper and lower flanges 2 and 3 from being distorted and to uniformly reinforce the trough portions (portions installed on the end side, etc.) of the deck plate over the width direction of the deck plate.

  Next, the roof structure employing the deck plate mutual connection structure of the present invention will be described. As shown in FIGS. 24 (b), (c) and FIG. 26, steel roofs installed at intervals in the front-rear direction. The deck plates 1 are sequentially installed in parallel in the left-right direction across the beams 19, and the female mold in the deck plate 1 to be installed next to the male fitting joint 7 in one adjacent deck plate 1 is installed. The fitting joint 6 is brought into a fitted state, and each deck plate 1 is fixed to the flange 38 of each beam 19 with the lower flange 2 or the arm portion 5 by a fixing means such as a launching rod. In addition, each trough 12 in each deck plate 1 and the trough 12 of the joint fitting portion 8 formed by the web 4 of the adjacent deck plate 1 are respectively provided with the shear reinforcement hardware 13 or the notch recess 18. (Refer to FIG. 7), the upper and lower projecting portions 15a and 15b of both of the shear reinforcement hardware 13 or upper and lower projecting portions 15a and 15b of both of them are arranged on the deck plate 1. It is fixed to the lower flange 2 or the upper flange 3 with a drill screw 17.

As described above, after the deck plates are fitted to each other and the shear reinforcement hardware is installed, the heat insulating plate 40 made of hard urethane foam, polystyrene foam, polyethylene foam, glass wool, rock wool or the like is placed on the deck plate (see FIG. 26) are arranged and fixed appropriately, the heat insulating plates 40 are connected and installed with a fireproof adhesive tape, and a waterproof sheet 41 such as a vinyl chloride sheet is provided on the heat insulating plate 40.
A fire-proof material may be used instead of the heat insulating plate 40, and the fire-proof material in that case is a non-flammable material (a non-flammable material is a material that does not burn for at least 5 minutes after the start of heating). For example, a non-combustible material such as stone (grain or lump or plate), glass, glass wool board, concrete, wood cement board, or gypsum board may be used.
One of the heat insulating material 40 and the nonflammable material may be laid on the deck plate, and the other may be laid sequentially, and then a waterproof sheet may be laid.
Instead of the waterproof construction method using the waterproof sheet, other known waterproof construction methods such as a modified asphalt sheet and a waterproof construction method using a rubber-based sheet may be adopted.
When the roof structure as shown in FIGS. 24B, 24C and 26 is used, the deck plates adjacent to each other in the lateral direction are surely integrated with a simple structure, and in-plane shear rigidity without using braces. In particular, it is possible to form a deck plate group having a large effect of preventing distortion deformation of the web 4 and the flanges 2 and 3 of the upper and lower portions of the deck plate 1, so that it can be deformed when a horizontal force is applied during an earthquake or the like. On the other hand, a roof structure having a deck plate having a high resistance can be obtained, and the equipment space 35 under the deck plate can be increased.

In the above-described embodiment, the form in which the two rising portions 14 are connected by the upper projecting portion 15a has been shown. However, when the present invention is implemented, the three rising portions 14 are spaced apart from each other, although not illustrated. It is good also as a form which provided integrally the upper overhang | projection part 15a or the lower overhang | projection part 15b provided over these.
In the case of the above embodiment, the form in which the shear reinforcement metal piece 13 is arranged from the upper side of the deck plate 1 is illustrated. However, in the case where the trough portion 12 has a dovetail shape with the lower part widened, the shear reinforcement metal piece 13 is provided. Alternatively, it may be inserted from the axial direction of the deck plate 1.

The cross-sectional shape of the deck plate 1 used in the present invention may be other cross-sectional shapes. For example, in the case of the deck plate 1 having a convex portion 43 as shown in FIG. 43, or when the stepped portion is formed by overlapping the arm portions 5 in the adjacent deck plates 1 as shown in FIG. 31 (b). What is necessary is just to set it as the form which provides a step part corresponding to the said step part in an overhang | projection part and a standing | starting-up part, and should just be a shear reinforcement metal fitting of the form which can respond according to the cross-sectional form of a deck plate.
Further, as the form of the shear reinforcing metal 13 used in the present invention, illustration is omitted in addition to the above form, but for example, the side end of one rising part 14 (or the side end of both rising parts 14) The rising portion 14 may be reinforced as a form having side plates so as to be connected to each other), and the side plate, the rising portion 14, and the web of the deck plate 1 may be surface-touched. Good. It is desirable that the rising portion 14 is arranged perpendicular to the surface of the web 4 because the rising portion 14 reliably resists deformation of the web 4.
When the present invention is implemented, for example, in FIGS. 3 (d), 7 (d), and 15 (d) to 17 (d), a rising portion is integrally formed with the lower left projecting portion 15 (15b). 14 or by repeatedly providing an upper projecting portion (or a downward rising portion 14) on the upper portion of the rising portion 14, the shear reinforcing metal piece 13 having three or more rising portions 14 may be used. .

