JP6978298B2 - Joinery - Google Patents

Description

The present invention relates to fittings used for entrances, kitchen doors, etc. of buildings, and particularly to fittings having fire resistance.

Conventionally, a fitting provided with a metal frame for fire protection (fitting frame) and a wooden fire door (door body) that can be opened and closed via a hinge on the metal frame for fire protection is known (see Patent Document 1). .. The inner peripheral wall of the metal frame for fire prevention is provided with a door stop portion having a rubber storage groove for the door stop, and the rubber for the door stop (tight material) can come into contact with the wooden fire door in the rubber storage groove for the door stop. It is stored in. The gap between the door stop rubber and the bottom of the door stop rubber storage groove is filled with a heat foaming material (thermal expansion refractory material).
This heated foam material extrudes the door stop rubber from the door stop rubber storage groove toward the peripheral edge side of the wooden fire door while thermally expanding in the event of a fire, and connects the peripheral edge of the wooden fire door and the inner peripheral wall of the fire protection metal frame. Close the gap.

Japanese Unexamined Patent Publication No. 9-13833

By the way, in the fittings described in Patent Document 1, as shown in FIG. 1 of Patent Document 1, the door stop rubber stored in the door stop rubber storage groove is attached to the door stop groove at a position where it hits a wooden fire door by adhesion or the like. It needs to be done, and the construction is complicated.
Here, it is conceivable that the door stop rubber can be easily positioned so that it can be engaged with the door stop storage groove, but in the event of a fire, the door stop rubber in the engaged state must be extruded by the thermal expansion of the heated foam material. Therefore, it is difficult to smoothly close the space between the metal frame for fire prevention and the wooden fire prevention door by the thermal expansion of the heated foam material.

An object of the present invention is to provide a fitting capable of smoothly closing between a fitting frame and a door body by the thermal expansion of a heat-expanding refractory material.

The fitting of the present invention includes a fitting frame having a door stop portion and a door body that is openably and closably attached to the fitting frame, and the door stop portion extends from the inner peripheral surface of the fitting frame. It has a groove-forming portion and a tight material that abuts on the indoor surface of the door body, and the tight material extends from the engaging base portion engaged with the groove forming portion and the engaging base portion. A heat-expanding fire-resistant material is arranged in the groove portion formed by the groove-forming portion, and at least the engaging base of the tight material is composed of a thermoplastic elastomer. It is characterized by being.
According to the fitting of the present invention, the heat-expanding refractory material is heated and thermally expanded at the time of a fire. It is easy to come off or falls off from the groove formation part. Therefore, the thermal expansion refractory material can be thermally expanded without being disturbed by the tight material, and the space between the fitting frame and the door body can be smoothly closed.
Further, since the engaging base portion made of the thermoplastic elastomer has elasticity, the engaging base portion can be engaged with the groove forming portion by pushing the engaging base portion into the groove portion formed in the groove forming portion.

In the fitting of the present invention, at least the engaging base portion of the tight material may be made of a material having a softening temperature equal to or lower than the thermal expansion temperature of the thermal expansion fireproof material.
According to such a configuration, the engaging base reaches the softening temperature and softens at the time of fire, so that the tight material easily comes off from the groove forming portion or falls off from the groove forming portion. Therefore, the thermal expansion refractory material can be thermally expanded without being disturbed by the tight material.

In the fitting of the present invention, at least the engaging base portion of the tight material may be made of a material having a melting temperature equal to or lower than the thermal expansion temperature of the thermal expansion refractory material.
According to such a configuration, when the engaging base reaches the melting temperature and melts in the event of a fire, the tight material easily comes off from the groove forming portion or falls off from the groove forming portion. Therefore, the thermal expansion refractory material can be thermally expanded without being disturbed by the tight material.

In the fitting of the present invention, the fitting frame has a prospective piece portion for forming an opening, and the groove forming portion is formed by an extension piece portion extending from the prospective piece portion and a extending piece portion extending from the extending piece portion. A side piece extending to the outdoor side, a first engaging piece extending from the side piece to the prospective piece side, and extending from the prospective piece toward the first engaging piece. It may be composed of the second engaging piece portion and the portion of the prospective piece portion located between the extending piece portion and the second engaging piece portion.
According to such a configuration, by forming between the extending piece portion and the second engaging piece portion by the prospective piece portion of the fitting frame, the groove portion does not increase the amount of protrusion of the groove forming portion toward the center of the opening. Can be formed large, and the amount of the heat-expanding refractory material arranged in this groove can be increased.
In addition, the opening position of the groove forming portion can be brought close to the prospective piece of the joinery frame, and the thermal expansion refractory material can easily bulge between the prospective surface of the door body and the prospective surface (inner peripheral surface) of the joinery frame. Can be placed in position.

