JP2020159155A - Deck plate unit, joint member, connection method of deck plate and construction method of floor slab - Google Patents

Abstract

To obtain an excellent workability of a floor slab, etc. in construction and remove a deck plate easily after construction.SOLUTION: A deck plate unit (1) comprises a deck plate (10) having a flat flange part (11) and a joint member (20) having one end connected to the flange part (11) of the deck plate (10) and the other end connected to another member (B, 200).SELECTED DRAWING: Figure 1

Description

The present invention relates to a deck plate unit, a joint member, a method of connecting a deck plate, and a method of constructing a floor slab.

A flat deck plate used as a formwork for a concrete structure is known at a construction site where concrete slabs constituting the floor and ceiling of a building are constructed. When installing a flat deck plate on a steel beam, the deck plate is fixed to the upper surface of the steel beam by welding. In addition, when installing a flat deck plate on a reinforced concrete beam, the deck plate is placed and fixed on the concrete formwork, and the end of the deck plate is installed so as to protrude to the inside surrounded by the formwork. However, it is integrated with the reinforced concrete beam. After the deck plate is installed, concrete is cast on the deck plate to form a slab. In such a construction method, since the deck plate is integrated with the solidified concrete, there is a problem that the deck plate cannot be removed after the construction and it is difficult to reuse it.

As a method for solving the above problem, for example, a formwork support tool is known in which a deck plate is supported in a pressure-welded state from below during construction, and the support is released after construction so that the deck plate can be removed. For example, see Patent Document 1). Further, as another method, for example, a formwork material is known in which a deck plate having a slide mechanism is adopted and the deck plate can be removed after construction by adjusting the position of connecting the deck plate to the support beam. (See, for example, Patent Document 2).

Japanese Unexamined Patent Publication No. 2015-105552 Japanese Unexamined Patent Publication No. 2004-257228

However, in the method as described in Patent Document 1, it is necessary to use a support for fixing the deck plate, which may cause excessive labor in the construction work. Further, in the method as described in Patent Document 2, it is necessary to prepare a deck plate having a slide mechanism, and the weight of the deck plate becomes high, which hinders the construction work. In addition, when connecting the deck plate to the support beam, in order to make the deck plate removable after construction, alignment with the support beam is an important work, which reduces workability during construction. was there.

Therefore, the present invention has been made in view of the above problems, and an object of the present invention is to provide a deck plate unit which is excellent in workability during construction and whose deck plate can be removed after construction.

In order to solve the above problems, the first aspect of the present invention is a deck plate having a flat flange portion, and a joint having one end connected to the flange portion of the deck plate and the other end connected to another member. Has a member.

Further, it is preferable that the joint member is connected to the flange portion of the deck plate in a state of being arranged above the flange portion of the deck plate.

Further, the flange portion of the deck plate and the joint member have an insertion hole through which a connecting tool is inserted, and the joint member is a flange of the deck plate via a connecting tool inserted through the insertion hole. It is preferable that the unit is connected to the unit.

Further, it is preferable that at least one of the insertion hole of the flange portion of the deck plate and the insertion hole of the joint member has an elongated hole shape extending along the longitudinal direction of the flange portion of the deck plate.

Further, one end is further connected to the flange portion of the deck plate, and the other end is further provided with an adjusting member connected to the joint member, and the joint member is attached to the flange portion of the deck plate via the adjusting member. It is preferable that they are connected.

Further, it is preferable that the other member is fixed to a beam of a structure or a formwork for constructing the beam.

Further, it is preferable that the other member is a second deck plate having a flat flange portion, and the joint member is connected to the flange portion of the second deck plate at the other end.

Further, one end is connected to the flange portion of the deck plate and the other end is connected to the flange portion of the second deck plate in a state of being arranged below the flange portion of the deck plate and the flange portion of the second deck plate. It is preferable that the joint auxiliary member is further provided, and the joint member is connected to the flange portion of the deck plate and the flange portion of the second deck plate at a position corresponding to the joint auxiliary member. ..

Further, it is preferable that the joint member has a spacer having a pair of legs erected from the main body and a bridge portion connecting the legs.

Further, it is preferable that the joint member has a plurality of the spacers, and the joint member further has a reinforcing portion for connecting the plurality of spacers.

A second aspect of the present invention is a joint member, which connects a deck plate and a support beam and is embedded in concrete forming a part of a floor slab. It has a first connecting portion formed on the main body portion and connected to the deck plate, and a second connecting portion connected to the support beam.

Further, it is preferable to further have a spacer including a pair of legs erected from the main body and a bridge portion connecting the legs.

A third aspect of the present invention is a method of connecting a deck plate having a flat flange portion to another member, in a state where the joint member is arranged above the deck plate. It includes a step of connecting one end of the joint member and a flange portion of the deck plate, and a step of connecting the other end of the joint member and the other member.

