JP2019011595A - Fire smoke cutoff member, fire smoke cutoff method, fire-resistant partition structure, and construction method thereof - Google Patents

Abstract

To provide a fire smoke cutoff member, a fire smoke cutoff method, a fire-resistant partition structure, and a construction method thereof capable of being easily installed at a wall body position arranged on a lower surface of a flat deck plate and cutting off a hollow part of a reinforcing steel rib arranged in the flat deck plate in a case of fire.SOLUTION: A construction method comprises: forming a cutout C to install a fire smoke cutoff member 100 cutting off a penetration surface of a hollow part 11c in a case of fire at the hollow part 11c of a reinforcing steel rib 11 where a wall body 50 is installed; fixing the fire smoke cutoff member 100 within the hollow part 11c through the cutout C; installing a horizontal member 51 for partitions at a lower surface of a ceiling surface to install the wall body 50; closing an opening formed between the horizontal member 51 for partitions and an irregularity surface of a deck plate 10 with a fire resistance member 60; and fixing the wall body 50 to the horizontal member 51 for partitions.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a smoke blocking material, a fire blocking method, a fireproof partition structure, and a method for forming the same, and in particular, in a hollow portion of a rib for supplementary steel included in a flat deck plate provided in a construction that forms a fireproof section, The present invention relates to a fire smoke blocking material, a fire smoke blocking method, a fireproof partition structure, and a method for forming the same.

  Conventionally, in a steel structure building, a floor slab is formed by making a formwork by assembling a supporting structure, which is a temporary structure for supporting the formwork, and placing concrete in the formwork. When the floor slab was finished, the formwork was removed and the support work was dismantled.

  Therefore, in order to streamline the formwork construction at the site, a flat deck plate with a flat top surface and ribs on the bottom surface, or a structural material called a deck plate for formwork, is used instead of the formwork. It is used (for example, refer to Patent Document 1).

FIG. 14 is a perspective view showing an example of the structure of a flat deck plate.
As shown in FIG. 14, the flat deck plate 10 is laid and joined to the beam 20. Further, in order to prevent the flat deck plate 10 from being detached from the beam 20, the joint 30 is welded from the flat deck plate 10 to the beam 20 at both longitudinal ends of the flat deck plate 10.

  In this way, the flat deck plate 10 only needs to be bridged between the beams 20 and the flat deck plate 10 can be left in place after the concrete is placed. Yes.

FIG. 15 is a cross-sectional view showing a reinforcing steel rib provided in the flat deck plate.
As shown in FIG. 15, the flat deck plate 10 is provided with a plurality of reinforcing steel ribs 11 formed by bending a metal plate constituting the flat deck plate 10 into a triangular cross section.

  The rib 11 for reinforcing steel has a triangular cross section formed by two inclined surfaces 11a and a bottom surface 11b, and a hollow portion 11c is formed in the interior surrounded by the two inclined surfaces 11a and the bottom surface 11b. Has been. Further, the metal plates joined from the apexes of the two inclined surfaces 11 a are bent in the vertical direction, and provided with a mating portion 11 d connected to the flat surface of the flat deck plate 10.

  Thus, by providing a plurality of reinforcing steel ribs 11 along the longitudinal direction on the lower surface of the flat deck plate 10, it is possible to prevent the flat deck plate 10 from being bent in the length direction.

FIG. 16 is a perspective view showing a state in which a wall is installed on the lower floor of the flat deck plate.
As shown in FIG. 16, the floor slab 40 is formed by placing concrete on the flat deck plate 10.

  As described above, since the flat deck plate 10 remains after the concrete is placed, the bottom surface of the flat deck plate 10 is in a state where the ribs 11 for reinforcing steel are exposed.

  On the lower floor of the formed floor slab 40, a wall body 50 is installed to divide the lower floor into a plurality of spaces. However, since the reinforcing steel ribs 11 are exposed on the ceiling surface of the lower floor, that is, the lower surface of the flat deck plate 10, the ceiling surface is uneven by the reinforcing steel ribs 11. For this reason, if the wall body 50 is installed in this state, a gap is generated on the ground contact surface between the wall body 50 and the ceiling surface due to the unevenness of the ribs 11 for supplementary steel.

  By the way, in a fireproof building including a steel structure building, a fire prevention zone is installed for the purpose of keeping the expansion of fire and smoke within a certain range when a fire occurs. For example, when a fire occurs in a part of a plurality of spaces divided by the wall body 50, this fire prevention section is to prevent the fire and smoke from spreading for a certain period of time from the space where the fire occurred to the neighboring space. It is.

  As described above, a gap is formed between the wall 50 and the lower surface of the flat deck plate 10 due to the uneven surface of the ribs 11 for supplemental steel. If a fire breaks out, smoke passes through this gap. Or fire may spread to nearby spaces. Therefore, a partition device that closes the gap between the wall body 50 and the lower surface of the flat deck plate 10 has been developed (see, for example, Patent Document 2).

FIG. 17 is a cross-sectional view showing an example of the structure of the partition device.
As shown in FIG. 17, a refractory material 60 that is larger and more elastic than the gap is inserted into a gap formed between the lower surface of the flat deck plate 10 and a horizontal partition member 51 called a wall runner. By doing so, the clearance gap formed between the wall body 50 and the partitioning horizontal member 51 is obstruct | occluded, and the fire prevention division is formed.

