JP4017259B2 - Flameproof shutter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a flameproof shutter, and more particularly to a flameproof shutter installed in a ventilation layer of a building, which can block the ventilation layer in the event of a fire in response to a temperature change in the ventilation layer. The present invention relates to a flameproof shutter capable of opening a ventilation layer after extinction.
[0002]
[Prior art]
In buildings such as wooden houses, high heat insulation and high airtightness are prevalent in order to secure a comfortable living space and achieve energy saving of air conditioning. In addition, as part of this, a ventilation layer that circulates the outside air inside the outer wall material is provided in the outer wall portion of the building in order to prevent moisture from staying inside the housing (Japanese Patent Laid-Open No. 3-137335, (See JP-A-7-259203 and JP-A-7-12488).
[0003]
However, in a building having a ventilation layer structure, when a fire breaks out, a flame spreads rapidly through the ventilation layer, and there is a risk of promoting the spread of fire to the upper floors and adjacent rooms. Therefore, in a wooden house or the like, a fireproof structure in which a ventilation member (fire stop) is installed in the ventilation layer is recommended. For example, the ventilating member is configured such that upper and lower two-stage partition pieces having a plurality of vent holes are horizontally installed along the vent layer in a state of crossing the vent layer.
[0004]
[Problems to be solved by the invention]
By the way, since the above-mentioned ventilation thing (fire stop) has a structure in which a plurality of ventilation holes are always open, the ventilation layer can be maintained in normal conditions. There is a problem that it cannot be reliably shut off.
[0005]
The present invention has been made in view of the above circumstances, and its purpose is to maintain ventilation of the ventilation layer in normal times, to reliably block the flame in the event of a fire, and to ventilate again after extinguishing the fire. An object of the present invention is to provide a flameproof shutter capable of recovering the ventilation of a layer.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, a first invention is a flameproof shutter installed in a ventilation layer of a building, which has a plurality of ventilation holes and is installed across the ventilation layer. And a shutter piece capable of closing each vent hole by overlapping with the shutter base, and a connecting member for connecting the shutter piece to the shutter base, the connecting member being made of a reversibly heat-deformable material. The shutter piece is held in a state of being separated from the shutter base under normal temperature conditions, and has a property of holding the shutter piece in a state of being thermally deformed and overlapping the shutter base under high temperature conditions. To do.
[0007]
According to a second aspect of the present invention, there is provided a flameproof shutter installed in a ventilation layer of a building, the shutter base having a plurality of ventilation holes and extending across the ventilation layer, and the shutter base. A shutter piece capable of closing the air holes by overlapping on one side; and a connecting member for connecting the shutter piece to a shutter base and supporting the shutter piece on one side, the connecting member having one end connected to the shutter piece. A connecting rod that is fixed and penetrates the vent hole, is bent in a lateral U shape, and one end thereof is fixed to the other surface of the shutter base, and the other end is fixed to the other end of the connecting rod. The shutter piece is held away from the shutter base under normal temperature conditions, and the shutter piece is held overlapping the shutter base under temperature conditions of 100 to 200 ° C. Characterized in that it comprises that property.
[0008]
Further, the third invention is a flameproof shutter installed in a ventilation layer of a building, and a support base attached horizontally along the width direction of the ventilation layer, and along the longitudinal direction of the support base A plurality of substantially vertical support pieces arranged at a predetermined pitch, a plurality of bimetals bent in a U shape and connected to the upper end or lower end of each support piece, and both ends of each bimetal The bimetal is provided with a shutter piece protruding in the width direction of the ventilation layer, and the bimetal holds the ventilation layer by keeping the shutter pieces arranged at the opposite end portions away from each other under normal temperature conditions. It is characterized in that it has a property of opening and holding the shutter pieces in contact with each other under a temperature condition of 100 to 200 ° C. to block the ventilation layer.