A fourth aspect of the present invention is a method for constructing a floor slab in which a deck plate having a flat flange portion is fixed to a support beam and concrete is placed on the deck plate. In a state where the joint member is arranged above, a step of connecting one end of the joint member and a flange portion of the deck plate, a step of connecting the other end of the joint member to the support beam, and the joint member and the said It includes a step of placing concrete on the deck plate and a step of releasing the connection between the joint member and the flange portion of the deck plate and removing the deck plate in a state where the concrete is solidified.

According to the aspect of the present invention, the workability at the time of construction of a floor slab or the like is excellent, and the deck plate can be easily removed after construction.

FIG. 5 is a perspective view showing a configuration in which (a) a joint member is connected to a support beam made of a vertical crosspiece, a horizontal crosspiece, and plywood in the deck plate unit according to the first embodiment, and (b) the joint member is a steel frame beam. It is a perspective view which shows the structure connected to. It is a perspective view which shows the structure of the deck plate which comprises the deck plate unit shown in FIG. It is a perspective view which shows the structure of the joint member which comprises the deck plate unit shown in FIG. (A) A side view showing a state in which a joint member fixed to the support beam B and a deck plate are connected, and (b) a side view showing a state in which a joint member fixed to the support beam B and a deck plate are connected. It is a side view which shows the state which (c) a joint member and a deck plate are connected. It is a perspective view which shows the structure of the adjustment member which comprises the deck plate unit which concerns on the modification of 1st Embodiment. (A) A side view showing a state in which a joint member fixed to the support beam B is connected to an adjusting member and a deck plate, and (b) a side view showing a state in which the joint member, the adjusting member and the deck plate are connected. Is. It is a perspective view which shows the structure of the joint member which comprises the deck plate unit which concerns on 2nd Embodiment. It is a side view which shows the state which connects the two deck plates with each other through a joint member. It is a perspective view which shows the structure of the joint auxiliary member which comprises the deck plate unit which concerns on the modification of the 2nd Embodiment. It is a side view which shows the state which the two deck plates are connected with each other through a joint member and a joint auxiliary member.

A preferred embodiment of the present invention will be described with reference to the drawings. The embodiment shown below is an example, and various forms can be taken within the scope of the present invention.

[First Embodiment]
<Structure of deck plate unit>
The configuration of the deck plate unit according to the first embodiment will be described with reference to FIGS. 1 to 3.
The deck plate unit 1 is used, for example, as a formwork for forming a floor slab, and is attached to a support beam B of a concrete structure such as a building. As shown in FIG. 1A, the deck plate unit 1 has a deck plate 10 and a joint member 20. The deck plate unit 1 is used in a state where the deck plate 10 is connected to one end side of the joint member 20 and the support beam B is connected to the other end side of the joint member 20 at the time of construction. The support beam B is formed of, for example, a vertical crosspiece b1, a horizontal crosspiece b2, and a plywood b3. The configuration of the support beam B is not limited to this, and various shapes and materials may be applied, for example, as shown in FIG. 1B, the support beam B is composed of a steel frame.
Hereinafter, for convenience of explanation, the expressions "longitudinal direction L" will be used for the direction along the longitudinal direction of the deck plate 10, and "width direction W" will be used for the direction along the width direction of the deck plate 10.

(Deck plate)
The deck plate 10 is called a flat deck, for example, and is made of a thin steel plate. As shown in FIG. 2, the deck plate 10 has a flat flange portion 11 and a hollow rib 12 having a substantially triangular cross section.
The flange portion 11 is provided between the ribs 12 adjacent to each other in the width direction W. The flange portion 11 forms a molded surface of a slab made of concrete as a formwork during construction. An elongated hole-shaped insertion hole 11a extending along the longitudinal direction L of the deck plate 10 is formed on one end side of the flange portion 11. A connecting tool (bolt 42a; see FIG. 4) used for connecting the flange portion 11 and the joint member 20 is inserted into the insertion hole 11a. Since the insertion hole 11a has an elongated hole shape, the operator adjusts the connection position between the flange portion 11 and the joint member 20 in the longitudinal direction L according to the length of the deck plate 10 in the longitudinal direction L. be able to.
A plurality of ribs 12 are arranged along the longitudinal direction L. The rib 12 is integrally formed with the flange portion 11 to increase the strength of the deck plate 10.
In the present embodiment, the deck plate 10 has been described in which the rib 12 is formed over the entire length of the flange portion 11, but the present invention is not limited to this. A deck plate that has been flattened by crushing the end portion of the rib 12 in the longitudinal direction (end closing process) may be applied.