JP 2011-26920 A JP 2002-332707 A

  However, a hollow portion 11c formed by bending a metal plate constituting the flat deck plate 10 is formed inside the rib 11 for supplementary steel formed on the lower surface of the flat deck plate 10, and the hollow portion 11c is formed in the event of a fire. There was a problem that fire and smoke spread along the section.

The rib 11 for reinforcing steel is formed by bending the flat deck plate 10 downward in the length direction, and is partitioned by a partition device that closes the gap between the wall body 50 and the flat deck plate 10. Even so, there is a risk that smoke may be transmitted from the remote space rather than the neighborhood.
Although it is conceivable that all the hollow portions 11c are not made hollow and are closed with metal or the like, this greatly adds the weight of the flat deck plate 10 and lowers the efficiency of the laying work. In addition, it is conceivable to close the gap by filling the hollow portion 11c with a heat-resistant material only in a necessary portion inside the reinforcing steel rib 11, but the heat-resistant material is inserted into the reinforcing steel rib 11 surrounded by the metal plate. In this case, the flat deck plate 10 can only be inserted from the end in the longitudinal direction, and it is difficult to accurately place the heat-resistant material inserted from the end in the desired position.

  Therefore, at present, as a countermeasure for closing the hollow portion, a portion of the rib 11 for reinforcing steel that comes into contact with the wall body 50 when the wall body 50 is installed is cut into a rectangle by the thickness of the wall body 50. A method of closing the hollow portion 11c by removing the uneven surface and installing the wall body 50 directly below the flat deck plate 10 is considered.

  However, a plurality of reinforcing steel ribs 11 are provided in the length direction of the flat deck plate 10, and the portion of the reinforcing steel rib 11 that comes into contact with the wall body 50 when the wall body 50 is installed is defined on the wall body 50. In order to cut the entire thickness, the number of cut points increases, which requires a lot of labor and labor.

  In recent years, the number of steel-framed buildings with high ceilings has increased, and the work for cutting the ribs 11 for supplementary steel is necessarily a work at a high place. For this reason, the work for cutting the ribs 11 for supplementary steel is also a work at a high place and a long work, which is a very dangerous work.

  Moreover, although the rib 11 for supplementary steel cuts using cutting machines, such as a grinder, the spark accompanying the cutting | disconnection of a flat deck plate scatters to a worker for a long time, and a worker is forced to do very dangerous work. As a result, the burden on the worker was great.

  The present invention has been made in view of such points, and can be easily installed at the wall position installed on the lower surface of the flat deck plate, and passes through the hollow portion of the rib for reinforcing steel that the flat deck plate has in the event of a fire. An object of the present invention is to provide a fire and smoke blocking material, a fire and smoke blocking method, a fireproof partition structure, and a method for forming the same.

In the present invention, in order to solve the above-mentioned problem, in the fire blocker for preventing the smoke from penetrating through the hollow portion of the rib for reinforcing steel that the flat deck plate has in the fire protection section divided by the wall body, There is provided a fire smoke blocking device comprising a fire smoke blocking material that is inserted from a notch provided on the lower surface of the rib for reinforcing steel in contact with a wall body and blocks a through surface of the hollow portion in the event of a fire. .
Thereby, the fire smoke shielding material inserted from the notch provided in the lower surface of the rib for supplementary steel which contacts a wall body interrupts | blocks the penetration surface of a hollow part at the time of a fire.

Moreover, in the present invention, in the smoke blocking method for preventing the smoke from penetrating through the hollow portion of the rib for reinforcing steel that the flat deck plate has in the fire protection section divided by the wall body, the smoke blocking material is, A fire smoke blocking method is provided, the method comprising a step of inserting from a notch provided in a lower surface of the reinforcing steel rib in contact with the wall body and blocking a through surface of the hollow portion in the event of a fire.
Thereby, the fire smoke shielding material inserted from the notch provided in the lower surface of the rib for supplementary steel which contacts a wall body interrupts | blocks the penetration surface of a hollow part at the time of a fire.

  Further, in the present invention, in the fire-resistant partition structure of the fire-proof section that divides the interior of the building with the concave and convex ceiling surface by the reinforcing steel rib having a hollow portion provided in the length direction of the flat deck plate, Inserted from a notch provided in the lower surface of the rib for reinforcing steel in contact with the wall to be installed, and a fire smoke blocking material that blocks the through surface of the hollow portion in the event of a fire, and crosses the lower side of the fire smoke blocking material There is provided a fire-resistant partition structure comprising a wall body having a fire-resistant structure provided and a fire-resistant member that closes an opening formed between the wall body and the uneven surface of the deck plate. .

  Thereby, the fire smoke blocking material that blocks the through surface of the hollow part at the time of a fire is inserted from the notch provided on the lower surface of the rib for reinforcing steel in contact with the wall body to be installed, and the wall body provided with a fireproof structure, The fireproof member is provided over the lower side of the fire smoke blocking material, and closes the opening formed between the wall body and the uneven surface of the deck plate.