[0009]
According to a fourth aspect of the present invention, there is provided a flameproof shutter installed in a ventilation layer of a building, the upper partition piece and the lower partition piece having a plurality of ventilation holes and extending across the ventilation layer. A shutter base provided, a shutter piece that can close the vent hole by overlapping with the lower partition piece, and a suspension spring that passes through the vent hole of the lower partition piece and suspends the shutter piece from the upper partition piece The suspension spring is made of a shape memory alloy, and is deformed into an extended state in which the shutter piece is spaced below the lower partition piece under normal temperature conditions, and the shutter under a transformation temperature condition of 100 to 200 ° C. It has the property of returning to a contracted state where the piece is overlaid on the lower partition piece.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a flameproof shutter according to first to fourth inventions will be described with reference to the accompanying drawings. FIG. 1 is a vertical sectional view showing the structure of a flameproof shutter according to the first invention. FIG. 2 is a vertical sectional view showing the operation of the flameproof shutter according to the first invention. FIG. 3 is a vertical sectional view of an outer wall portion of a building having a ventilation layer in which the flameproof shutter of the present invention is installed. FIG. 4 is a vertical sectional view showing the structure of the flameproof shutter according to the second invention. FIG. 5 is a vertical sectional view showing the operation of the flameproof shutter according to the second invention. FIG. 6 is a perspective view showing an example of the shape of the bimetal of the flameproof shutter according to the second invention. FIG. 7 is a perspective view showing another example of the bimetal shape of the flameproof shutter according to the second invention. FIG. 8 is a perspective view showing the structure of a flameproof shutter according to the third invention. FIG. 9 is a perspective view showing the operation of the flameproof shutter according to the third invention. FIG. 10 is a vertical sectional view showing the structure of the flameproof shutter according to the fourth invention. FIG. 11 is a vertical sectional view showing the operation of the flameproof shutter according to the fourth invention.
[0011]
First, the flameproof shutter according to the first invention will be described. A flameproof shutter according to a first aspect of the present invention is a flameproof shutter installed in a ventilation layer (A) of a building, as indicated by reference numeral (10) in FIGS. A shutter base (11) having (11A) and extending across the ventilation layer (A), and a shutter piece (12) capable of closing each ventilation hole (11A) by overlapping with the shutter base (11) And a connecting member (13) for connecting the shutter piece (12) to the shutter base (11). The connecting member (13) is made of a reversibly heat-deformable material, and keeps the shutter piece (12) spaced from the shutter base (11) under normal temperature conditions (see FIG. 1). Under the condition, it has a property of being thermally deformed and holding the shutter piece (12) in a state of being overlapped with the shutter base (11) (see FIG. 2).
[0012]
As shown in FIG. 3, the ventilation layer (A) is formed with a gap of about 20 mm between the outer wall material (B) constituting the outer wall portion of the building and the structural face material (C) inside thereof. Many spaces are formed in the width direction of the outer wall as spaces having a width of about 400 to 2000 mm divided by left and right vertical trunk edges (not shown). Each ventilation layer (A) communicates with the outside air through the drain opening (D) on the lower end side and the eaves opening (E) on the upper end side of the outer wall material (B). Further, a heat insulating material (G) is interposed between the structural surface material (C) and the interior material (F) inside thereof.
[0013]
The shutter base (11) is made of a metal plate having a thickness of about 0.1 to 1 mm. As the metal plate, an aluminum plate or a copper plate can be used, but an iron-based metal plate, particularly a stainless steel plate is preferable. As shown in FIGS. 1 and 2, the shutter base (11) has joint pieces (11B) and (11C) bent along the outer wall material (B) and the structural face material (C) at both edges. It has a formed crank-shaped cross-sectional shape. Then, one of the joining pieces (11C) is nailed to the structural face material (C), so that the shutter base (11) is installed substantially horizontally along the width direction of the ventilation layer (A).
[0014]
Each vent hole (11A) of the shutter base (11) has a circular shape having a diameter of about 5 to 15 mm, and a pitch of about 30 to 50 mm in the longitudinal direction of the shutter base (11) (the width direction of the vent layer (A)). Are arranged in The shape of each vent hole (11A) is not limited to a circle, and may be an ellipse or a rectangle.
[0015]
The shutter piece (12) is formed in a disk shape from a metal plate similar to the shutter base (11). The diameter of the shutter piece (12) is set to about 7 to 18 mm, for example, as a size capable of closing each vent hole (11A).
[0016]
The connecting member (13) is formed in a strip shape having a width of about 5 to 10 mm by a reversibly heat-deformable material, for example, a bimetal or a shape memory alloy. One end of the connecting member (13) is bent in a lateral U shape, and the other end is extended in a standing state penetrating the vent hole (11A). The connecting member (13) has one end welded to the lower surface of the shutter base (11) and the other end welded to the lower surface of the shutter piece (12).