In the fitting of the present invention, the groove forming portion is formed by forming the groove portion formed by the groove forming portion into a first groove portion in which the engaging base portion is arranged and a second groove portion in which the thermal expansion refractory material is arranged. It may have a partition piece portion.
According to such a configuration, the thermal expansion refractory material can be easily slid and inserted into the second groove portion while being guided by the partition piece portion. Further, since the thermal expansion refractory material is prevented from moving to the first groove portion by the partition piece portion, the engagement base of the tight material should be smoothly engaged with the first groove portion without the thermal expansion refractory material getting in the way. Can be done.

In the fitting of the present invention, an edge material is attached to the door end side of the door body, a groove forming portion is formed on the outdoor side portion of the edge material, and the groove forming portion is engaged with the groove forming portion. A tight material having a base portion and an extended fin portion is engaged, and a thermal expansion fireproof material is arranged in the groove portion formed by the groove forming portion, and at least the engaging base portion of the tight material is , May be composed of a thermoplastic elastomer.
According to such a configuration, in the event of a fire, the tight material softens and melts in the same manner as the above-mentioned door stop portion, so that the thermal expansion refractory material in the groove forming portion of the edge material heats without being disturbed by the tight material. It can be expanded to smoothly close the space between the edge material and the joinery frame.
Further, since the engaging base portion made of the thermoplastic elastomer has elasticity, the engaging base portion can be engaged with the groove forming portion by pushing the engaging base portion into the groove portion formed in the groove forming portion.

According to the present invention, it is possible to provide a fitting that can smoothly close the fitting frame and the door body by the thermal expansion of the thermal expansion refractory material.

The vertical sectional view which shows the door which concerns on embodiment of this invention. The cross-sectional view which shows the door which concerns on the said embodiment. The cross-sectional view which shows the main part of the door which concerns on the said embodiment. The cross-sectional view which shows the main part of the door which concerns on the modification of this invention. The cross-sectional view which shows the main part of the door which concerns on the modification of this invention.

[Structure of this embodiment]
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In FIGS. 1 and 2, the door 1 as a fitting according to the present embodiment is a so-called single door, and can be opened and closed by a door frame 2 which is a fitting frame fixed to an opening of an outer wall of a building and a door frame 2. It is equipped with a door 5 which is a supported door body.
In the following description, the left-right direction of the door 1 is the X-axis direction, the vertical direction is the Y-axis direction, and the indoor / outdoor direction (depth direction) is the Z-axis direction. The X, Y, and Z axis directions are orthogonal to each other.

The door frame 2 has an upper frame 10, a lower frame 20, and left and right vertical frames 30, 40. The vertical frame 30 arranged on the left side of FIG. 2 is the hanging side and the hinge 4 is attached, and the vertical frame 40 arranged on the right side of FIG. 2 is the door end side. The hinge 4 is composed of a flag hinge or the like. The inner peripheral surface formed by each prospective piece portion 113,121,213,313,321,413,421 described later of the door frame 2 forms an opening of the door frame 2.

As shown in FIG. 1, the upper frame 10 is a heat insulating profile formed by connecting an aluminum (metal) outdoor member 11 and an indoor member 12 with a heat insulating material 13 such as urethane resin, and is an outdoor member 11. And the indoor member 12 is fixed to the skeleton (not shown). The outdoor member 11 is an extruded aluminum profile having a hollow frame shape, and has a prospective piece portion 113 along the Z-axis direction. The indoor member 12 is an extruded aluminum profile and has a prospective piece portion 121 along the Z-axis direction and a door stop portion 122 that constitutes an indoor finding surface with respect to the indoor surface of the door 5. The door stop portion 122 has a groove forming portion 123 continuous with the prospective piece portion 121, and a tight material 15 (airtight material) that abuts on the indoor surface of the door 5.

The lower frame 20 is made of an extruded aluminum profile, and as shown in FIG. 1, a prospective piece portion 213 along the Z-axis direction and a door stop portion 222 constituting an indoor finding surface with respect to the indoor surface of the door 5. And have. The door stop portion 222 has a groove forming portion 223 continuous with the prospective piece portion 213 and a tight material 25 (airtight material) that abuts on the indoor surface of the door 5. Since the lower frame 20 is accommodated in, for example, mortar, heat does not flow in and out. Therefore, the lower frame 20 is not made of an aluminum heat insulating profile like the upper frame 10, but is made of an extruded aluminum profile integrally formed from the outdoor side to the indoor side. A rubber sliding portion 24 is attached to the lower frame 20. The indoor exposed surface of the lower frame 20 is covered with the sliding portion 24 and the tight material 25 described later.