(Joint member)
The joint member 20 is interposed between the deck plate 10 and the support beam B, and connects the deck plate 10 and the support beam B. As shown in FIG. 3, the joint member 20 has a main body portion 21, a spacer 24, and a reinforcing portion 25. When the joint member 20 is connected to the deck plate 10, the length of the deck plate 10 along the longitudinal direction L is shorter than the length along the width direction W.
The main body 21 has a substantially rectangular flat plate shape, and is formed of, for example, a thin steel plate. The main body 21 has a first connection 22 and a second connection 23.
The first connecting portion 22 is provided on one end side of the main body portion 21 in the longitudinal direction L. The first connecting portion 22 is connected to the flange portion 11 of the deck plate 10. The first connecting portion 22 has a plurality of elongated hole-shaped insertion holes 22a extending along the longitudinal direction L. The insertion holes 22a are formed at intervals in the width direction W. A connecting tool (bolt 42a), which will be described later, is inserted into the insertion hole 22a when the flange portion 11 and the joint member 20 are connected to each other. Since the insertion hole 22a has an elongated hole shape, the operator adjusts the connection position between the flange portion 11 and the joint member 20 in the longitudinal direction L according to the length of the deck plate 10 in the longitudinal direction L. be able to.
The second connecting portion 23 is provided on the other end side (opposite side of the first connecting portion 22) of the main body 21 in the longitudinal direction L. The second connecting portion 23 has a plurality of circular insertion holes 23a formed at intervals in the width direction W. A connecting tool (nail 41; see FIG. 4) is inserted into the insertion hole 23a when the joint member 20 and the support beam B are connected to each other. The shape of the insertion hole 23a is not limited to this. The insertion hole 23a may have an elongated hole shape similar to the insertion hole 22a of the first connection portion 22. The insertion hole 23a is arranged on a straight line along the insertion hole 22a of the first connection portion and the longitudinal direction L. The position where the insertion hole 23a is arranged is not limited to this, and may be changed as appropriate.

The spacer 24 is, for example, formed by bending a bar-shaped steel (reinforcing bar). The spacer 24 serves as a bar arrangement member for arranging the lower end bar in a state of being floated from the deck plate 10. Further, the spacer 24 increases the strength of the main body 21 in the longitudinal direction L. Further, the spacer 24 serves as a handle used by the operator to carry the joint member 20 at the time of construction. The spacer 24 has a pair of standing portions 24a erected on the upper surface of the main body portion 21 and a bridge portion 24b connecting the upper ends of the standing portions 24a. One of the pair of standing portions 24a is erected on one end side (first connection portion 22 side) of the main body portion 21, and the other of the pair of standing portions 24a is erected on the other end side of the main body (second connection portion). It is erected on the side of part 23). The base end portions of the pair of standing portions 24a are joined to the main body portion 21 by welding or the like. The connecting portion between the upright portion 24a and the bridge portion 24b is formed by being curved in an arc shape. In the present embodiment, two spacers 24 are formed in the vicinity of both ends of the main body 21 in the width direction W, but the present invention is not limited to this. The spacer 24 may be added in order to improve the strength of the main body 21.

The reinforcing portion 25 is formed of, for example, a linear bar-shaped steel (reinforcing bar). Similar to the spacer 24, the reinforcing portion 25 serves as a reinforcing bar arranging member for arranging the lower end reinforcing bars in a state of being floated from the deck plate 10. Further, the reinforcing portion 25 increases the strength of the main body portion 21 in the width direction W. Both ends of the reinforcing portion 25 are joined to the bridge portion 24b of the spacer 24 by welding or the like. Both ends of the reinforcing portion 25 protrude to the outside of the spacer 24 in the width direction W.

<Construction method using deck plate unit>
A method of constructing a floor slab using the deck plate unit 1 will be described with reference to FIG.
First, as shown in FIG. 4A, the first connecting portion 22 of the joint member 20 is connected to the flange portion 11 of the deck plate 10. Specifically, the flange portion 11 is arranged below the first connecting portion 22 of the joint member 20. At this time, the flange portion 11 is arranged below the first connection portion 22 so that the insertion hole 11a of the flange portion 11 and the insertion hole 22a of the first connection portion 22 communicate with each other. The position where the flange portion 11 is arranged is adjusted along the longitudinal direction L according to the length of the deck plate 10 in the longitudinal direction L. In this state, the bolts 42a forming a part of the connecting tool are inserted into the insertion holes 11a and 22a communicating with each other from above the first connecting portion 22. A washer 42c forming a part of the connecting tool is interposed between the bolt 42a and the first connecting portion 22. The tip of the inserted bolt 42a protruding below the flange portion 11 is fastened via a washer 42c by a nut 42b forming a part of the connector. As a result, the deck plate 10 and the joint member 20 are connected.

Next, as shown in FIG. 4B, the second connecting portion 23 of the joint member 20 is connected to the support beam B. Specifically, in a state where the second connecting portion 23 of the joint member 20 is placed on the cross rail b2 of the support beam B, the nail 41 constituting the connecting tool is second from above the second connecting portion 23. By being inserted into the insertion hole 23a of the connecting portion 23, the support beam B is driven into the horizontal crosspiece b2. As a result, the joint member 20 is fixed to the support beam B. In this way, the deck plate unit 1 is connected to the support beam B.