  Further, in the present invention, the formation of the fire-resistant partition structure of the fire-proof compartment that divides the interior of the building with the ceiling surface uneven by the rib for reinforcing steel having a hollow portion provided in the length direction of the flat deck plate. In the method, a step of forming a notch in the lower surface of the rib for reinforcing steel in contact with the wall body to be installed, and a fire smoke blocking material for blocking the through surface of the hollow portion from the notch in the event of a fire are inserted and fixed. A step of installing a wall body having a fireproof structure across the lower side of the fire smoke blocking material, and an opening formed between the wall body and the uneven surface of the deck plate with a fireproof member. A method for forming a fireproof partition structure.

  As a result, a notch is formed on the bottom surface of the rib for supplementary steel in contact with the wall to be installed, and a fire-smoke-blocking material that blocks the through-hole of the hollow part is inserted and fixed from the notch in the event of a fire. A wall body having a fireproof structure is installed over the lower side of the material, and an opening formed between the wall body and the uneven surface of the deck plate is closed with a fireproof member.

  According to the fire smoke blocking material, the fire smoke blocking method, the fireproof partition structure, and the method for forming the same according to the present invention, the through surface of the hollow portion is blocked in the event of a fire. Since it is possible to block fire and smoke in the hollow portion of the rib for supplementary steel without removing the rib for reinforcing steel into a rectangle, it is possible to form a fire prevention compartment in a short time and safely. .

It is a figure which shows an example of the fire smoke interrupting apparatus which concerns on 1st Embodiment. It is a figure which shows a mode that the notch for attaching a smoke blocker to a rib for supplementary steel is provided. It is a figure which shows a mode that the smoke blocker was inserted in the hollow part from the notch provided in the rib for supplementary steel. It is a figure which shows the structural example of the fireproof partition wall comprised with the fireproof material which obstruct | occludes the clearance gap formed between a wall body and a flat deck plate, and a fire smoke blocking device. It is a figure which shows the state when the fire smoke-blocking device installed in the inside of the rib for supplemental steel becomes a normal state and high temperature. It is a figure which shows an example of the fire smoke interrupting apparatus which concerns on 2nd Embodiment. It is a figure which shows a mode that the smoke blocker was inserted in the hollow part from the circular notch provided in the rib for supplementary steel. It is a figure which shows an example of the smoke blocker which concerns on 3rd Embodiment. It is a figure which shows a mode at the time of the high temperature of the state which inserted the smoke blocking device into the hollow part from the notch provided in the steel rib, and the installed smoke blocking device. It is a figure which shows an example of the fire smoke blocker which concerns on 4th Embodiment. It is a figure which shows a mode that the notch for attaching a smoke blocker to a rib for supplementary steel is provided. It is a figure which shows a mode that the fire smoke cutoff device was inserted in the notch from the notch provided in the rib for supplementary steel. It is a figure which shows the state at the time of normal time and the high temperature of the smoke blocker installed in the inside of the rib for supplementary steel. It is a perspective view which shows the structural example of a flat deck plate. It is sectional drawing which shows the rib for supplementary steel with which a flat deck plate is provided. It is a perspective view which shows a mode that a wall body is installed in the lower floor of a flat deck plate. It is sectional drawing which shows the structural example of a partition apparatus.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[First Embodiment]
FIG. 1 is a diagram illustrating an example of a fire blocker according to the first embodiment.
As shown in FIG. 1, the fire blocker 100 includes a cylindrical portion 101, a tapered portion 102, a flange portion 103, and a knob portion 104.

  The fire smoke blocking device 100 is attached to a hollow portion 11c formed inside a reinforcing steel rib 11 having a triangular cross section provided on the lower surface of a flat deck plate, and blocks a through surface of the hollow portion 11c when a fire occurs. Is. Moreover, in order to completely prevent the penetration of fire and smoke in the formed fire prevention section by using the fire smoke blocking device 100 together with the fireproof member 60 and the wall body 50 that fill the gap between the wall body 50 and the flat deck plate 10. belongs to.

  In this embodiment, the reinforcing steel rib 11 having a width of one triangular bottom face 11b of the cross section of the reinforcing steel rib provided on the flat deck plate is 50 mm, and the apex height of the two slopes 11a is 50 mm. A description will be given assuming a flat deck plate provided.

  The fire smoke blocking device 100 is basically made of thermal expansion rubber having a performance of expanding at a certain temperature, and expands at a high temperature such as when a fire occurs, and can maintain an expanded shape after expansion. It is possible to use one having flame retardancy and elasticity.

  The cylindrical portion 101 provided in the fire smoke blocking device 100 is obtained by processing thermally expanded rubber into a cylindrical shape, and the cross-section provided on the rib 11 for reinforcing steel provided on the flat deck plate is larger than the width of the bottom surface 11b having a triangular shape. It is processed into a short cylinder of about 30 mm.

  One end of the cylindrical portion 101 is provided with a tapered portion 102 so that the cross section of the cylindrical portion 101 is triangular. The triangular tip of the section formed by the tapered portion 102 is fitted into the triangle formed in the section of the rib 11 for supplementary steel, and the through surface of the hollow portion 11c can be blocked.

  The flange portion 103 is provided with a convex flange of about 35 mm that is slightly larger than the diameter of the column of the column portion 101 on the circumference of the other end of the column portion 101. The flange portion 103 is provided to prevent the fire smoke blocking device 100 from falling when the fire smoke blocking device 100 is attached to the inside of the hollow portion 11c formed in the rib 11 for supplementary steel. Details will be described later.