As shown in FIG. 2, the vertical frame 30 on the hanging side and the vertical frame 40 on the door end side are made of aluminum (metal) outdoor members 31, 41 and indoor members 32, 42, and a heat insulating material 33 such as urethane resin. , 43 is a heat insulating profile, and like the upper frame 10, the outdoor members 31, 41 and the indoor members 32, 42 are fixed to a frame (not shown). The outdoor members 31 and 41 have a hollow frame shape, and include prospective piece portions 313 and 413 along the Z-axis direction. The indoor members 32 and 42 have a prospective piece portion 321 and 421 along the Z-axis direction, and a door stop portion 322 and 422 constituting an indoor finding surface with respect to the indoor surface of the door 5. The door stop portion 322,422 has a groove forming portion 323,423 continuous with the prospective piece portion 321 and 421, and a tight material 35, 45 (airtight material) that abuts on the indoor surface of the door 5.

In the above door frame 2, the groove forming portion 423 of the door stop portion 422 on the door end side extends laterally from the prospective surface of the prospective piece portion 421 in the X-axis direction, as shown in FIG. 3A. The extending piece portion 424, the side piece portion 425 extending to the outdoor side from the extending end edge of the extending piece portion 424 in the Z-axis direction, and the side piece portion 425 extending to the prospective piece portion 421 side in the X-axis direction. Out of the first engaging piece 427, the second engaging piece 428 extending from the prospective piece 421 toward the first engaging piece 427 in the X-axis direction, and the prospective piece 421. It is composed of a portion located between the one piece 424 and the second engaging piece 428. A partition piece portion 425A is formed on the side piece portion 425, and a partition piece portion 426A is formed on the portion of the prospective piece portion 421. The partition piece portion 425A protrudes from the side piece portion 425 toward the prospective piece portion 421 side in the X-axis direction, and the partition piece portion 426A protrudes from the prospective piece portion 421 toward the side piece portion 425 side in the X-axis direction. It protrudes, and the protruding end edges of the partition pieces 425A and 426A face each other with a gap in the X-axis direction. These partition piece portions 425A and 426A divide the groove portion 429, which is a space formed by the groove forming portion 423, into a first groove portion 429A on the outdoor side and a second groove portion 429B on the indoor side, and the first groove portion. An engaging portion 453 of the tight material 45, which will be described later, is arranged in the 429A, and a thermal expansion refractory material 9 is slid and inserted along the extending piece portion 424 in the second groove portion 429B. The estimated dimensions between the partition piece portions 425A and 426A and the extension piece portion 424 are equal to or larger than the thickness dimension of the thermal expansion refractory material 9. The estimated dimension between the partition piece portion 425A and the first engaging piece portion 427 is set to be equal to or larger than the thickness dimension of the engaging portion 453 of the tight material 45. Since the dimensions are set in this way, the estimated dimension between the extending piece portion 424 and the first engaging piece portion 427 and the second engaging piece portion 428 is the thickness of the engaging portion 453 of the tight material 45. The size is equal to or larger than the total size of the size and the thickness of the heat-expanding fireproof material 9.

As shown in FIG. 3A, the tight material 45 has an engaging base portion 451 and a contact portion 455 extending from the engaging base portion 451.
In the present embodiment, the engaging base portion 451 has a plate-shaped base portion 452 and an engaging portion 453 that is continuous on the indoor side with respect to the base portion 452. A pair of engaging claws 453A projecting on both sides of the tight material 45 in the width direction (X-axis direction) are formed in the engaging portion 453. The engaging portion 453 is arranged in the first groove portion 429A, and the base portion 452 is in contact with the outdoor surfaces of the first engaging piece portion 427 and the second engaging piece portion 428 of the groove forming portion 423, and a pair of engagement portions are engaged. The joint claw 453A is engaged with the indoor surface of the first engaging piece portion 427 and the second engaging piece portion 428, respectively. In this way, the engaging base portion 451 is engaged with the groove forming portion 423.
The contact portion 455 has a hollow contact main body portion 456 continuous with the base portion 452, and contact piece portions 457 and 458 extending to the outdoor side from the contact main body portion 456. The contact piece portion 457 abuts on the indoor surface portion 521 of the door 5 in the closed position, which will be described later, and the contact piece portion 458 abuts on the prospective piece portion 413 of the outdoor member 41.
The tight material 45 is entirely composed of a thermoplastic elastomer (TPE (Thermo Plastic Elastomer)) including the engaging base portion 451 and the contact portion 455, and in the present embodiment, it is based on the thermal expansion temperature of the thermal expansion fireproof material 9. Also has low softening and melting temperatures. Further, since the tight material 45 has elasticity because it is composed of the thermoplastic elastomer, the engaging portion 453 can be pushed into the first groove portion 429A from the outdoor side and engaged with the groove forming portion 423. Moreover, the contact portion 455 can elastically contact the indoor surface of the door 5 to maintain airtightness.
As the above-mentioned thermoplastic elastomer, olefin-based or styrene-based ones are suitable for the tight material 45, but in addition, vinyl chloride-based ones, polyester-based ones, urethane-based ones, and the like may be used. Regarding the olefin-based thermoplastic elastomer, the heat resistant temperature is from about 85 ° C. to 90 ° C., the melting temperature is about 100 ° C., and the softening temperature is a temperature between the heat resistant temperature and the melting temperature. Regarding the styrene-based thermoplastic elastomer, the heat resistant temperature is from about 60 ° C. to 70 ° C., the melting temperature is about 100 ° C., and the softening temperature is a temperature between the heat resistant temperature and the melting temperature. In this embodiment, an olefin-based thermoplastic elastomer is used.
The groove forming portion 323 and the tight material 35 of the door stop portion 322 on the hanging source side shown in FIG. 2 are configured in the same manner as the groove forming portion 423 and the tight material 45 of the door stop portion 422 and are installed in opposite directions. ing. Therefore, for each configuration of the groove forming portion 423 and the tight material 35, the same reference numerals as those of the groove forming portion 423 and the tight material 45 are appropriately added to the drawings, and detailed description thereof will be omitted.
Further, as for the found dimension of the groove portion 429 in the door stop portion 322, 422, since the groove forming portion 323, 423 is formed by using a part of the prospective piece portions 321 and 421, the X axis between the door stop portions 322 and 422 is formed. It can be formed larger than the found size of the groove portion 429 in the door stop portions 122 and 222, which will be described later, without narrowing the opening size in the direction. Therefore, the volume of the groove portion 429 in the door stop portion 322,422 can be increased, and the thermal expansion refractory material 9 larger than the door stop portions 122 and 222 can be arranged in the groove portion 429.

The groove forming portion 123 of the upper door stop portion 122 shown in FIG. 1 has substantially the same configuration as the groove forming portion 423 of the door stop portion 422 on the door end side, but has a side piece portion 126. The configuration is different. Regarding the same configuration as each configuration of the groove forming portion 423 among the respective configurations of the groove forming portion 123, the same reference numerals as those of the respective configurations of the groove forming portion 423 are appropriately attached to the drawings, and detailed description thereof is omitted. The different configurations such as are described below.
As shown in FIG. 1, the side piece portion 126 extends from the extending piece portion 424 to the outdoor side in the Z-axis direction, is located between the side piece portion 425 and the prospective piece portion 121, and is located between the side piece portion 425 and the prospective piece portion 121. It is separated downward (Y-axis direction) from 121. A second engaging piece portion 428 and a partition piece portion 426A are formed on the side piece portion 126.
The tight material 15 of the upper door stop portion 122 has substantially the same configuration as the tight material 45, but is different in that it further includes a contact piece portion 459 that abuts on the indoor surface portion 521. Regarding the configurations of the tight material 15 and the same configurations as those of the tight material 45, the same reference numerals as those of the respective configurations of the tight material 45 will be appropriately added to the drawings, and detailed description thereof will be omitted.
The groove forming portion 223 and the tight material 25 of the lower door stop portion 222 are configured in the same manner as the groove forming portion 123 and the tight material 15 of the upper door stop portion 122 and are installed upside down. Therefore, for each configuration of the groove forming portion 223 and the tight material 25, the same reference numerals as those of the groove forming portion 123 and the tight material 15 are appropriately added to the drawings, and detailed description thereof will be omitted.

As shown in FIGS. 1 and 2, the door 5 has a metal outdoor surface material 51, a metal indoor surface material 52, a heat insulating core material 53, a reinforcing material 54, and a metal edge material such as aluminum. It is equipped with 55. The outdoor surface material 51 and the indoor surface material 52 are adhered to and integrated with the outdoor surface and the indoor surface of the heat insulating core material 53 with an adhesive. Therefore, the door 5 is a flush door type in which the outdoor surface material 51 and the indoor surface material 52 are attached to the outdoor surface and the indoor surface of the heat insulating core material 53 to be finished flat. An operation handle (not shown) is provided on the door end side of the door 5.
The outdoor surface material 51 and the indoor surface material 52 are made of steel plates. The outdoor surface material 51 is arranged along the outdoor surface of the heat insulating core material 53. The indoor surface material 52 is arranged along the indoor surface of the heat insulating core material 53. The heat insulating core material 53 is made of a heat insulating material made of EPS (expanded bead method polystyrene). As the heat insulating core material 53, a phenol resin-based heat insulating material may be used, or a honeycomb material (aluminum hydroxide honeycomb, ceramic honeycomb, paper honeycomb), a foam material (isocyanurate foam, urethane foam, phenol resin foam). Insulation material such as may be used. The reinforcing material 54 is composed of a composite reinforcing material including a rigid reinforcing resin material 541 and a reinforcing metal material 542 such as steel, and has a four-circumferential framework along the periphery of the door 5. The reinforcing material 54 on the door end side is provided with a lock case 6 such as a latch bolt 6A and a dead bolt (not shown) that are locked to the lock receiver 7 provided on the vertical frame 40 on the door end side so that they can appear and disappear. Is attached.

The outdoor surface material 51 includes an outdoor surface portion 511 bonded to the outdoor surface of the heat insulating core material 53, and outdoor prospective piece portions 513A, 513B bent in the Z-axis direction from the upper and lower edge edges of the outdoor surface portion 511. And the outdoor prospective piece portions 513C and 513D which are bent indoors in the Z-axis direction from the left and right end edges of the outdoor surface portion 511.
The indoor surface material 52 includes an indoor surface portion 521 bonded to the indoor surface of the heat insulating core material 53, and indoor prospective piece portions 522A, 522B bent toward the outdoor side in the Z-axis direction from the upper and lower edge edges of the indoor surface portion 521. And the indoor prospective piece 522C bent to the outdoor side in the Z-axis direction from the end edge of the indoor surface portion 521 on the hanging side, and folded to the outdoor side in the Z-axis direction from the end edge of the indoor surface portion 521 on the door end side. It has a curved indoor prospective piece 522D and an inner piece 523 bent from the outdoor edge of the indoor prospective piece 522D toward the hanging source side in the Z-axis direction.
The reinforcing resin material 541 of the reinforcing material 54 is formed in a channel shape, and the reinforcing metal material 542 is formed of flat steel whose indoor and outdoor edges are held in the holding groove 541A formed in the reinforcing resin material 541. It is configured. The reinforcing resin material 541, the reinforcing metal material 542, and the outdoor prospective pieces 513A to 513D are fastened by fastening members such as rivets and screws. The reinforcing resin material 541, the reinforcing metal material 542, and the indoor prospective piece portions 522A to 522C are fastened by fastening members such as rivets and screws.
The edge material 55 is formed of an extruded metal material such as aluminum, and sandwiches the outdoor prospective piece portion 513D with the reinforcing material 54 on the door end side. The edge material 55 is fixed to the reinforcing material 54 on the door end side by a rivet, an adhesive, or the like.
Here, the indoor edge portion 55A of the edge material 55 is located on the outdoor side of the indoor surface portion 521 as shown in FIG. 3A. Further, the indoor prospective piece portion 522D and the inner piece portion 523 are located on the outer side (vertical frame 40 side) in the X-axis direction with respect to the indoor edge portion 55A of the edge member 55. As a result, the side edge portion of the indoor surface material 52 on the door end side is arranged so that it can heat-extend to the door end side without being disturbed by the edge material 55.

Hereinafter, the above-mentioned operation of the door 1 in the event of a fire will be described.
In the event of an indoor fire, the indoor surface material 52 heats up mainly in the Y-axis direction, so that the door 5 is thermally warped like a bow, and the upper end and the lower end of the door 5 are relative to the intermediate portion of the door 5 in the Y-axis direction. And move to the outdoor side. Therefore, the gap between the upper end portion or the lower end portion of the door 5 and the tight materials 15, 25, 35, 45 is wider than that in the case where the door 5 is not warped by heat. Here, the indoor surface material 52 thermally expands in the X-axis direction, but the indoor edge portion 55A of the edge material 55 is on the outdoor side of the indoor surface portion 521 of the indoor surface material 52, and the indoor prospective piece portion 522D and the inner piece Since the portion 523 is located on the vertical frame 40 side with respect to the edge material 55 in the X-axis direction, the thermal elongation of the indoor surface material 52 in the X-axis direction is not suppressed by hitting the edge material 55. As described above, the door 5 is configured so that the heat warp of the indoor surface material 52 is not promoted due to the suppression of the heat elongation of the indoor surface material 52 in the X-axis direction.
When the indoor side is heated by an indoor fire, the tight materials 15, 25, 35, 45 soften, reach the melting temperature, and begin to melt. As a result, the tight materials 15, 25, 35, 45 are easily detached from the groove forming portions 123, 223, 323, 423, or are in a detached state. When the thermal expansion refractory material 9 reaches the thermal expansion temperature in such a state, it foams and thermally expands, and while bulging from each groove portion 429 to the outdoor side, the groove forming portions 123, 223, 323, 423 and the indoor surface portion 521 It enters into the gap between the indoor prospective pieces 522A to 522D and the gap between the prospective pieces 113, 213, 313, 413 and closes these gaps. Note that FIG. 3B shows a state in which the gap on the door end side is closed by the thermal expansion of the thermal expansion refractory material 9.
Further, in the event of an outdoor fire, the heat warp direction of the door 5 is opposite to that described above, but the tight materials 15, 25, 35, 45 are heated and easily come off from the groove forming portions 123, 223, 323, 423. When the thermal expansion fireproof material 9 subsequently reaches the thermal expansion temperature, the thermal expansion is thermally expanded, and the door frame 2 and the door 5 are closed in the same manner as described above.