[0017]
The flameproof shutter (10) according to the first invention is installed in at least one of the following parts shown in FIG. For example, it is installed in the vicinity of the drain opening (D) of the ventilation layer (A) in order to prevent the spark from entering the ventilation layer (A) from the base side and rising. Moreover, in order to prevent a spark from being sucked into the ventilation layer (A) from the back of the eave, it is installed in the vicinity of the eaves opening (E) of the ventilation layer (A). Furthermore, in order to prevent the fire spread between the upper floor and the lower floor, it is installed in the vicinity of the boundary (H) between the upper and lower floors of the ventilation layer (A).
[0018]
As shown in FIG. 1, the flameproof shutter (10) according to the first aspect of the present invention installed in the ventilation layer (A) has a shutter base (12) as a shutter base, as shown in FIG. (11) is supported in a state of being separated above. That is, the shutter piece (12) opens each vent hole (11A) of the shutter base (11), so that the vent layer (A) can be surely opened to maintain the ventilation.
[0019]
On the other hand, when the temperature in the vicinity of the flameproof shutter (10) in the ventilation layer (A) becomes a high temperature condition of 100 to 200 ° C. due to the occurrence of a fire, as shown in FIG. When the bent portion is thermally deformed in the extending direction, the connecting member (13) attracts and overlaps the shutter piece (12) on the upper surface of the shutter base (11). That is, each vent hole (11A) of the shutter base (11) is closed by each shutter piece (12), so that the vent layer (A) can be reliably shut off and the flame can be shut off. As a result, it is possible to avoid a situation in which the flame spreads rapidly through the ventilation layer (A), and to suppress the fire spread of the building.
[0020]
Further, when the temperature near the flameproof shutter (10) in the ventilation layer (A) is reduced to near room temperature due to the fire extinguishing, as shown in FIG. 1, the portion bent in the lateral U shape of the connecting member (13) is formed. By thermally deforming in the contraction direction, the connecting member (13) again supports the shutter piece (12) separately above the shutter base (11). In other words, each vent hole (11A) of the shutter base (11) is opened, and the ventilation layer (A) can be opened again to restore the ventilation.
[0021]
Next, a flameproof shutter according to the second invention will be described. A flameproof shutter according to a second aspect of the present invention is a flameproof shutter installed in a ventilation layer (A) of a building, as indicated by reference numeral (20) in FIGS. (21A) and a shutter base (21) installed across the ventilation layer (A), and a shutter piece (21A) that can close each ventilation hole (21A) by overlapping one side of the shutter base (21) 22) and a connecting member (23) for connecting the shutter piece (22) to the shutter base (21) and supporting it on one side thereof. The connecting member (23) has one end fixed to the shutter piece (22) and penetrating through the vent hole (21A), and is bent in a lateral U-shape and has one end at the shutter base ( 21) It has a bimetal (23B) fixed to the other one surface and the other end fixed to the other end of the connecting rod (23A). The connecting member (23) keeps the shutter piece (22) separated from the shutter base (21) under normal temperature conditions (see FIG. 4), and the shutter piece (22 under temperature conditions of 100 to 200 ° C. ) Is held in a state of overlapping the shutter base (21) (see FIG. 5).
[0022]
The shutter base (21) is configured in the same manner as the shutter base (11) of the flameproof shutter (10) according to the first invention described above. That is, the shutter base (21) is formed by a metal plate similar to the shutter base (11) into a cross-sectional shape having the same joining pieces (21B) and (21C) as the joining pieces (11B) and (11C). Yes. The shutter base (21) has a plurality of air holes (21A) similar to the air holes (11A) arranged in the longitudinal direction. Then, one of the joining pieces (21C) is nailed to the structural face material (C), whereby the shutter base (21) is laid substantially horizontally along the width direction of the ventilation layer (A).
[0023]
The shutter piece (22) is formed in a disk shape having a size capable of closing the vent hole (21A) by the same metal plate as the shutter piece (12) of the flameproof shutter (10).