DESCRIPTION OF SYMBOLS 1 Deck plate 2 Lower flange 3 Upper flange 4 Web 5 Arm part 6 Female type fitting joint 6a Inclined inner side surface plate 6b Top surface plate 6c Inclined outer side surface plate 7 Male type fitting joint 7a Inclined side surface plate 7b Upper surface plate 8 Joint fitting part 9 Inclined outer surface 10 Dovetail groove 11 Groove 12 Valley portion 13 Shear reinforcement hardware 14 Rising portion 15 Overhanging portion 15 Overhanging portion 15b Lower overhanging portion 15a Upper overhanging portion 16 Distortion deformation 17 Drill screw 18 Notch recess 19 Support beam 20 Launching rod 21 Tempering stopper welding 22 Raising member 23 Mounting portion 24 Bending shear test device 25 Fixed side support frame material 26 Rotating frame 27 Movable frame 30 Brace 31 Ceiling 32 Field edge 33 Roof 34 Space 35 Equipment space 36 Bending plate 37 Support member 38 Upper flange (beam)
39 Lower flange (bending plate)
40 heat insulating plate 41 waterproof sheet 42 leading hole 43 convex portion

Claims (8)

  A deck plate reinforcing structure in which an upper flange and a lower flange are formed via a web, and an in-plane of the deck plate is formed in a trough formed by webs facing each other at an interval on the upper surface of the lower flange. A shear reinforcement metal for increasing the shear rigidity is disposed, and the shear reinforcement metal is provided with a rising portion that fits in the valley while being in contact with the web and extends between opposing webs in the valley, and the rising portion The deck plate has an overhanging portion that projects horizontally in an integrated manner, and the overhanging portion is fixed to the deck plate.   The deck plate in-plane shear reinforcement structure according to claim 1, wherein a plurality of the shear reinforcement hardware are provided at intervals in the longitudinal direction of the valley portion in the deck plate.   The in-plane surface of the deck plate according to claim 1 or 2, wherein the shear reinforcement hardware is respectively installed in parallel in the width direction of the deck plate in the parallel valley portions in the deck plate. Shear reinforcement structure.   The shear reinforcement hardware has an upper projecting portion projecting in the deck plate width direction above the rising portion and a lower projecting portion projecting in the deck plate extending direction at the lower portion, and the upper projecting portion and the lower projecting portion are fixed to the deck plate. The deck plate in-plane shear reinforcement structure according to claim 1, wherein the deck plate has an in-plane shear reinforcement structure.   A deck plate is installed across the beam, and the deck plate is reinforced by the in-plane shear reinforcement structure of the deck plate according to any one of claims 1 to 4, and the deck plate and the shear reinforcement hardware A roof structure provided with a deck plate, characterized in that a heat insulating plate and / or a fireproof material is installed on the top, and a waterproof sheet is provided on the heat insulating plate and / or the fireproof material.   A shear reinforcing metal fitting installed to increase in-plane shear rigidity of a deck plate in which an upper flange and a lower flange are connected via a web and are alternately formed with a crest and a trough, the shear reinforcing metal Is provided with a rising portion that fits in the valley portion while being in contact with the web and extends between opposing webs in the valley portion, so that the rising portion integrally projects in the horizontal direction and is fixed to the deck plate. Shear reinforcement hardware for deck plates, characterized by having an overhanging portion.   7. The deck plate for a deck plate according to claim 6, wherein the shear reinforcement hardware includes rising portions at intervals in the groove longitudinal direction of the deck plate, and each rising portion is integrally connected to the projecting portion. Shear reinforcement hardware.   The shear reinforcement metal fitting for a deck plate according to claim 6, wherein the projecting portion is provided on either one or both of a lower end portion and an upper end portion of the rising portion.

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