[Effect of this embodiment]
(1) In the present embodiment, the thermal expansion refractory material 9 is arranged in the groove portion 429 formed by the groove forming portions 123, 223, 323, 423 of the door stop portions 122, 222, 322, 422, and the tight material 15 is provided. , 25, 35, 45 engagement bases 451 are made of a thermoplastic elastomer.
Since it has the above configuration, the thermal expansion refractory material 9 is heated and thermally expands at the time of an indoor fire. At this time, the engaging base portion 451 softens or melts, and the tight materials 15, 25, 35, 45 form the groove. It is easy to come off from 123,223,323,423, or it falls off from the groove forming portion 123,223,323,423. Therefore, the thermal expansion refractory material 9 can be thermally expanded without being disturbed by the tight materials 15, 25, 35, 45, and the space between the door frame 2 and the door 5 can be smoothly closed.
Further, since the engaging base portion 451 made of the thermoplastic elastomer has elasticity, the groove forming portions 123, 223 by pushing the engaging base portion 451 into the groove portions formed in the groove forming portions 123, 223, 323, 423. It can engage with 323,423.
Further, since the thermal expansion refractory material 9 is arranged in the groove portion 429 and is covered with the groove forming portions 123, 223, 323, 423 and the tight material 15, 25, 35, 45, the thermal expansion refractory material 9 is exposed to the outside. Can be made to look like no.
(2) Since the engaging base portion 451 is made of a material having a softening temperature equal to or lower than the thermal expansion temperature of the thermal expansion fireproof material 9, the engaging base portion reaches the softening temperature and softens in the event of a fire. This makes it easier for the tight materials 15, 25, 35, 45 to come off the groove forming portions 123, 223, 323, 423, or to fall off from the groove forming portions 123, 223, 323, 423. Therefore, the thermal expansion refractory material 9 can be thermally expanded without being disturbed by the tight materials 15, 25, 35, 45.
(3) Since the engaging base portion 451 is made of a material whose melting temperature is equal to or lower than the thermal expansion temperature of the thermal expansion fire resistant material 9, the engaging base portion 451 reaches the melting temperature and melts in the event of a fire. By doing so, the tight materials 15, 25, 35, 45 are likely to come off from the groove forming portion 123, 223, 323, 423, or fall off from the groove forming portion 123, 223, 323, 423. Therefore, the thermal expansion refractory material 9 can be thermally expanded without being disturbed by the tight materials 15, 25, 35, 45.
(4) The tight materials 15, 25, 35, 45 have elasticity because all of them are composed of a thermoplastic elastomer. Therefore, as described above, the engaging base portion 451 can be pushed toward the groove portion 429 while being bent to engage with the groove forming portions 123, 223, 323, 423, and the indoor surface portion 521 of the contact portion 455 can be engaged. Airtightness can be maintained by abutting against. Further, in the event of a fire, the engaging base portion 451 softens or melts, so that the groove forming portions 123, 223, 323, and 423 can be easily disengaged.
(5) The groove forming portion 323, 423 has a portion located between the extending piece portion 424 and the second engaging piece portion 428, which is composed of the prospective piece portion 321, 421 of the door frame 2. Therefore, the groove portion 429 can be formed large without increasing the amount of protrusion of the groove forming portions 323 and 423 toward the center of the opening, and the amount of the thermal expansion refractory material 9 arranged in the groove portion 429 can be increased. Further, the opening position of the groove forming portions 323 and 423 can be brought close to the prospective piece portions 321 and 421, and the thermal expansion refractory material 9 can be easily bulged between the prospective surface of the door 5 and the prospective surface of the door frame 2. Can be placed in position.
(6) The groove forming portions 123, 223, 323, 423 have partition piece portions 425A, 426A in which the groove portion 429 divides the first groove portion 429A and the second groove portion 429B. Therefore, the thermal expansion refractory material 9 can be easily slid and inserted into the second groove portion 429B while being guided by the partition piece portions 425A and 426A. Further, since the thermal expansion refractory material 9 is prevented from moving to the first groove portion 429A by the partition piece portions 425A and 426A, the thermal expansion refractory material 9 does not interfere with the tight materials 15, 25, 35 and 45. The combined base portion 451 can be smoothly engaged with the first groove portion 429A.
(7) The estimated dimension between the extending piece portion 424 and the first engaging piece portion 427 and the second engaging piece portion 428 is the engaging portion 453 arranged in the first groove portion 429A of the engaging base portion 451. The size is equal to or larger than the total of the thickness of the heat-expanding fireproof material 9 and the thickness of the heat-expanding fireproof material 9. Therefore, the engaging portions 453 of the tight materials 15, 25, 35, 45 are arranged in the groove portion 429 while engaging with the first engaging piece portion 427 and the second engaging piece portion 428, and the groove forming portion 123, The thermal expansion refractory material 9 can be arranged along the extension piece portion 424 of 223, 323, 423. As a result, the thermal expansion refractory material 9 is arranged in a direction that allows it to easily swell from between the first engaging piece portion 427 and the second engaging piece portion 428 due to thermal expansion. It can be closed smoothly.

[Modification example]
The present invention is not limited to the configuration described in the above embodiments, and modifications to the extent that the object of the present invention can be achieved are included in the present invention.
For example, in the above embodiment, the groove forming portion 423 is a double pocket having partition piece portions 425A and 426A and partitioned into the first groove portion 429A and the second groove portion 429B. For example, in FIG. 4A. As shown, the configuration of the partition piece portions 425A and 426A may be omitted to form a single pocket.
Further, as shown in FIG. 4B, the engaging portion 453 of the tight material 45 is provided at a position closer to the prospective piece portion 421 with respect to the base portion 452, and the extending piece portion 424 is found and extended inward, and the tip thereof is extended. By providing the side piece portion 431 extending from the edge to the outdoor side, a groove portion 430 adjacent to the groove portion 429 to which the engaging portion 453 is engaged is formed, and the thermal expansion refractory material 9 is arranged in the groove portion 430. May be good.
Similarly, the groove forming portions 123, 223, and 323 may be made into a single pocket, or a groove portion 430 may be provided and the thermal expansion refractory material 9 may be arranged therein.
In the above embodiment, the indoor edge portion 55A of the edge material 55 is located on the outdoor side of the indoor surface portion 521, and the indoor prospective piece portion 522D and the inner piece portion 523 are located on the vertical frame 40 side of the indoor edge portion 55A. However, as shown in FIG. 5, for example, the inner piece portion 523 may be omitted, and the indoor prospective piece portion 522D may be arranged between the reinforcing member 54 and the edge member 55.
Further, as shown in FIG. 5, a groove forming portion 553 may be formed on the outdoor side portion of the edge material 55, and the tight material 56 (watertight material) may be engaged with the groove forming portion 553. The tight material 56 has an engaging base portion 561 and an extending fin portion 565 extending from the engaging base portion 561. In the present embodiment, the engaging base portion 561 has a plate-shaped base portion 562 and an engaging portion 563 that is continuous on the indoor side with respect to the base portion 562. The engaging portion 453 is arranged in the groove portion 529, which is a space formed by the groove forming portion 553. Further, the thermal expansion refractory material 9 is slid and inserted in the groove portion 529 along the Z-axis direction.
The tight material 56 is entirely composed of a thermoplastic elastomer (TPE (Thermo Plastic Elastomer)) including the engaging base portion 561 and the extending fin portion 565, and in the present embodiment, the thermal expansion temperature of the thermal expansion fireproof material 9 is formed. It has a lower softening temperature and melting temperature. Further, since the tight material 56 is made of a thermoplastic elastomer and has elasticity, the engaging portion 563 can be pushed into the groove portion 529 from the outdoor side to engage with the groove forming portion 553. The extending fin portion 565 is arranged so as to face the vertical frame 40 on the door end side, thereby improving the watertightness.
The tight material 56 softens and melts when heated during a fire, while the thermal expansion fireproof material 9 in the groove 529 foams and thermally expands in the X-axis direction toward the vertical frame 40 side. Since the tight material 56 softens and melts and easily comes off from the groove forming portion 553 or comes off, the thermal expansion refractory material 9 thermally expands without being disturbed by the tight material 56, and the edge material 55 and the vertical frame 40 The space can be closed smoothly.
In the above embodiment, the tight materials 15, 25, 35, 45 are entirely made of a thermoplastic elastomer, but the engaging base portion 451 is made of a thermoplastic elastomer and the contact portion 455 is made of a different elastic material. You may.
In the above embodiment, the groove forming portions 123 and 223 have the side piece portions 126, so that the groove portions 429 are located at positions separated from the prospective piece portions 121 and 213, but the present invention is not limited to this. It may be configured in the same manner as the groove forming portions 323 and 423 utilizing a part of 321 and 421. Further, the groove forming portions 323 and 423 may be provided with the side piece portions 126 and may be configured in the same manner as the groove forming portions 123 and 223.
In the above embodiment, the reinforcing material 54 is framed around four circumferences, but the configuration of the reinforcing material 54 at the upper part and the lower part of the door 5 may be omitted.
In the above-described embodiment, the single-door door 1 has been described as a fitting, but in addition, any opening-type fitting in which a door body can be opened and closed can be attached to a fitting frame having a door stop portion, for example, an outer case window. It may be an inward casement window, a rotating window, a vertical sliding window, an inwardly tilted window, a protruding window, or various casement doors or doors.