[0024]
The connecting rod (23A) of the connecting member (23) is a rod having a diameter of 1 to 2 mm and a length of about 10 to 30 mm made of the same metal as the shutter base (11), and one end of the connecting rod (23) is a shutter piece (22). It is fixed to the approximate center. Further, as shown in FIG. 6, the bimetal (23B) is formed in a strip shape having a width of about 5 to 10 mm, and has a size approximately equal to the vent hole (21A) of the shutter base (21) on one end side thereof. A vent hole (23C) having and overlapping therewith is formed. The connecting rod (23A) penetrates the vent hole (21A) and the vent hole (23C), and the other end is fixed to the center in the width direction of the other end of the bimetal (23B). In addition, you may form the ventilation notch (23D) instead of the said vent hole (23C) as shown in FIG. 7 in the one end side of a bimetal (23B).
[0025]
The flameproof shutter (20) according to the second invention is similar to the flameproof shutter (10) according to the first invention, in the vicinity of the drain opening (D) of the ventilation layer (A) shown in FIG. It is installed at at least one location near the eaves opening (E) or near the boundary (H).
[0026]
As shown in FIG. 4, the flameproof shutter (20) according to the second aspect of the present invention installed in the ventilation layer (A) has a shutter base (22) as a shutter base, as shown in FIG. (21) is supported in a state of being separated above. That is, the shutter piece (22) opens each vent hole (21A) of the shutter base (21), and the vent layer (A) can be surely opened to maintain the ventilation.
[0027]
On the other hand, when the temperature in the vicinity of the flameproof shutter (20) in the ventilation layer (A) reaches 100 to 200 ° C. due to the occurrence of a fire, the connecting member (23) is bent in a lateral U shape as shown in FIG. The bimetal (23B) thermally expands, and the other end moves downward. For this reason, the connecting rod (23A) moves downward to overlap the shutter piece (22) on the upper surface of the shutter base (11). That is, each vent hole (21A) of the shutter base (21) is closed by each shutter piece (22), so that the vent layer (A) can be reliably shut off and the flame can be shut off. As a result, it is possible to avoid a situation in which the flame spreads rapidly through the ventilation layer (A), and to suppress the fire spread of the building.
[0028]
Further, when the temperature near the flameproof shutter (20) in the ventilation layer (A) is lowered to near room temperature due to fire suppression, the bimetal (23B) of the connecting member (23) is thermally contracted as shown in FIG. Since the end moves upward, the connecting member (23) supports the shutter piece (22) again in a state of being separated above the shutter base (21). In other words, each vent hole (21A) of the shutter base (21) is opened, and the ventilation layer (A) can be opened again to restore the ventilation.
[0029]
Next, a flameproof shutter according to the third invention will be described. As shown in FIG.8 and FIG.9, the flameproof shutter (30) based on 3rd invention is a flameproof shutter installed in the ventilation layer of a building, Comprising: It is horizontal along the width direction of a ventilation layer. A support base (31) attached to the base, a plurality of substantially vertical support pieces (32) arranged at a predetermined pitch along the longitudinal direction of the support base (31), and a bent portion bent in a U shape. A plurality of bimetals (33) connected to the upper end or lower end of each support piece (32), and shutter pieces (34) provided at both ends of each bimetal (33) and projecting in the width direction of the ventilation layer. I have. Each bimetal (33) opens the ventilation layer by holding the shutter pieces (34) arranged at the opposite end portions thereof at a distance from each other under normal temperature conditions (see FIG. 8). Under the temperature condition of 200 ° C., the shutter pieces (34) are held in contact with each other and have a property of blocking the ventilation layer (see FIG. 9).
[0030]
The support base (31) is made of a metal plate similar to the shutter base (11) of the flameproof shutter (10) according to the first invention described above, and is substantially along the structural face material (C) shown in FIG. It has a joint part (31A) extending horizontally, and a plurality of support parts (31B) projecting substantially horizontally from the lower edge of the joint part (31A) into the ventilation layer (A). The support portions (31B) are arranged at a predetermined pitch in the longitudinal direction of the joint portion (31A), and the air holes (31C) are formed between the support portions (31B). The joint portion (31A) is nailed to the structural face material (C), so that the support base (31) is installed substantially horizontally along the width direction of the ventilation layer (A).