As shown in FIG. 4C, concrete C is cast on the upper surface of the deck plate unit 1 in a state where the deck plate unit 1 is joined to the support beam B. Specifically, concrete C is placed in a state where reinforcing bars (not shown) are arranged above the spacer 24 and the reinforcing portion 25 of the joint member 20. The joint member 20 is fixed to the concrete C (floor slab) by embedding the spacer 24 and the reinforcing portion 25 in the placed concrete C.
When the concrete C is solidified, the deck plate 10 is removed from the frame shape of the floor slab by disconnecting the deck plate 10 and the joint member 20. Specifically, the nut 42b used for fastening (connecting) the flange portion 11 of the deck plate 10 and the first connecting portion 22 of the joint member 20 is removed from the bolt 42a. As a result, the connection between the deck plate 10 and the joint member 20 is released. In this state, the operator can remove the deck plate 10 from the floor slab by pulling the deck plate 10 downward.

As described above, by using the deck plate unit 1 composed of the deck plate 10 and the joint member 20, the deck plate 10 is joined to the support beam B via the joint member 20. As a result, even when the concrete C is cast on the upper surface of the deck plate 10, the deck plate 10 can be easily removed from the floor slab by disconnecting the joint member 20 and the deck plate 10. it can. As a result, the deck plate 10 can be reused as a formwork for forming the floor slab.
Further, since the spacer 24 to which the reinforcing portion 25 is attached is fastened to the support beam B, the floor slab and the support beam B can be more firmly integrated by embedding them in the concrete C. ..

[Modified example of the first embodiment]
The deck plate unit 1 according to the first embodiment is not limited to the above configuration. For example, the configurations shown in FIGS. 5 and 6 can be applied.
The deck plate unit 1a according to the modified example has an adjusting member 30 in addition to the deck plate 10 and the joint member 20. Hereinafter, the description of the same configuration as that of the deck plate unit 1 will be omitted.

The adjusting member 30 is provided between the deck plate 10 and the joint member 20, and serves as an intermediate member for connecting the deck plate 10 and the joint member 20. For example, in order to make up for the insufficient length (support length) of the deck plate 10 when the length of the deck plate 10 attached between the two support beams B is not sufficient for the distance between the support beams B. used. As shown in FIG. 5, the adjusting member 30 has a flat plate shape on a substantially rectangular shape, and is formed of, for example, a thin steel plate. The adjusting member 30 has a long hole-shaped first insertion hole 30a formed on one end side (deck plate 10 side) in the longitudinal direction L and a length formed on the other end side (joint member 20 side) in the longitudinal direction L. It has a hole-shaped second insertion hole 30b. The first insertion hole 03a and the second insertion hole 30b have an elongated hole shape extending along the longitudinal direction L of the deck plate 10. Since the first insertion hole 30a and the second insertion hole 30b have an elongated hole shape, the operator can connect the flange portion 11 and the adjusting member 30 according to the length of the deck plate 10 in the longitudinal direction L. The position and the connection position between the joint member 12 and the adjusting member 30 can be adjusted in the longitudinal direction L.

As shown in FIG. 6A, in the construction of the floor slab, the second connecting portion 23 of the joint member 20 is first connected to the support beam B. On the other hand, the deck plate 10 is fixed in a state where the lower end portion of the rib 12 is supported by the support S. Next, one end of the adjusting member 30 is arranged above the flange portion 11 of the deck plate 10, and the other end of the adjusting member 30 is arranged below the first connecting portion 22 of the joint member 20.
At this time, the adjusting member 30 is arranged above the flange portion 11 so that the insertion hole 11a of the flange portion 11 and the first insertion hole 30a of the adjusting member 30 communicate with each other. Further, the adjusting member 30 is arranged below the first connecting portion 22 so that the insertion hole 22a of the first connecting portion 22 and the second insertion hole 30b of the adjusting member 30 communicate with each other. In this state, the flange portion 11 and the adjusting member 30, and the joint member 20 and the adjusting member 30 are connected to each other by using connecting tools (bolts 42a, nuts 42b and washers 42c). Since the connection method using the connector is the same as that of the above embodiment, it will be omitted. In this way, the deck plate unit 1 is connected to the support beam B.

As shown in FIG. 6B, concrete C is cast on the upper surface of the deck plate unit 1 in a state where the deck plate unit 1 is connected to the support beam B.
After the concrete C has solidified, the support work S supporting the deck plate 10 is removed to complete the connection work. In this state, the deck plate 10 and the adjusting member 30 are removed from the frame shape of the floor slab by releasing the fastening state of the nut that has fastened the adjusting member 30 and the first connecting portion 22.