  A knob portion 104 is provided on the bottom surface of the cylindrical portion 101 on the flange portion 103 side. The knob portion 104 is formed with two semicircular concave portions 104a, so that a projection portion 104b is formed on the bottom surface of the cylindrical portion 101 on the flange portion 103 side.

  When mounting the fire smoke blocking device 100 in the hollow portion of the reinforcing steel rib 11, a notch C (not shown) is opened on the bottom surface 11b of the reinforcing steel rib 11 at a desired position where the fire smoke blocking device 100 is installed, The smoke blocking device 100 is inserted into the hollow portion 11c from the notch C.

  At this time, since it can be easily inserted by screwing into the hollow portion 11c while rotating the smoke blocking device 100, the knob portion 104 is formed so as to be easily held by the thumb and index finger of the worker. Specifically, the smoke blocking device 100 can be firmly held by putting the thumb and index finger of the worker into the respective recesses 104a and pinching the protrusion 104b with the thumb and index finger of the worker as they are. Further, by rotating the wrist while being held by the thumb and forefinger, the rotation operation of the smoke blocking device 100 can be easily performed.

FIG. 2 is a view showing a state in which a notch for attaching the fire smoke blocking device is provided in the rib for reinforcing steel.
As shown in FIG. 2, a reinforcing steel rib 11 is provided on the lower surface of the flat deck plate 10. The rib 11 for reinforcing steel has a triangular section formed by two inclined surfaces 11a and a bottom surface 11b, and includes a hollow portion 11c in which the inside of the triangle is hollow. The metal plate joined from the apex is bent in the vertical direction, and is constituted by a mating portion 11 d connected to the flat surface of the flat deck plate 10.

  First, the notch C for inserting the smoke blocking apparatus 100 into the rib for supplementary steel is provided. The notch C is formed on the bottom surface 11 b at the mounting position of the wall body 50 to be installed, and the circular notch C is provided using the core drill 200.

  The diameter of the notch C is perforated smaller than the diameter of the flange portion 103 provided in the installed smoke blocking apparatus 100. For example, a notch C is formed by drilling from the center of the bottom surface of the rib 11 for supplementary steel toward the mating portion 11d with a core drill of 32 mm.

FIG. 3 is a view showing a state in which a smoke blocking device is inserted into a hollow portion from a notch provided in a rib for reinforcing steel.
As shown in FIG. 3, the fire blocker 100 is inserted into the hollow portion 11 c from a notch C drilled on the lower surface of the rib 11 for supplementary steel with a core drill 200.
The diameter of the circular notch C is 32 mm, the tip of the fire smoke blocking device 100 is provided with a tapered portion 102, and the diameter of the cylindrical portion 101 is 30 mm. Although it can be inserted, the flange 103 has a diameter of 35 mm.

  Since the fire smoke blocking device 100 including the flange portion 103 having a diameter larger than the notch C is formed of thermally expanded rubber having flame retardancy and elasticity, an operator compresses the fire smoke blocking device 100 by hand. By doing so, it can be easily inserted into the hollow portion 11c from the circular cutout C.

  The smoke blocker 100 that has been compressed and inserted into the hollow portion 11c returns to its original shape due to the elastic force. In other words, in the smoke blocker 100, the flange portion having a diameter of 35 mm larger than the diameter 32 mm of the circular notch C inserted in the hollow portion 11c is restored in the hollow portion 11c. Thereby, the smoke blocker 100 inserted in the hollow part 11c does not fall from a circular notch.

  In addition, when an operator inserts the fire smoke blocking apparatus 100 in the hollow portion 11c, the worker uses the knob portion 104 provided in the fire smoke blocking apparatus 100 to rotate the fire smoke blocking apparatus 100 in the hollow portion 11c. Can be inserted into.

  Specifically, the operator's thumb and forefinger are inserted into the recess 104a, and the protrusion 104b is pinched with the operator's thumb and forefinger as it is, and inserted into the hollow portion 11c while rotating the smoke blocking device 100.

  After inserting the smoke blocking device 100 into the hollow portion 11c, the inclined surface of the taper portion 102 provided in the smoke blocking device 100 and the ribs 11 for supplemental steel are two inclined surfaces while further rotating the smoke blocking device 100. Adjustment is performed so that the position is aligned with 11a.

  At this time, the shape of the smoke blocking device 100 and the shape of the hollow portion 11c do not need to completely match, and a slight gap may be left. Since the thermal smoke rubber that expands at a high temperature such as when a fire breaks out is used for the fire smoke barrier 100, the fire smoke barrier 100 expands in the event of a fire, and the gap between the fire smoke barrier 100 and the hollow portion 11c. Can be completely occluded. Details will be described later.

FIG. 4 is a view showing a structural example of a fireproof partition wall composed of a fireproof material that closes a gap formed between the wall body and the flat deck plate, and a fire smoke blocking device.
As shown in FIG. 4, the fire blocker 100 is inserted into the hollow portion 11 c inside the reinforcing steel rib 11 provided on the flat deck plate 10 at a position where the wall body 50 is installed.

  In addition, when the fire smoke blocking device 100 is installed, a wall body 50 is installed together with the partition horizontal member 51 at the lower part of the flat deck plate 10, and is formed between the wall body 50 and the flat deck plate 10. The gap is closed by inserting a refractory material 60 that is larger and more elastic than the gap.