[0031]
The upper end of each support piece (32) is welded to the lower surface of each support portion (31B) of the support base (31). Each support piece (32) stands along the gap interval direction of the ventilation layer (A) shown in FIG. 3, and is arranged at a predetermined pitch along the width direction of the ventilation layer (A). Each bimetal (33) is formed in a band shape having a width that is slightly smaller than the gap interval of the air-permeable layer (A) shown in FIG. 3, and the central portion of the inner surface that is bent in the U-shape is each support piece (32). It is welded to the lower end.
[0032]
The shutter piece (34) is formed in an L-shaped cross-section from the same kind of metal plate as the shutter piece (12) of the flameproof shutter (10). The shutter piece (34) has a width dimension equivalent to that of the bimetal (33), and one piece is welded to the outer surface of the end of the bimetal (33). Instead of the shutter piece (34), both ends of the bimetal (33) can be bent outward at substantially right angles to form a shutter piece.
[0033]
The flameproof shutter (30) according to the third invention is similar to the flameproof shutter (10) according to the first invention, in the vicinity of the drain opening (D) of the ventilation layer (A) shown in FIG. It is installed at at least one location near the eaves opening (E) or near the boundary (H).
[0034]
The flameproof shutter (30) according to the third aspect of the invention arranged in the ventilation layer (A) is in a contracted state in which each bimetal (33) is closed in a U shape as shown in FIG. Therefore, the shutter pieces (34) fixed to the opposite end portions of the bimetals (33) are held in a state of being separated from each other. Accordingly, the ventilation layer (A) communicates vertically with the space between the opposing shutter pieces (34) and the ventilation holes (31C) of the support base (31). It can be opened to ensure that the ventilation is maintained.
[0035]
On the other hand, when the temperature in the vicinity of the flameproof shutter (30) in the ventilation layer (A) reaches 100 to 200 ° C. due to the occurrence of a fire, as shown in FIG. The shutter pieces (34) that spread and face each other are held in contact with each other. Therefore, the ventilation layer (A) is blocked in the vertical direction by each bimetal (33) and each shutter piece (34) continuous in the width direction, and the ventilation layer (A) is reliably blocked to prevent the flame. Can be blocked. As a result, it is possible to avoid a situation in which the flame spreads rapidly through the ventilation layer (A), and to suppress the fire spread of the building.
[0036]
Further, when the temperature in the vicinity of the flameproof shutter (30) in the ventilation layer (A) decreases to near room temperature due to fire suppression, as shown in FIG. 8, each bimetal (33) is thermally contracted in a U shape and faces each other. The shutter pieces (34) are returned to a state of being separated from each other. Therefore, the ventilation layer (A) can be opened again to restore the ventilation.
[0037]
Next, a flameproof shutter according to the fourth invention will be described. A flameproof shutter according to a fourth aspect of the present invention is a flameproof shutter installed in a ventilation layer (A) of a building, as indicated by reference numeral (40) in FIGS. (41A) and a shutter base (41) provided with an upper partition piece (41B) and a lower partition piece (41C) installed across the ventilation layer (A), and a lower partition piece (41C) The shutter piece (42) capable of closing the vent hole (41A) by overlapping and the vent hole (41A) of the lower partition piece (41C) are passed through and suspended from the upper partition piece (41B). And a suspension spring (43) to be held. The suspension spring (43) is made of a shape memory alloy, and is deformed into an extended state in which the shutter piece (42) is separated below the lower partition piece (41C) under normal temperature conditions (see FIG. 10). Under the transformation temperature condition of 200 ° C., the shutter piece (42) has a property of returning to the contracted state where it is overlaid on the lower partition piece (41C) (see FIG. 11).
[0038]
The shutter base (41) is made of a metal plate similar to the shutter piece (11) of the flameproof shutter (10) according to the first invention described above, and has a U-shaped cross section as shown in FIGS. It is formed into a shape. The shutter base (41) has a side wall portion that connects the base portion of the upper partition piece (41B) and the base portion of the lower partition piece (41C) to the structural face material (C). It is constructed substantially horizontally along the width direction of the layer (A). In such a shutter base (41), the upper partition piece (41B) and the lower partition piece (41C) have a plurality of air holes (41A) similar to the air holes (11A) arranged in the longitudinal direction. Yes.
[0039]
The shutter piece (42) is formed in a disk shape having a size capable of closing the vent hole (41A) by the same metal plate as the shutter piece (12) of the flameproof shutter (10). The suspension spring (43) has a hook at its upper end hooked to a substantially central portion in the width direction of the upper partition piece (41B), and a linear portion at its lower end fixed to the substantially central portion of the shutter piece (42). Has been.
[0040]
The flameproof shutter (40) according to the fourth invention is similar to the flameproof shutter (10) according to the first invention, in the vicinity of the drain opening (D) of the ventilation layer (A) shown in FIG. It is installed at at least one location near the eaves opening (E) or near the boundary (H).
[0041]
As shown in FIG. 10, the flameproof shutter (40) according to the fourth aspect of the present invention installed in the ventilation layer (A) has a suspension spring (43) in an extended state as shown in FIG. The shutter piece (42) is suspended below the lower partition piece (41C). That is, each shutter piece (42) opens each vent hole (41A) of the lower partition piece (41C), and passes through each vent hole (41A) of the lower partition piece (41C) and the upper partition piece (41B). The ventilation layer (A) communicates vertically. Therefore, the ventilation layer (A) can be reliably opened and the ventilation can be reliably maintained.
[0042]
On the other hand, when the temperature near the flameproof shutter (40) in the ventilation layer (A) reaches 100 to 200 ° C. due to a fire, the suspension spring (43) returns to the contracted state as shown in FIG. The shutter piece (42) is overlaid on the lower partition piece (41C). That is, each shutter piece (42) closes each ventilation hole (41A) of the lower partition piece (41C), and the ventilation layer (A) can be reliably cut off to block the flame. As a result, it is possible to avoid a situation in which the flame spreads rapidly through the ventilation layer (A), and to suppress the fire spread of the building.
[0043]
Further, when the temperature in the vicinity of the flameproof shutter (40) in the ventilation layer (A) is lowered to near room temperature due to the fire extinguishing, as shown in FIG. 10, each suspension spring (43) returns to the extended state and each shutter is released. The piece (42) is suspended in a state of being separated below the lower partition piece (41C). Therefore, the ventilation layer (A) can be opened again to restore the ventilation.
[0044]
In addition, the flameproof shutter (10) according to the first invention, the flameproof shutter (20) according to the second invention, and the flameproof shutter (30) according to the third invention are respectively in the orientation shown in the drawing. It may be installed in the ventilation layer (A) with the top and bottom reversed.
[0045]
【The invention's effect】
As described above, according to the flameproof shutter according to the first aspect of the present invention, the connecting member holds the shutter piece in a state separated from the shutter base and opens a plurality of vent holes in the shutter base under normal temperature conditions. The ventilation layer can be reliably opened. On the other hand, under high temperature conditions, the connecting member is thermally deformed to hold the shutter piece so as to overlap the shutter base and close the plurality of air holes in the shutter base, so that the air-permeable layer can be reliably blocked. Accordingly, ventilation of the ventilation layer can be maintained in normal times, the flame can be reliably shut off in the event of a fire, and ventilation of the ventilation layer can be recovered again after the fire is extinguished.
[0046]
According to the flameproof shutter of the second invention, the connecting member holds the shutter piece in a state of being separated from the shutter base and opens a plurality of vent holes in the shutter base under normal temperature conditions. Can be opened. On the other hand, at a high temperature of 100 to 200 ° C., the connecting member holds the shutter piece in a state where it overlaps the shutter base and closes the plurality of air holes in the shutter base, so that the air-permeable layer can be reliably blocked. Accordingly, ventilation of the ventilation layer can be maintained in normal times, the flame can be reliably shut off in the event of a fire, and ventilation of the ventilation layer can be recovered again after the fire is extinguished.
[0047]
Furthermore, according to the flameproof shutter according to the third invention, under normal temperature conditions, each bimetal holds each shutter piece adjacent to each other so that the air-permeable layer can be opened reliably. . On the other hand, under the temperature condition of 100 to 200 ° C., each of the bimetals keeps the adjacent shutter pieces in contact with each other, so that the air-permeable layer can be reliably blocked. Accordingly, ventilation of the ventilation layer can be maintained in normal times, the flame can be reliably shut off in the event of a fire, and ventilation of the ventilation layer can be recovered again after the fire is extinguished.
[0048]
According to the flameproof shutter according to the fourth aspect of the present invention, under normal temperature conditions, the extended shape memory alloy suspension spring suspends the shutter piece separately below the lower partition piece, Since the plurality of ventilation holes of the partition piece and the lower partition piece are opened, the ventilation layer can be reliably opened. On the other hand, under the transformation temperature condition of 100 to 200 ° C., the suspension spring returns to the contracted state, the shutter piece is overlapped with the lower partition piece, and the plurality of air holes of the lower partition piece are closed, so that the ventilation layer is surely blocked. I can do it. Therefore, ventilation of the ventilation layer can be maintained during normal times, the flame can be reliably shut off in the event of a fire, and ventilation of the ventilation layer can be recovered again after the fire is extinguished.
[Brief description of the drawings]
FIG. 1 is a vertical sectional view showing the structure of a flameproof shutter according to a first invention.
FIG. 2 is a vertical sectional view showing the operation of the flameproof shutter according to the first invention.
FIG. 3 is a vertical sectional view of a wall portion of a building having a ventilation layer in which the flameproof shutter of the present invention is installed.
FIG. 4 is a vertical sectional view showing the structure of a flameproof shutter according to a second invention.
FIG. 5 is a vertical sectional view showing the operation of the flameproof shutter according to the second invention.
FIG. 6 is a perspective view showing an example of a bimetal shape of a flameproof shutter according to a second invention.
FIG. 7 is a perspective view showing another example of the bimetal shape of the flameproof shutter according to the second invention.
FIG. 8 is a perspective view showing a structure of a flameproof shutter according to a third invention.
FIG. 9 is a perspective view showing the operation of the flameproof shutter according to the third invention.
FIG. 10 is a vertical sectional view showing the structure of a flameproof shutter according to a fourth invention.
FIG. 11 is a vertical sectional view showing the operation of the flameproof shutter according to the fourth invention.
[Explanation of symbols]
10: Flameproof shutter
11: Shutter base
11A: Ventilation hole
11B: Joining piece
11C: Joining piece
12: Shutter piece
13: Connecting member
20: Flameproof shutter
21: Shutter base
21A: Ventilation hole
21B: Joining piece
21C: Joining piece
22: Shutter piece
23: Connecting member
23A: Connecting rod
23B: Bimetal
23C: Ventilation hole
23D: Ventilation cutout
30: Flameproof shutter
31: Support base
31A: Junction
31B: Support part
31C: Ventilation hole
32: Support piece
33: Bimetal
34: Shutter piece
40: Flameproof shutter
41: Shutter base
41A: Ventilation hole
41B: Upper partition piece
41C: Lower partition piece
42: Shutter piece
43: Suspension spring
A: Ventilation layer
B: Exterior wall material
C: Structural face material
D: Drainage opening
E: Eave sky opening
F: Interior material
G: Heat insulating material
H: boundary

Claims (2)

A flameproof shutter installed in a ventilation layer of a building, the shutter base having a plurality of ventilation holes and extending across the ventilation layer, and each of the passages by overlapping with one side of the shutter base. A shutter piece capable of closing the air holes, and a connecting member for connecting the shutter piece to the shutter base and supporting the shutter piece on one side thereof, the connecting member having one end fixed to the shutter piece and penetrating the vent hole A connecting rod, and a bimetal bent in a lateral U shape and having one end fixed to the other surface of the shutter base and the other end fixed to the other end of the connecting rod, Under normal temperature conditions, the shutter piece is held away from the shutter base, and under the temperature condition of 100 to 200 ° C., the shutter piece is held in a state of being overlapped with the shutter base. Flameproofing shutter characterized and. A flameproof shutter installed in a ventilation layer of a building, wherein the support base is mounted horizontally along the width direction of the ventilation layer, and a plurality of the shutters are arranged at a predetermined pitch along the longitudinal direction of the support base. A substantially vertical support piece, a plurality of bimetals bent in a U shape and connected to the upper end or lower end of each support piece, and the width direction of the ventilation layer provided at both ends of each bimetal Each of the bimetals, in a room temperature condition, keeps the shutter pieces arranged at opposite ends thereof in a state of being separated from each other to open the air-permeable layer, and has a temperature of 100 to 200 ° C. A flameproof shutter having a property of holding the shutter pieces in contact with each other under a temperature condition and blocking the ventilation layer.

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