As described above, by interposing the adjusting member 30 between the deck plate 10 and the joint member 20, even in a configuration in which the support length of the deck plate 10 needs to be adjusted, after construction (after placing concrete C). ), The deck plate 10 can be easily removed from the frame shape of the floor slab. Further, by using the adjusting member 30, the length that is insufficient to support the deck plate 10 can be supplemented, so that the total length of the deck plate 10 can be shortened. This makes it easy to handle the deck plate 10.

[Second Embodiment]
<Structure of deck plate unit>
The deck plate unit according to the second embodiment of the present invention will be described with reference to FIGS. 7 and 8.
The deck plate unit 100 according to the present embodiment is used for connecting to another deck plate instead of the support beam B in the first embodiment. That is, the deck plate unit 100 is used when two deck plates are joined to each other via a joint member. At the construction site, depending on the distance between the support beams B, the worker may connect the deck plates to each other for use. In such a case, the deck plate unit 100 according to the present embodiment is applied. In the present embodiment, for convenience of explanation, the deck plate forming a part of the deck plate unit 100 is set as the first deck plate 110, and another deck plate connected to the deck plate unit 100 is used as the second deck. Let it be plate 200.
The deck plate unit 100 has a first deck plate 110 and a joint member 120. The deck plate unit 100 is used in a state where the first deck plate 110 is connected to one end side of the joint member 120 and the second deck plate 200 is connected to the other end side of the joint member 120 at the time of construction. .. The configuration of the first deck plate 110 and the second deck plate 200 is the same as the configuration of the deck plate 10 according to the first embodiment, and thus the description thereof will be omitted.

(Joint member)
As shown in FIG. 7, the joint member 120 is interposed between the first deck plate 110 and the second deck plate 200, and connects the first deck plate 110 and the second deck plate 200. The joint member 120 has a main body portion 121, a spacer 124, and a reinforcing portion 125.
The main body 121 has a substantially rectangular flat plate shape, and is formed of, for example, a thin steel plate. The main body 121 has a first connecting portion 122 and a second connecting portion 123.
The first connecting portion 122 is provided on one end side of the main body portion 121 in the longitudinal direction L. The first connecting portion 122 is connected to the flange portion 111 of the first deck plate 110. The first connecting portion 122 has a plurality of elongated hole-shaped insertion holes 122a formed at intervals in the width direction W. The insertion hole 122a is formed so as to extend along the longitudinal direction L. A connecting tool (bolt 42a) is inserted into the insertion hole 122a when the flange portion 111 and the joint member 120 are connected to each other. Since the insertion hole 122a has an elongated hole shape, the operator sets the connection position between the flange portion 111 and the joint member 120 in the longitudinal direction L according to the length of the first deck plate 110 in the longitudinal direction L. Can be adjusted in.
The second connecting portion 123 is provided on the other end side of the main body portion 121 in the longitudinal direction L. The second connecting portion 123 has a plurality of elongated hole-shaped insertion holes 123a formed at intervals in the width direction W. The insertion hole 123a is formed so as to extend along the longitudinal direction L. A connecting tool (bolt 42a) is inserted into the insertion hole 123a when the flange portion 201 of the second deck plate 200, which will be described later, and the joint member 120 are connected to each other. Since the insertion hole 123a has an elongated hole shape, the operator sets the connection position between the flange portion 201 and the joint member 120 in the longitudinal direction L according to the length of the second deck plate 200 in the longitudinal direction L. Can be adjusted in. The insertion hole 123a of the second connection portion 123 is arranged on a straight line along the insertion hole 122a of the first connection portion 122 and the longitudinal direction L.

The spacer 124 is, for example, formed by bending a bar-shaped steel (reinforcing bar). Since the role of the spacer 124 is the same as that of the spacer according to the first embodiment, the description thereof will be omitted. The spacer 124 has a pair of standing portions 124a erected on the upper surface of the main body 121 and a bridge portion 124b connecting the upper ends of the standing portions 124a. One of the pair of standing portions 124a is erected on one end side (first connection portion 122 side) of the main body portion 121, and the other of the pair of standing portions 124a is erected on the other end side of the main body portion 121 (the first). 2 It is erected on the connection part 123 side). The base end portions of the pair of standing portions 124a are joined to the main body portion 121 by welding or the like. The connecting portion between the upright portion 124a and the bridge portion 124b is formed by being curved in an arc shape. In the present embodiment, four spacers 124 are formed according to the positions between both ends of the main body 121 in the width direction W and the adjacent insertion holes 122a and 123a in the width direction W. The number of spacers 124 installed may be changed in order to appropriately adjust the strength of the main body 121.

The reinforcing portion 125 is formed of, for example, a linear bar-shaped steel (reinforcing bar). Since the role of the reinforcing portion 125 is the same as that of the reinforcing portion according to the first embodiment, the description thereof will be omitted. The reinforcing portion 125 is joined to the bridge portion 124b of the spacer 124 by welding or the like. Both ends of the reinforcing portion 125 protrude to the outside of the spacer 124 in the width direction W.

<Joining method using deck plate unit>
A method of joining two deck plates using the deck plate unit 100 will be described with reference to FIG.
As shown in FIG. 8, the first deck plate 110 and the second deck plate 200 are arranged in a state of being butted with a gap. At this time, the first deck plate 110 and the second deck plate 200 are fixed in a state where the ends of the ribs 112 and 202 are supported by the support S.
In this state, the joint member 120 is arranged above the first deck plate 110 and the second deck plate 200. Specifically, the first connection portion 122 of the joint member 120 is arranged above the flange portion 111 of the first deck plate 110, and the joint member 120 is arranged above the flange portion 201 of the second deck plate 200. The second connection portion 123 is arranged. In this state, the insertion hole 111a of the flange portion 111 of the first deck plate 110 and the insertion hole 122a of the first connection portion 122 of the joint member 120 communicate with each other. Further, the insertion hole 201a of the flange portion 201 of the second deck plate 200 and the insertion hole 123a of the second connection portion 123 of the joint member 120 communicate with each other.

In the above state, the bolt 42a is inserted from above the first connecting portion 122 into the insertion hole 111a and the insertion hole 122a communicating with each other via the washer 42c. Further, another bolt 42a is inserted from above the second connecting portion 123 into the insertion hole 201a and the insertion hole 123a communicating with each other via the washer 42c. The tips of the inserted bolts 42a protruding below the flanges 111 and 201 of the deck plates 110 and 200 are fastened by nuts 42b via washers 42c. As a result, the joint member 120 is connected to the first deck plate 110 and the second deck plate 200. In this way, the two deck plates 110 and 200 are connected to each other via the joint member 120.

When constructing a floor slab or the like, concrete (not shown) is cast on the upper surface of the joint. Since the method of constructing the floor slab is the same as that of the first embodiment, it will be omitted.
After the concrete has solidified, the joint member 120, which is partially embedded in the concrete, is fixed to the structure. In this state, the connection work is completed by removing the support S S that supports the deck plates 110 and 200. If necessary, the first deck plate 110 and the second deck plate 200 may be removed by disconnecting the joint member 120. In this case, the nut 42b used for fastening (connecting) the flange portion 111 of the first deck plate 110 and the first connecting portion 122 of the joint member 120 is removed from the bolt 42a. As a result, the connection between the first deck plate 110 and the joint member 120 is released. In this state, the operator can remove the first deck plate 110 from the frame form of the floor slab by pulling the first deck plate 110 downward. On the other hand, the nut 42b used for fastening (connecting) the flange portion 201 of the second deck plate 200 and the second connecting portion 123 of the joint member 120 is removed from the bolt 42a. As a result, the connection between the second deck plate 200 and the joint member 120 is released. The operator can remove the second deck plate 200 from the formwork of the floor slab by pulling the second deck plate 200 downward.
The first deck plate 110 and the second deck plate 200 may be in a joined state without being disconnected from the joint member 120.

As described above, by using the deck plate unit 100 including the first deck plate 110 and the joint member 120, the two deck plates 110 and 200 are connected to each other via the joint member 120. Normally, in order for the deck plates to be joined to each other, the ends of the deck plates need to be end-closed. The end of the end-closed deck plate is less rigid than the rest. However, according to the embodiment of the present embodiment, the deck plates 110 and 200 are joined to each other via the joint member 120 on the upper surfaces of the flange portions 111 and 201 of the deck plates 110 and 200. Therefore, the end closing process that causes a decrease in rigidity becomes unnecessary, and the strength of the connecting portion between the deck plates can be improved. Further, since a deck plate that has not been end-closed can be used for connecting the deck plates, the support span that can be supported at the construction site can be expanded. The invention according to the present embodiment may be applied to a deck plate unit in which the end portion of the deck plate is end-closed.

[Modified example of the second embodiment]
The deck plate unit 100 according to the second embodiment is not limited to the above configuration. For example, the configurations shown in FIGS. 9 and 10 can be applied.
The deck plate unit 100a according to the modified example has a joint auxiliary member 130 in addition to the first deck plate 110 and the joint member 120.
The joint auxiliary member 130 connects the first deck plate 110 and the second deck plate 200 together with the joint member 120. The joint auxiliary member 130 increases the strength of the connecting portion between the deck plates 110 and 200 connected by the joint member 120. As shown in FIG. 9, the joint auxiliary member 130 has a flat portion 131 having a flat shape and a rib accommodating portion 134 formed so as to be recessed downward from the flat portion 131.