1 ... Door (joint), 113,121,213,313,321,413,421 ... Expected piece part, 122,222,322,422 ... Door stop part, 123,223,323,423 ... Groove forming part, 15 , 25, 35, 45, 56 ... Tight material, 2 ... Door frame (joint frame), 30, 40 ... Vertical frame, 424 ... Extension piece, 126, 425,431 ... Side piece, 425A, 426A ... Partition One part, 427 ... First engagement piece part, 428 ... Second engagement piece part, 429, 430, 529 ... Groove part, 429A ... First groove part, 429B ... Second groove part, 451, 561 ... Engagement base part, 452 , 562 ... base, 453,563 ... engaging part, 453A ... engaging claw, 455 ... contact part, 5 ... door (door body), 51 ... outdoor surface material, 52 ... indoor surface material, 521 ... indoor surface part, 522A to 522D ... Indoor prospective piece, 53 ... Insulation core material, 54 ... Reinforcing material, 55 ... Edge material, 55A ... Indoor edge part, 565 ... Extended fin part, 9 ... Thermal expansion fireproof material.

Claims (5)

It is equipped with a fitting frame having a door stop and a door body that can be opened and closed attached to the fitting frame.
The door stop portion has a groove forming portion extending from the inner peripheral surface of the joinery frame and a tight material that abuts on the indoor surface of the door body.
The tight material has an engaging base portion engaged with the groove forming portion and a contact portion extending from the engaging base portion.
A thermal expansion refractory material is arranged in the groove formed by the groove forming portion.
At least the engaging base of the tight material is made of a thermoplastic elastomer .
The joinery frame has a prospective piece that forms an opening.
The groove forming portion is an extension piece portion extending from the prospective piece portion, a side piece portion extending from the extension piece portion to the outdoor side, and a side piece portion extending from the side piece portion to the prospective piece portion side. The first engaging piece portion, the second engaging piece portion extending from the prospective piece portion toward the first engaging piece portion, and the extending piece portion and the second of the prospective piece portions. It is composed of a part located between the engaging pieces.
The engaging base portion has an engaging claw that is arranged in the groove portion so as to be engageable with the first engaging piece portion and the second engaging piece portion.
Each of the estimated dimension between the extending piece portion and the first engaging piece portion and the estimated dimension between the extending piece portion and the second engaging piece portion is the thickness dimension of the engaging claw. A fitting characterized in that the dimension is larger than the estimated dimension including the thickness dimension of the heat-expanding fireproof material. In the fitting according to claim 1,
A fitting characterized in that at least the engaging base of the tight material is made of a material having a softening temperature equal to or lower than the thermal expansion temperature of the thermal expansion refractory material. In the fitting according to claim 1 or 2.
A fitting characterized in that at least the engaging base of the tight material is made of a material having a melting temperature equal to or lower than the thermal expansion temperature of the thermal expansion fireproof material. In the fitting according to any one of claims 1 to 3,
The groove forming portion has a partition piece portion that partitions the groove portion formed by the groove forming portion into a first groove portion in which the engaging base portion is arranged and a second groove portion in which the thermal expansion refractory material is arranged. Joinery characterized by the fact that it is used. In the fitting according to any one of claims 1 to 4,
An edge material is attached to the door end side of the door body, and the edge material is attached.
A groove forming portion is formed on the outdoor side portion of the edge material.
A tight material having an engaging base portion and an extending fin portion is engaged with the groove forming portion.
A thermal expansion refractory material is arranged in the groove formed by the groove forming portion.
A fitting characterized in that at least the engaging base of the tight material is made of a thermoplastic elastomer.

Images