  Thus, a fireproof partition is formed by the fireproof partition wall composed of the wall body 50, the heat-resistant material 60, and the smoke blocker 100, and the thermal expansion rubber that is the smoke blocker 100 is expanded in the event of a fire. Then, since the through surface of the hollow portion 11c of the rib 11 for supplementary steel that could not be closed can be closed, the flame and smoke generated during the fire can be kept within a certain range.

FIG. 5 is a diagram illustrating a state when the smoke blocking device installed inside the rib for supplementary steel becomes a normal state and a high temperature.
As shown in FIG. 5, the fire smoke blocking device 100 is installed at a position where the wall body 50 is installed in the hollow portion 11 c of the reinforcing steel rib 11 provided at the lower portion of the flat deck plate 10.

Fig.5 (a) has shown the state in which the fire smoke blocking device 100 was installed, ie, the normal state before a fire broke out.
As shown to Fig.5 (a), a clearance gap may arise a little between the fire smoke blocker 100 installed in the hollow part 11c, and the rib 11 for supplementary steel. Thus, if there is a gap between the smoke blocker 100 and the rib 11 for supplementary steel, there is a risk that fire and smoke may expand into the adjacent space through this gap. Since the fire smoke blocking device 100 expands when it occurs, this gap can be closed.

FIG. 5B shows a state in which a fire has occurred and the temperature has risen after the installation of the smoke blocking apparatus 100.
As shown in FIG. 5 (b), the smoke blocker 100 expands when a certain temperature is exceeded due to a temperature rise caused by the occurrence of a fire, and the gap formed in FIG. Can be occluded.

  In this way, the smoke blocking device 100 expands due to the temperature rise that occurs at the time of the occurrence of the fire, so that the through surface of the hollow portion 11c inside the rib 11 for supplementary steel, which has been difficult in the past, can be completely blocked.

  Thereby, the space obstruct | occluded by the wall 50, the refractory material 60, and the smoke blocker 100 is completely interrupted | blocked with the adjacent space. In other words, it becomes possible to keep the flame and smoke generated in the event of a fire within a certain range, and it is possible to install a stronger fire prevention zone.

[Second Embodiment]
Next, a second embodiment of the present invention will be described. The fire smoke blocking device 110 of this embodiment is substantially the same as the configuration shown in the first embodiment, except that the shape of the fire smoke blocking device 110 is different. For this reason, about the component similar to the said 1st Embodiment, the same code | symbol is attached | subjected etc., and the description is abbreviate | omitted suitably.

FIG. 6 is a diagram illustrating an example of a fire blocker according to the second embodiment.
As shown in FIG. 6, the fire blocker 110 includes a main body portion 111, a tapered portion 112, a side surface portion 113, and a bottom surface portion 114.

  The fire smoke blocking device 110 is basically made of thermally expanded rubber that has the ability to expand at a certain temperature, expands at a high temperature such as when a fire breaks out, and maintains an expanded shape after expansion. It is flame retardant and elastic.

  The main body 111 provided in the fire smoke blocking device 110 is processed into a wedge shape in which a triangular prism formed of thermally expanded rubber is tilted sideways. The bottom surface portion 111 of the main body 111 has a width in the direction of the taper portion 112 larger than the diameter 32 mm of the notch C formed in the bottom surface 11b of the reinforcing steel rib 11 provided on the flat deck plate 10. The For example, if there is a width of about 45 mm, the smoke blocking device 110 will not fall from the notch C.

  The main body portion 111 is provided with two tapered portions 112 from the bottom surface portion 114 toward the upper portion of the smoke blocking device 110. The tip of the triangle formed by the tapered portion 112 is fitted into the triangle formed on the cross section of the rib for reinforcing steel, and the through surface of the hollow portion 11c can be blocked.

FIG. 7 is a view showing a state in which the smoke blocking device is inserted into the hollow portion from a circular notch provided in the rib for reinforcing steel.
As shown in FIG. 7, the fire blocker 110 is inserted into the hollow portion 11 c from a circular notch C drilled in the lower surface of the rib 11 for supplementary steel by the core drill 200.

  Although the diameter of the circular notch C is 32 mm, a tapered portion 102 is formed at the tip of the smoke blocking device 100, but the width in the direction of the tapered portion 102 of the smoke blocking device 100 is 45 mm. It is formed larger than the diameter of C.

  Since the fire blocker 110 having a width larger than the notch C is a thermally expandable rubber having elastic flame retardancy and elasticity, an operator compresses the smoke blocker 110 by hand, The circular cutout C can be inserted into the hollow portion 11c.

  The smoke blocker 110 compressed and inserted into the hollow portion 11c returns to its original shape due to the elastic force. That is, in the fire smoke blocking device 110, the bottom surface portion 114 larger than the diameter of the circular notch 32mm inserted in the hollow portion 11c is restored.

  Further, since the bottom surface portion 114 is rectangular with respect to the circular notch C, the four corners of the bottom surface portion 114 are restored larger than the notch C. Thereby, the smoke blocker 110 inserted in the hollow part 11c can prevent falling from the circular notch C.