The flat portion 131 has a first connecting portion 132 provided on one end side of the flat portion 131 in the longitudinal direction L, and a second connecting portion 133 provided on the other end side of the flat portion 131 in the longitudinal direction L.
The first connecting portion 132 has an elongated hole-shaped insertion hole 132a extending along the longitudinal direction L. The second connecting portion 133 has an elongated hole-shaped insertion hole 133a extending in the same direction as the insertion hole 132a along the longitudinal direction L. The rib accommodating portion 134 has a pair of side walls 134a formed substantially perpendicular to the flat portion 131, and a bottom wall 134b connecting the lower ends of the side walls 134a. The rib accommodating portions 134 are formed between adjacent flat portions 131 in the width direction W, respectively. The height of the side wall 134a of the rib accommodating portion 134 (the length in the direction perpendicular to the longitudinal direction L and the width direction W) is the rib 112 of the first deck plate 110 and the rib 202 of the second deck plate 200. It is set to be approximately the same as or larger than the height. The width (length in the width direction W) of the bottom wall 134b of the rib accommodating portion 134 is substantially the same as or larger than the width of the rib 112 of the first deck plate 110 and the rib 202 of the second deck plate 200. It is set. That is, the rib accommodating portion 134 accommodates the ends of the ribs 112 and 202 of both deck plates 110 and 200 in a state where the first deck plate 110 and the second deck plate 200 and the joint auxiliary member 130 are connected. It is designed to be able to (cover).

A method of connecting the first deck plate 110 and the second deck plate 200 will be described. As shown in FIG. 10, the joint member 120 is arranged above the first deck plate 110 and the second deck plate 200 in a state of being butted with a gap in the longitudinal direction L. On the other hand, the joint auxiliary member 130 is arranged below the first deck plate 110 and the second deck plate 200 in the above state. In this state, the insertion hole 111a of the flange portion 111 of the first deck plate 110, the insertion hole 122a of the first connection portion 122 of the joint member 120, and the insertion hole 132a of the first connection portion 132 of the joint auxiliary member 130 communicate with each other. To do. Further, the insertion hole 201a of the flange portion 201 of the second deck plate 200, the insertion hole 123a of the second connection portion 123 of the joint member 120, and the insertion hole 133a of the second connection portion 133 of the joint auxiliary member 130 communicate with each other. Further, in this state, the end portion of the rib 112 of the first deck plate 110 and the end portion of the rib 202 of the second deck plate 200 are accommodated in the accommodating portion 134 of the joint auxiliary member 130.

In the above state, the bolt 42a is inserted into the insertion holes 122a, 111a, 132a communicating with each other from above the first connecting portion 122 of the joint member 120 via the washer 42c. Further, another bolt 42a is inserted into the insertion holes 123a, 201a, 133a communicating with each other from above the second connecting portion 123 of the joint member 120 via the washer 42c. The tip of the bolt 42a protruding below the joint auxiliary member 130 is fastened by the nut 42b via the washer 42c. As a result, the joint member 120 and the joint auxiliary member 130 are connected to the first deck plate 110 and the second deck plate 200. In this way, the deck plates 110 and 200 are connected to each other with the two deck plates 110 and 200 sandwiched between the joint member 120 and the joint auxiliary member 130.
When constructing the floor slab, concrete (not shown) is cast on the upper surface of the connecting structure. Since the method of constructing the floor slab is the same as that of the above embodiment, it is omitted.

After the concrete has solidified, the joint member 120 partially embedded in the concrete is fixed to the concrete (floor slab). In this state, if necessary, the first deck plate 110 and the second deck plate 200 may be removed by disconnecting the joint member 120 and the joint auxiliary member 130. In this case, the nut 42b used for fastening (connecting) the flange portion 111 of the first deck plate 110, the first connecting portion 122 of the joint member 120, and the first connecting portion 132 of the joint auxiliary member 130 is connected from the bolt 42a. It will be removed. As a result, the connection between the first deck plate 110, the joint member 120, and the joint auxiliary member 130 is released. On the other hand, the nut 42b used for fastening (connecting) the flange portion 201 of the second deck plate 200, the second connecting portion 123 of the joint member 120, and the second connecting portion 133 of the joint auxiliary member 130 is removed from the bolt 42a. Is done. As a result, the connection between the second deck plate 200, the joint member 120 and the joint auxiliary member 130 is released. In this state, the operator can easily remove both deck plates 110 and 200 from the frame shape of the floor slab by pulling the first deck plate 110 and the second deck plate 200 downward together with the joint auxiliary member 130. Can be removed.
The first deck plate 110 and the second deck plate 200 may be in a connected state without being disconnected from the joint member 120 and the joint auxiliary member 130.
In the above modified example, the rib accommodating portion 134 of the joint auxiliary member 130 accommodates the ribs 112 and 202 of the deck plates 110 and 200 one by one, but the present invention is not limited to this. For example, the rib accommodating portion 134 of the joint auxiliary member 130 may be configured to comprehensively accommodate a plurality of ribs 112, 202 of the deck plates 110, 200.

In the above embodiment, the deck plate units 1, 1a, 100, 100a have been described with reference to an example in which they are used for the construction of the floor slab, but the present invention is not limited to this. The deck plate units 1, 1a, 100, 100a may be applied to any application at a construction site or the like where a deck plate is used. The deck plate unit may be applied, for example, when the deck plate is used as a scaffolding for workers at a construction site.
Further, in the above embodiment, as the deck plate, a flat deck plate has been described as an example, but the present invention is not limited to this. As the deck plate, those having various forms may be applied.

1,1a Deck plate unit 10 Deck plate 11 Flange part 11a Insertion hole 12 Rib 20 Joint member 21 Main body 22 First connection part 22a Insertion hole 23 Second connection part 23a Insertion hole 24 Spacer 24a Standing part 24b Bridge part 25 Reinforcement part 30 Adjusting member 30a First insertion hole 30b Second insertion hole 100, 100a Deck plate unit 110 First deck plate 111 Flange part 111a Insertion hole 112 Rib 120 Joint member 121 Main body 122 First connection part 122a Insertion hole 123 Second connection Part 123a Insertion hole 124 Spacer 124a Standing part 124b Bridge part 125 Reinforcing part 130 Joint auxiliary member 131 Flat part 132 First connection part 132a Insertion hole 133 Second connection part 133a Insertion hole 134 Rib accommodating part 200 Second deck plate 201 Flange 201a Insertion hole 202 Rib B Support beam b1 Vertical crosspiece b2 Horizontal crosspiece b3 Plywood S Support

Claims (14)

A deck plate with a flat flange and
A joint member whose one end is connected to the flange of the deck plate and the other end is connected to another member.
A deck plate unit characterized by having. The deck plate unit according to claim 1, wherein the joint member is connected to the flange portion of the deck plate in a state of being arranged above the flange portion of the deck plate. The flange portion of the deck plate and the joint member have an insertion hole through which a connecting tool is inserted.
The deck plate unit according to claim 1 or 2, wherein the joint member is connected to a flange portion of the deck plate via a connecting tool inserted into the insertion hole. 3. Claim 3 characterized in that at least one of the insertion hole of the flange portion of the deck plate and the insertion hole of the joint member has an elongated hole shape extending along the longitudinal direction of the flange portion of the deck plate. Deck plate unit described in. One end further has an adjusting member connected to the flange portion of the deck plate and the other end connected to the joint member.
The deck plate unit according to any one of claims 1 to 4, wherein the joint member is connected to a flange portion of the deck plate via the adjusting member. The deck plate unit according to any one of claims 1 to 5, wherein the other member is fixed to a beam of a structure or a formwork for constructing the beam. The other member is a second deck plate having a flat flange portion.
The deck plate unit according to any one of claims 1 to 5, wherein the joint member is connected to a flange portion of the second deck plate at the other end. One end is connected to the flange portion of the deck plate and the other end is connected to the flange portion of the second deck plate in a state of being arranged below the flange portion of the deck plate and the flange portion of the second deck plate. Further has a joint auxiliary member
The deck plate unit according to claim 7, wherein the joint member is connected to a flange portion of the deck plate and a flange portion of the second deck plate at a position corresponding to the joint auxiliary member. .. The one according to any one of claims 1 to 8, wherein the joint member has a spacer including a pair of legs erected from the main body portion and a bridge portion connecting the legs. Deck plate unit. The joint member has a plurality of the spacers and has a plurality of the spacers.
The deck plate unit according to claim 9, wherein the joint member further includes a reinforcing portion that connects the plurality of spacers. In the joint member that connects the deck plate and the support beam and is embedded in the concrete that forms part of the floor slab.
With the main body
A first connecting portion formed on the main body portion and connected to the deck plate,
The second connecting portion connected to the support beam and
A joint member characterized by having. The joint member according to claim 11, further comprising a spacer including a pair of legs erected from the main body and a bridge portion connecting the legs. In the method of connecting a deck plate that connects a deck plate having a flat flange portion to another member,
A step of connecting one end of the joint member and a flange portion of the deck plate in a state where the joint member is arranged above the deck plate.
The process of connecting the other end of the joint member and the other member,
A method of connecting a deck plate, which comprises having. In the method of constructing a floor slab in which a deck plate having a flat flange portion is fixed to a support beam and concrete is placed on the deck plate.
A step of connecting one end of the joint member and a flange portion of the deck plate in a state where the joint member is arranged above the deck plate.
The process of connecting the other end of the joint member to the support beam,
The process of placing concrete on the joint member and the deck plate,
A step of disconnecting the joint member and the flange portion of the deck plate and removing the deck plate in a state where the concrete is solidified.
A method of constructing a floor slab, which is characterized by having.

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