  Further, the shape of the fire smoke blocking device 110 and the shape of the hollow portion 11c do not have to completely match, and a slight gap may be left. Since the thermal smoke rubber that expands at a high temperature such as when a fire breaks out is used for the fire smoke shield device 110, the fire smoke shield device 110 expands when a fire occurs, and the gap between the fire smoke shield device 110 and the hollow portion 11c. Can be completely occluded.

  In this way, the fire smoke blocking device 110 expands due to the temperature rise that occurs at the time of the occurrence of a fire, so that the through surface of the hollow portion 11c inside the reinforcing steel rib 11 that has been difficult in the past can be completely blocked.

  As a result, the space blocked by the wall body 50, the refractory material 60, and the smoke blocker 110 is completely blocked from the adjacent space. In other words, it becomes possible to keep the flame and smoke generated in the event of a fire within a certain range, and it is possible to install a stronger fire prevention zone.

[Third Embodiment]
Next, a second embodiment of the present invention will be described. The fire smoke blocking device 120 of the present embodiment is substantially the same as the configuration shown in the first embodiment, except that the shape of the fire smoke blocking device 120 is different. For this reason, about the component similar to the said 1st Embodiment, the same code | symbol is attached | subjected etc., and the description is abbreviate | omitted suitably.

FIG. 8 is a diagram illustrating an example of a fire blocker according to the third embodiment.
As shown in FIG. 8, the fire smoke blocking device 120 includes two side parts 121, a bottom part 122, an injection port 123, and a thermal expansion rubber 124 not shown here.

  The two side parts 121 and the side part 121 and the bottom part 122 are obtained by bending a single plate material into a U shape and processing the tip of the side part 121 into a triangular shape, and have heat resistance. It is a metal plate. Or you may use the board | plate material made from a thermal expansion rubber which can maintain a U-shaped shape.

The height of the side surface portion 121 is about 45 mm shorter than the height of the hollow portion 11 c formed inside the supplementary steel rib 11.
Further, each side of the bottom surface portion 122 and the diagonal line of the bottom surface portion 122 are formed with a length that is the same as or slightly smaller than the diameter 32 mm of the circular notch C. As a result, the smoke blocking device 120 can be easily inserted into the hollow portion 11C from the circular cutout C.
The bottom surface portion 122 is provided with an injection port 123 for injecting a semi-solid thermal expansion rubber 124 later.

FIG. 9 is a diagram showing a state in which the fire smoke blocking device is inserted into the hollow portion from a notch provided in the steel rib, and a state of the installed fire smoke blocking device at a high temperature.
As shown to Fig.9 (a), the smoke blocking device 120 is inserted in the hollow part 11c from the notch C drilled in the lower surface of the rib for supplementary steel with the core drill 200. FIG. The fire smoke blocking device 120 is inserted so that the two side surfaces 121 face the longitudinal direction of the rib 11 for supplementary steel, that is, the two side surfaces 121 block the through surface of the hollow portion 11C.

  The diameter of the circular notch C is 32 mm, and each side of the bottom surface portion 122 and the diagonal line of the bottom surface portion 122 are formed with a length that is the same as or slightly smaller than the diameter 32 mm of the circular notch. Therefore, the smoke blocker 120 can be easily inserted into the hollow portion 11c.

  Next, as shown in FIG. 9 (b), a semi-solid thermal expansion rubber 124 is injected into the mold from an injection port 123 provided in the bottom surface portion 122. The thermal expansion rubber 124 is injected from the injection port 123 using a syringe or the like. The thermal expansion rubber 124 is a thermally expandable rubber material having a viscosity that can be injected from the injection port 123, and a material that cures over time may be used.

  As shown in FIG. 9C, since the thermal expansion rubber 124 injected from the injection port 123 is semi-solid, the side surface portion 121, the bottom surface portion 122, and the reinforcing steel rib 11 include two inclined surfaces 11a. The thermal expansion rubber 124 is cured as time elapses.

  The thermal expansion rubber 124 is filled until the side surface 121, the bottom surface 122, and the reinforcing rib 11 are filled with the space surrounded by the two inclined surfaces 11a. As a result, the smoke blocker 120 is in close contact with the two inclined surfaces 11a.

  The thermal expansion rubber 124 can remain in a range surrounded by the side surface portion 121, the bottom surface portion 122, and the supplementary steel rib 11 with the two inclined surfaces 11a, but the bottom surface of the bottom surface portion 122 and the supplementary steel rib 11 can remain. A gap is formed between the two. However, since the temperature becomes high when a fire breaks out, the thermal expansion rubber 124 staying in the mold expands, so that the fire smoke blocking device 120 is pushed down, and as shown in FIG. The gap that has occurred in between is closed.

  In addition, by injecting the thermal expansion rubber 124 into the gap between the lower surface of the bottom surface portion 122 and the reinforcing steel rib 11 seen in FIG. 9C, the thermal expansion rubber 124 expands in the event of a fire, The penetration surface of the hollow portion 11C can be closed more firmly.

  In this way, the smoke blocking device 120 expands due to the temperature rise that occurs at the time of the occurrence of a fire, so that the through surface of the hollow portion 11c inside the reinforcing steel rib 11 that has been difficult in the past can be completely blocked.

  As a result, the space blocked by the wall body 50, the refractory material 60, and the smoke blocking device 130 is completely blocked from the adjacent space. In other words, it becomes possible to keep the flame and smoke generated in the event of a fire within a certain range, and it is possible to install a stronger fire prevention zone.

[Fourth Embodiment]
Next, a fourth embodiment of the present invention will be described. The fire smoke blocking device 130 of the present embodiment is substantially the same as the configuration shown in the first embodiment, except that the shape of the fire smoke blocking device 130 is different. For this reason, about the component similar to the said 1st Embodiment, the same code | symbol is attached | subjected etc., and the description is abbreviate | omitted suitably.

FIG. 10 is a diagram illustrating an example of a fire blocker according to the fourth embodiment.
As shown in FIG. 10, the fire blocker 130 includes a blocking surface 131, a thermal expansion rubber layer 132, a flange surface 133, and a screw hole 134.

The blocking surface 131 and the flange surface 133 are bent so that the cross-section of a single plate is L-shaped, and is a metal plate having a heat resistance and a thickness of 1.6 mm.
The blocking surface 131 has an area that can completely cover the triangle seen in the cross section of the rib 11 for supplementary steel, and preferably has a width exceeding 50 mm and a height exceeding 50 mm. In addition, both surfaces of the blocking surface 131 are covered with thermally expandable rubber having a performance of expanding at a certain temperature.

Or you may use the board | plate material made from thermal expansion rubber which can maintain the L-shape for the interruption | blocking surface 131 and the flange surface 133 itself.
The flange surface 133 is provided with a screw hole 134 for inserting a screw or a bolt to be used when the fire blocker 130 is later fixed to the rib 11 for reinforcing steel.

FIG. 11 is a view showing a state in which a notch for attaching the fire smoke blocking device is provided in the rib for reinforcing steel.
As shown in FIG. 11, first, a notch C for inserting the fire blocker 130 into the inside of the rib 11 for supplementary steel is provided. The cutout C is provided with a straight cutout perpendicular to the longitudinal direction of the rib 11 for supplementary steel using a grinder 300 or the like on the bottom surface 11b in accordance with the mounting position of the wall body 50 to be installed.

  The notch is formed with a thickness of 1.6 mm thickness of the blocking surface 131 and the thickness of the thermal expansion rubber layer 132 coated on the peripheral surface of the blocking surface 131. The notches C1 to C3 are formed on the two inclined surfaces 11a and the bottom surface 11b. Is provided. Moreover, you may provide a notch in the matching part 11d as needed.

FIG. 12 is a view showing a state in which the smoke blocking device is inserted into the notch from the notch provided in the rib for reinforcing steel.
As shown in FIG. 12, a blocking surface 131 provided in the smoke blocking device 130 is inserted into the hollow portion 11 c from the notch C formed in the lower surface of the rib for supplementary steel by the grinder 300.

  The blocking surface 131 is inserted into the reinforcing steel rib 11 until the flange surface 133 hits the bottom surface 11b, and the screw 135 inserted from the screw hole 134 is tightened to fasten the reinforcing steel rib 11 and the smoke blocking device 130.

  The blocking surface 131 that can completely cover the triangle seen in the cross section of the reinforcing steel rib 11 is inserted into the reinforcing steel rib 11 so that the through surface of the hollow portion 11c of the reinforcing steel rib 11 is obtained. The fire block device 130 is fixed to the rib 11 for supplementary steel by a screw 135 on the surface where the bottom surface 11b and the flange surface 133 are in contact with each other.

FIG. 13 is a diagram showing a normal state and a high temperature state of the fire smoke blocking device installed inside the reinforcing steel rib.
As shown in FIG. 13, the fire blocker 130 is inserted into the hollow portion 11 c inside the reinforcing steel rib 11 provided on the flat deck plate 10 at a position where the wall body 50 is installed.

FIG. 13A shows a state after the installation of the fire smoke blocking device 130, that is, before a fire occurs.
As shown to Fig.13 (a), a some clearance gap may arise between the notch C provided in the smoke blocker 130 installed in the hollow part 11c, and the rib 11 for supplementary steel. Thus, if there is a gap between the fire smoke blocking device 100 and the rib 11 for supplementary steel, there is a risk that fire and smoke may expand into the adjacent space through this gap.

FIG. 12B shows a state in which a fire has occurred and the temperature has risen after the installation of the fire smoke blocking device 130.
As shown in FIG. 12B, when the temperature rises due to the occurrence of a fire, the smoke blocker 130 expands when a certain temperature is exceeded, and the gap generated in FIG. The thermal expansion rubber layer 132 included in can be closed.

  In this way, the blocking surface 131 provided in the fire smoke blocking device 130 blocks the through surface of the hollow portion 11c of the rib 11 for supplementary steel, and the thermal expansion rubber layer 132 provided in the smoke blocking device 130 is provided due to a temperature rise caused when a fire occurs. As a result of the expansion, the gap between the reinforcing steel rib 11 and the notch C can be closed, and the through surface of the hollow portion 11c inside the reinforcing steel rib 11 which has been difficult in the past can be completely closed.

  As a result, the space blocked by the wall body 50, the refractory material 60, and the smoke blocking device 130 is completely blocked from the adjacent space. In other words, it becomes possible to keep the flame and smoke generated in the event of a fire within a certain range, and it is possible to install a stronger fire prevention zone.

  As described above, the notch C to be processed when attaching the fire protection device of the present invention is not a large one as in the prior art, and is only the notch C provided by the drilling with the core drill 200 or the grinder 300, so that it is short. Since the fire smoke blocking device can be used in time, the burden on workers can be reduced.

  In addition, since the thermal expansion rubber expands in the event of a fire, it closes the gap that forms between the smoke blocking device and the rib for supplementary steel, so that the flame that expands through the hollow portion formed inside the steel rib when a fire occurs And can block smoke.

DESCRIPTION OF SYMBOLS 10 Flat deck plate 11 Reinforcing steel rib 11a Slope 11b Bottom surface 11c Hollow part 11d Joint part 20 Beam 30 Reinforcement 40 Floor slab 50 Wall body 51 Spacing material for partition 60 Refractory material 100, 110, 120, 130 Smoke interruption device 101 Cylindrical portion 102, 112 Tapered portion 103 Flange portion 104 Knob portion 104a Recess portion 104b Protrusion portion 111 Main body portion 113, 121 Side surface portion 114, 122 Bottom surface portion 123 Inlet 124 Thermal expansion rubber 131 Blocking surface 132 Thermal expansion rubber layer 133 Flange surface 134 Screw hole 135 Screw 200 Core drill 300 Grinder C, C1, C2, C3 Notch

Claims (18)

In the fire block device for preventing the smoke from penetrating through the hollow portion of the rib for reinforcing steel that the flat deck plate has in the fire prevention section divided by the wall body,
Inserted from a notch provided in the lower surface of the rib for reinforcing steel in contact with the wall body, a fire smoke blocking material that blocks the through surface of the hollow portion in the event of a fire,
A fire smoke barrier device comprising: The fire smoke blocking material is
The fire-smoke shutoff device according to claim 1, wherein the fire-extinguishing material is a thermal expansion material that closes a gap with the penetrating surface by expanding due to overheating during a fire. The fire smoke blocking material is
A flange portion having a larger diameter than the opening portion of the notch inserted into the hollow portion;
The fire smoke blocking device according to claim 2, further comprising: The fire smoke blocking material is
The fire smoke blocking device according to claim 2, wherein the fire blocking device is a heat-resistant material that is larger and more elastic than the through-surface of the hollow portion. The thermal expansion material is
The fire smoke blocking device according to claim 2, which is a heat-expandable fire resistant rubber. The notch is
The fire smoke blocking device according to claim 2, wherein the device is a circular hole drilled by a core drill. The fire smoke blocking material is
The fire smoke blocking device according to claim 1, wherein the fire blocking device is a plate material that blocks the through surface. The plate material is
The fire smoke blocking device according to claim 7, further comprising a refractory surface in a direction of the penetrating surface. The fire resistance is
The fire-smoke shutoff device according to claim 8, which is a thermal expansion refractory rubber layer. The plate material is
A fixing portion for fixing with the rib for reinforcing steel,
The fire blocker according to claim 7, further comprising: The fixing part is
The fire-smoke shutoff device according to claim 10, wherein a flange surface in which a cross section of the plate member is bent in an L shape and a lower surface of a rib for supplementary steel are fastened with a fastening material. The notch is
The fire smoke blocking device according to claim 7, wherein a peripheral surface of the hollow portion is vertically formed with a thickness of the plate member. The fire smoke blocking material is
A frame material that blocks the penetrating surface;
A refractory material filled between the frame members;
The fire smoke blocking device according to claim 1, comprising: The frame material is
Two side plates for preventing the filled refractory material from flowing out in the direction of the penetrating surface;
A bottom plate that connects the two side plates and prevents the filled refractory material from flowing out from the lower portion of the hollow portion;
An inlet for filling the refractory material;
The fire smoke blocking device according to claim 1, comprising: The refractory material is
The fire smoke blocking device according to claim 13, which is a viscous anti-solid body. In the fire blocking method for preventing the smoke from penetrating through the hollow part of the rib for reinforcing steel that the flat deck plate has in the fire protection section divided by the wall body,
A process in which a fire smoke blocking material is inserted from a notch provided in a lower surface of the rib for reinforcing steel in contact with the wall body, and blocks a through surface of the hollow portion at the time of a fire;
A fire smoke blocking method comprising: In the fire-resistant partition structure of the fire prevention compartment that divides the inside of the building with the ceiling surface made uneven by the rib for reinforcing steel having a hollow part inside provided in the length direction of the flat deck plate,
Inserted from a notch provided on the lower surface of the rib for reinforcing steel in contact with the wall to be installed, and a fire smoke blocking material that blocks the through surface of the hollow portion in the event of a fire,
A wall body having a fireproof structure provided over the fire smoke blocking material;
A fire-resistant member that closes an opening formed between the wall and the uneven surface of the deck plate;
A fireproof partition structure comprising: In the method for forming a fire-resistant partition structure of a fire-proof section that divides the interior of a building with a concave and convex ceiling surface by a rib for reinforcing steel having a hollow portion inside provided in the length direction of the flat deck plate,
Forming a notch in the lower surface of the rib for reinforcing steel in contact with the wall to be installed;
Inserting and fixing a fire blocker that blocks the through surface of the hollow part during a fire from the notch, and
Installing a wall with a fireproof structure over the fire smoke blocking material;
A step of closing the opening formed between the wall and the uneven surface of the deck plate with a fire-resistant member;
A method for forming a fireproof partition structure, comprising: