JP6683494B2 - Cushion structure component and method for manufacturing joined body of highly breathable elastic body and foamed body portion - Google Patents

Description

  TECHNICAL FIELD The present invention relates to a cushion structure component and a method for manufacturing a joined body of a highly breathable elastic body and a foam portion.

  With increasing concern about the environment, idling stop has become popular as one of the fuel-efficient technologies for vehicles. Since the air conditioner of the idling stop also stops when the vehicle is stopped, there is a demand for improving passenger temperature sensitivity. Further, in a vehicle that uses electric power such as EV and PHV as a main power source, the cruising distance becomes a more important issue than HEV. It is an urgent task to improve the cruising range of EVs and PHVs in the future by reducing the power consumption by using an air conditioner to extend the cruising range.

  For example, Patent Document 1 discloses a three-dimensional net-like structure formed by a plurality of elastic resin wire rods being bent while being entangled with each other and being bonded to each other at a plurality of bonding points. Such a three-dimensional network structure has excellent properties as a cushioning material. Further, such a three-dimensional net-like structure has excellent air permeability.

JP-A-7-60861

  In addition, in the background technology, a highly breathable elastic body such as breath air is integrally foamed with urethane, and then a fan, a seat heater, or the like is attached. For this reason, not only is the work burden on the seat supplier increased, but the final vehicle assembly manufacturer must also fit two connectors for the fan and the heater.

  For vehicle manufacturers, the number of connectors at the time of seat mounting is strictly regulated in order to improve work efficiency, and even if the number of equipment is increased to improve CS, it is often not allowed. Also, on the air conditioning unit creation side, if a dedicated design was made for each individual vehicle model, the work such as design cost and management cost would be complicated, and the number of products at the time of supply would increase. Will have to be reflected in, which will lead to loss of price competitiveness.

  Then, an object of the present invention is to provide a cushion structure part for manufacturing an air-conditioning sheet cheaply and efficiently.

  In order to achieve the above-mentioned object, a cushion structure component of the present invention is a highly breathable elastic body having breathability and elasticity, and a semi-rigid foam laminated on the bottom surface of the highly breathable elastic body. A semi-rigid foam having a portion and a fan fitted into the opening, the fan having a collar portion sandwiched between the highly breathable elastic body and the semi-rigid foam; and the highly breathable elastic body And a permeation membrane which is arranged so as to surround the side surface of the semi-rigid foam and which is capable of permeating a liquid foam raw material forming a foam part by solidifying while foaming.

  As described above, the cushion structure component of the present invention is a highly breathable elastic body, a semi-rigid foam having an opening, and a fan fitted in the opening and sandwiched between the highly breathable elastic body and the semi-rigid foam. A fan having a collar portion and a highly breathable elastic body and a side surface of a semi-rigid foam are arranged so as to surround the side surface, and a liquid foam raw material that forms a foam portion by solidifying while foaming can penetrate. And a permeable membrane. With such a configuration, it is possible to reduce the work cost and the number of harnesses by integrating the highly breathable elastic body and the fan and then solidifying the foam material while foaming it. Therefore, the air conditioning sheet can be manufactured inexpensively and efficiently.

3 is a cross-sectional view of the cushion structure of Example 1. FIG. FIG. 3 is an exploded perspective view of the cushion structure component of the first embodiment. 3 is a cross-sectional view of the cushion structure component of Example 1. FIG. 3 is a perspective view of the cushion structure component of Example 1 as viewed from the bottom side. FIG. FIG. 3 is an enlarged view of the vicinity of the connector of the cushion structure component of the first embodiment. It is sectional drawing of the cushion structure of Example 2. It is an exploded perspective view of a cushion structure part of Example 2. It is sectional drawing of the cushion structure component of Example 2. FIG. 7 is an exploded perspective view of a modified example of the cushion structure component according to the second embodiment. It is sectional drawing of the modification of the cushion structure component of Example 2. It is explanatory drawing of the fog ring as a fixing means. (A) is a perspective view and (b) is a side view. It is explanatory drawing of the latching arm as a fixing means. (A) is a perspective view and (b) is a side view. It is explanatory drawing of the latching claw as a fixing means. (A) is a perspective view and (b) is a side view. It is a modification in which a three-dimensional net-like structure portion is arranged on the buttocks. It is a modification in which a three-dimensional net-like structure portion is arranged on the back.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the constituent elements described in the following embodiments are mere examples, and the technical scope of the present invention is not intended to be limited thereto.

(Constitution)
First, the configuration of the cushion structure 1 including the cushion structure component 2 of this embodiment will be described with reference to FIG. The cushion structure 1 of this embodiment is applied to a vehicle seat. The cushion structure 1 supports the buttocks and legs of a vehicle occupant. The cushion structure 1 includes, as the cushion central portion 106, a cushion front portion 102 that mainly supports the passenger's legs and a cushion rear portion 104 that mainly supports the passenger's buttocks. The cushion structure 1 further includes cushion side portions (not shown) on both left and right sides of the cushion central portion 106.

  As shown in FIGS. 1 to 4, the cushion structural component 2 arranged in the cushion front portion 102 is formed by bonding a plurality of elastic resin wire rods at a plurality of bonding points while curving while intertwining with each other. The three-dimensional reticulated structure part 3 formed as a highly breathable elastic body having air permeability and elasticity, and the semi-rigid foam 4 superposed on the bottom surface of the three-dimensional reticulated structure part 3 and having an opening 41. The fan 5, which is the semi-rigid foam 4 and the fan 5 fitted into the opening 41, and which has the collar portion 51 sandwiched between the three-dimensional net-like structural portion 3 and the semi-rigid foam 4, the three-dimensional net-like structural portion 3 and the half. The solid foam 4 is arranged so as to surround the side surface of the rigid foam 4, and the liquid foam raw material 60 that forms the foam part 6 by being solidified while foaming can penetrate the permeation membrane 7 and the three-dimensional reticulated structure part 3. It includes a heater 8, a placed on.

  The three-dimensional network structure portion 3 is formed in a rectangular parallelepiped shape as a whole. The three-dimensional net-like structure portion 3 is formed by a plurality of elastic resin wire rods being entwined with each other and curved while being bonded to each other at a plurality of bonding points. The resin wire is made of a thermoplastic resin. As the thermoplastic resin, polyolefin-based polymers such as polyethylene and polypropylene, polyester-based polymers, polyester elastomers and polyurethane-based polymers can be applied.

  The outer diameter of this resin wire can be 0.1 to 7 mm. The resin wire rod can be a wire rod having a hollow inside. The hollow rate inside the resin wire can be set to 5 to 80%. When the three-dimensional network structure portion 3 is formed by the resin wire, the thermoplastic resin is melted by the extruder. The melted thermoplastic resin is injected as a plurality of resin wire rods from a nozzle and is naturally dropped. While still in the molten state, a plurality of resin wires are bonded to each other at bonding points. By solidifying the adhered resin wire, the three-dimensional net-like structure part 3 can be manufactured.

  The semi-rigid foam 4 is formed in a rectangular plate shape as a whole. The semi-rigid foam 4 is a semi-rigid urethane foam used as a cushioning material (shock absorber) or the like, and exhibits intermediate properties between a soft foam and a hard foam. The features of semi-rigid foam 4 are that it is versatile in processing and can be used in a variety of shapes from circular and rod shapes to punching and cutting, has soundproofing and sound absorbing properties, and has high elasticity and is suitable as a cushioning material. It has excellent heat insulation properties and is effective in keeping heat and cold. Then, in the semi-rigid foam 4 of this embodiment, a square opening 41 is formed near the center. The opening 41 is formed to have substantially the same shape as the external shape (of the main body) of the fan 5 described later, and the (main body of) the fan 5 is fitted therein. Further, as shown in FIG. 4, a plurality of slits 42 are arranged on the bottom surface (back surface) of the semi-rigid foam 4 so as to surround the opening 41. Further, even when the slit 42 is not formed, the slit can be formed at the same time when the jig is strongly inserted to fix the film (permeation membrane).

  The fan 5 is a propeller-type blower (cooling fan) having a thickness of about 5 mm to 50 mm used for cooling a power supply and a CPU in a personal computer or the like. The fan 5 may be of any type as long as it can blow a predetermined amount of air to the three-dimensional net structure 3. The size of the fan 5 is, for example, 40 mm square, 60 mm square, 80 mm square, 90 mm square, or 120 mm square. The fan 5 of the present embodiment has a substantially square main body 50 having a built-in motor and propeller, and a collar portion 51 that laterally extends in a brim shape from the upper portion of the main body. The outer shape of the main body 50 is substantially the same as the opening 41 provided in the semi-rigid foam 4. The outer shape of the collar portion 51 is slightly larger than the shape of the opening portion 41.

  The foam part 6 is formed by solidifying the liquid foam material 60 while foaming. Specifically, the foam material 60 is preferably polyurethane, but may be another foam material (for example, foam PS, foam PP, foam PE, etc.). In the manufacturing process, the foam raw material 60 is poured into the mold in a liquid state at a position adjacent to the three-dimensional network structure portion 3 via the permeable membrane 7. Then, a part of the foam raw material 60 is impregnated into the three-dimensional network structure through the permeable membrane 7. Then, an impregnated portion having an impregnated amount according to the number of superposed permeation membranes 7 or the size of the slits or voids is formed. In the present embodiment, the foam raw material 60 may be entirely impregnated in the three-dimensional network structure portion 3.

  The permeable membrane 7 is a cloth formed by weaving fibers. The fibers of the permeable membrane 7 are covered with a resin such as vinyl. Between the fibers, there are voids into which the foam material can penetrate. For the permeable membrane, for example, a non-slip sheet made of expanded vinyl chloride or the like can be applied. The permeable membrane 7 is formed in a tubular shape. The vertical width of the permeable membrane 7 is longer than the total length of the three-dimensional reticulated structure portion 3 and the semi-rigid foam 4. The perimeter of the permeation membrane 7 is made narrower in the vicinity of one edge (near the upper end in the figure) by making the length in the circumferential direction shorter and narrower in the vicinity of the other edge (near the lower side in the figure). It is pressed into the slit 42 of the rigid foam 4.

  In order to adjust the impregnation amount of the foam raw material into the three-dimensional network structure portion 3, the amount of the foam raw material 60 that permeates the permeable membrane 7 per unit time is adjusted. Specifically, in order to adjust the impregnation amount of the foam raw material 60 into the three-dimensional network structure portion 3, a plurality of permeation membranes 7 may be stacked and arranged on the side surface of the three-dimensional network structure portion 3. In addition, the amount of the foam raw material 60 that permeates the permeation membrane 7 per unit time can be adjusted by changing the size of the void portion of the permeation membrane 7. For example, by increasing the amount of resin coating that coats the fibers, it is possible to manufacture the permeable membrane 7 in which the size of the voids is made smaller.

  Instead of the osmotic membrane 7, an osmotic membrane that is a non-woven fabric made of monofilament fibers can be applied. Further, instead of the permeable membrane 7, a permeable membrane that is a resin film having a circular shape, a triangular shape, a quadrangular shape, or the like through which the foam material can penetrate can be applied. Besides, instead of the osmotic membrane 7, an osmotic membrane that is a resin film having an elongated slit portion through which the foam material can penetrate can be applied.

  Further, instead of the osmotic membrane 7, it is possible to apply an osmotic membrane that is a resin film having an L-shaped slit portion bent at the top on the surface of the resin film. On the surface of the resin film, the pair of slit portions that are bent in opposite directions are arranged so that their tops face each other. The pair of slit portions facing each other at the top allows the foam raw materials to permeate in the facing directions. Accordingly, the foam raw material that has penetrated through the slit portions in which the pair of top portions face each other is likely to bond with the foam raw material that has penetrated through the other slit portions, even in a small amount.

  Alternatively, instead of the osmotic membrane 7, it is possible to apply an osmotic membrane that is a resin film having a C-shaped (center angle 180 °) slit portion curved at the top on the surface of the resin film. On the surface of the resin film, the pair of slits curved in opposite directions are arranged so that their tops face each other. The permeable membrane having the curved slit portion has the same action as the permeable membrane.

  Further, instead of the osmotic membrane 7, it is possible to apply an osmotic membrane that is a resin film having an L-shaped slit portion bent at the top on the surface of the resin film. On the surface of the resin film, the pair of slit portions that are bent in the same direction are arranged so that their tops face in the same direction. The slit portions facing the same direction at the top allow the foam raw materials to permeate in the same direction. As a result, the foam raw material that has permeated through the slits in which the pair of tops face the same direction is likely to solidify at a closer distance from the permeation membrane.

  Alternatively, instead of the osmotic membrane 7, it is possible to apply an osmotic membrane that is a resin film having a C-shaped (center angle 180 °) slit portion curved at the top on the surface of the resin film. On the surface of the resin film, the pair of slits that are curved in the same direction are arranged so that their tops face the same direction. The permeable membrane having the curved slit portion has the same action as the permeable membrane.

  The heater 8 is formed by arranging heating wires 81 in a zigzag shape on a flat plate-shaped main body 80, and has a connector 82 at the tip of the power cable. The power cable of the heater 8 is passed between the three-dimensional net-like structure portion 3 and the foam portion 6 and is integrated with the connector 56 of the fan 5. That is, as shown in FIG. 5, the connector 56 of the fan 5 is connected (coupled) to the connector 82 of the heater 8 to form one connector. Then, at the time of assembly work, it becomes one connector and is connected to the vehicle-side connector 91.

(Method for manufacturing bonded body)
Next, a method for manufacturing the bonded body will be described. The three-dimensional reticulated structure part 3, the liquid foam raw material 60, the semi-rigid foam 4, the fan 5, and the permeation membrane 7 are prepared in advance (preparation step). Next, the main body portion 50 of the fan 5 is fitted into the opening 41 of the semi-rigid foam 4, and the collar portion 51 of the fan 5 is sandwiched between the upper surface of the semi-rigid foam 4 and the lower surface of the three-dimensional net structure portion 3 to make the semi-rigid foam. The foam 4 and the three-dimensional net-like structure 3 are overlapped (sandwiched). Next, the side surfaces of the three-dimensional net-like structure portion 3 and the semi-rigid foam 4 in the superposed state are covered with the permeable membrane 7 (covering step). At this time, the permeation membrane 7 is stretched and accommodates the three-dimensional network structure portion 3 and the semi-rigid foam 4. Next, the permeation membrane 7 protruding from the semi-rigid foam 4 is pushed into the slit 42 provided on the bottom surface of the semi-rigid foam 4 by using the jig 90 having a U-shaped cross section. In this way, the cushion structure component 2 is integrated. Further, the slit can be provided on the bottom surface of the semi-rigid foam in advance, but it is also possible to form the slit in the semi-rigid foam at the same time when the slit is pushed by using the jig 90 having a U-shaped cross section.

  Next, the integrated cushion structure component 2 is placed in the mold (placement step). Next, the liquid foam raw material 60 is poured into the mold. As a result, the foamed and foamed liquid foam material 60 is arranged so as to be adjacent to the permeable membrane 7. Next, a part of the foam raw material 60 is impregnated into the three-dimensional network structure portion 3 through the permeation film 7 (impregnation step). Then, an impregnated portion having an impregnated amount according to the number of superposed permeation membranes 7 or the size of the holes and the size of the slits or voids is formed.

  Here, when the permeation membrane of the resin film having the L-shaped slit portion bent at the top is used instead of the permeation membrane 7, the slit portions facing each other at the top face the foam raw material 60 to each other. Infiltrate in the direction. Thereby, the foam raw material 60 that has permeated through the pair of slit portions facing each other at the top portion is easily bonded to the foam raw material 60 that has permeated through the other slit portions even if the amount is small. Therefore, a stronger bonding strength can be obtained with a smaller amount of impregnation.

  Alternatively, when the permeation membrane of the resin film having the slit portion bent at the top is used instead of the permeation membrane 7, the slit portions that face the same direction at the top face the foam raw material 60 in the same direction. Infiltrate. As a result, the foam raw material 60 that has permeated through the slits in which the pair of tops face the same direction is likely to solidify at a closer distance from the permeation membrane. Therefore, a stronger bonding strength can be obtained with a smaller amount of impregnation.

  Next, the foam material 6 is foamed and solidified (step of solidifying) to form the foam portion 6. In other words, the foam raw material 60 impregnated in the impregnated portion of the three-dimensional network structure portion 3 is solidified, so that the three-dimensional network structure portion 3 and the foam portion 6 are joined. Then, the joined body in which the three-dimensional network structure portion 3 and the foam portion 6 are joined is taken out from the mold.

(effect)
Next, the effects of the cushion structure component 2 of this embodiment will be listed and described.

(1) As described above, the cushion structure component 2 of the present embodiment has a three-dimensional net-like structure formed by a plurality of elastic resin wire rods being bent while being entangled with each other and being bonded to each other at a plurality of bonding points. The structure part 3 is a semi-rigid foam 4 superposed on the bottom surface of the three-dimensional reticulated structure part 3, the semi-rigid foam 4 having an opening 41, and the fan 5 fitted in the opening 41. The fan 5 having the collar portion 51 sandwiched between the structure portion 3 and the semi-rigid foam 4 is arranged so as to surround the side surfaces of the three-dimensional net-like structure portion 3 and the semi-rigid foam 4, and by solidifying while foaming. The liquid-permeable foam raw material 60 forming the foam part 6 is permeable to the permeation film 7. With such a configuration, the three-dimensional reticulated structure portion 3 and the fan 5 are integrated, and the foam raw material 60 is foamed and solidified to reduce the work cost and the number of harnesses when assembling the vehicle and the seat. it can. Therefore, the air conditioning sheet can be manufactured inexpensively and efficiently.

  That is, the foam raw material 60 is impregnated into the three-dimensional network structure portion 3 through the permeation membrane 7. Further, the foam raw material 60 is solidified. The foam raw material 60 impregnated in the three-dimensional network structure portion 3 is solidified while being in contact with a plurality of resin wire rods of the three-dimensional network structure portion 3 over a wide area. Therefore, it is possible to manufacture a joined body of the three-dimensional network structure portion 3 and the foam body portion 6 with improved joint strength.

  Further, the foam raw material 60 is arranged so as to be adjacent to the permeation membrane 7, and the three-dimensional network structure portion 3 is impregnated with the foam raw material 60 through the permeation membrane 7. Therefore, the width of the impregnated portion formed by the foam raw material 60 impregnating the three-dimensional network structure portion 3 and then solidifying by adjusting the amount of the permeation membrane 7 that the foam raw material 60 can permeate is adjusted. You can

  At this time, the fan 5 is fitted into the opening 41 of the semi-rigid foam 4, and the foam raw material 60 is foamed in a state where the three-dimensional net-structure 3 (and the semi-rigid foam 4) and the fan 5 are integrated, The work cost for mounting the fan 5 can be reduced, and the number of harnesses can be reduced. That is, in the process of solidifying the foam raw material 60, the fan 5 can be sandwiched and fixed by the three-dimensional net-like structure portion 3 and the semi-rigid foam 4, so that the work of fixing the fan 5 is not necessary. Further, by fitting the fan 5 into the opening 41 of the semi-rigid foam 4, the fan 5 can be fixed at an accurate position.

  Further, as shown in FIGS. 1 and 2, when the heater 8 is installed on the upper surface of the three-dimensional reticulated structure part 3, wiring for the heater 8 is provided between the three-dimensional reticulated structure part 3 and the semi-rigid foam 4 to the back side. By turning, the connector 56 for the fan 5 and the connector 82 for the heater 8 can be integrated into one, as shown in FIG. Therefore, a vehicle assembly operator can connect the vehicle-side connector 91 to the heater 5 connector 56 and the fan 8 connector 82 with one touch.

(2) In addition, a slit 42 is formed on the bottom surface of the semi-rigid foam 4, the permeation membrane 7 is formed in a tubular shape, and the one end edge vicinity is pushed into the slit 42, whereby the semi-rigid foam 4 is formed. Since it is fixed, the permeable membrane 7 can be fixed by a simple operation. This step can be formed simultaneously with fixing to the slit 42 with an insertion tool having a U-shaped cross section. Furthermore, by fixing the permeation film 7 to the bottom surface of the semi-rigid foam 4, the integrity as the cushion structure component 3 can be enhanced.

(3) Furthermore, the permeation membrane 7 is a cloth formed of fibers, and the fibers forming the cloth are covered with a resin so that the surface is not exposed. Therefore, when the foam raw material 60 is impregnated into the three-dimensional network structure portion 3 through the permeation membrane 7, the bubbles of the foam raw material 60 are hard to disappear due to the unevenness of the fibers forming the cloth. Therefore, it is possible to prevent the impregnated portion of the three-dimensional network structure portion 3 impregnated with the foam raw material 60 from being cured by the disappearance of the bubbles of the foam raw material 60. In this case, the amount of impregnation can be reduced by making the size of the voids smaller.

(4) Further, the permeable membrane 7 is a non-woven fabric formed of monofilament fibers. Monofilament fibers do not have surface irregularities like multifilament fibers. Further, the non-woven fabric has less unevenness in the portion where the foam raw material 60 penetrates, as compared with the woven fabric. Therefore, when the foam raw material 60 is impregnated into the three-dimensional network structure portion 3 through the permeation membrane 7, the bubbles of the foam raw material 60 are hard to disappear due to the unevenness of the fibers forming the cloth. Therefore, it is possible to prevent the impregnated portion of the three-dimensional network structure portion 3 impregnated with the foam raw material 60 from being cured by the disappearance of the bubbles of the foam raw material 60.

(5) Further, the permeable membrane 7 is a resin film having either a hole or a slit. The resin film does not have the unevenness due to the fibers unlike the cloth of the woven fabric. Therefore, when the foam raw material 60 is impregnated into the three-dimensional network structure portion 3 through the permeation membrane 7, the bubbles of the foam raw material 60 are not extinguished due to the unevenness of the fibers forming the cloth. Therefore, it is possible to prevent the impregnated portion of the three-dimensional reticulated structure portion 3 impregnated with the foam raw material 60 from being hardened as compared with other portions due to the disappearance of the bubbles of the foam raw material 60.

(6) Then, in the method for manufacturing the joined body of the three-dimensional net-like structure portion 3 and the foam portion 6 of this embodiment, a plurality of elastic resin wire rods are entwined with each other while curving while being entangled with each other and bonded to each other at a plurality of bonding points. A step of preparing a three-dimensional reticulated structure part 3 formed by the above, a liquid foam raw material 60, a semi-rigid foam 4 having an opening 41, a fan 5 having a collar part 51, and a permeable membrane 7. And a step of fitting the fan 5 into the opening 41 and sandwiching the collar portion 51 between the semi-rigid foam 4 and the three-dimensional network structure portion 3; and a three-dimensional network structure portion 3 and the semi-rigid foam in which the collar portion 51 is sandwiched. A step of covering the side surface of the perforated membrane 4 with the permeable membrane 7; the three-dimensional net-like structural portion 3 and the semi-rigid foam 4 (that is, the integrated cushion structural component 2) covered with the permeable membrane 7, and the liquid foam raw material 60. ,, in the mold Step a; contains; via the osmosis membrane 7 impregnating the foam material 60 of the liquid in the three-dimensional network structure portion 3; and solidifying while foaming the foam material 60. For this reason, the work cost and the number of harnesses can be reduced by integrating the three-dimensional net-like structure part 3 and the fan 5 and then solidifying the foam material 60 while foaming it. Therefore, the air conditioning sheet can be manufactured inexpensively and efficiently.

  Hereinafter, the cushion structure 1A including the cushion structure component 2A (2B) different from that of the first embodiment will be described with reference to FIGS. 6 to 13. The same or equivalent portions as those described in the above embodiment will be described with the same reference numerals.

  First, the cushion structure 1A of this embodiment will be described with reference to FIG. The cushion structure 1A of the present embodiment includes a cushion front portion 102 and a cushion rear portion 104 as the cushion central portion 106. The cushion structure 1A further includes a cushion side portion (not shown). In addition, in the cushion structure 1A of the present embodiment, in addition to the front portion of the cushion front portion 102 and the cushion rear portion 104 being connected by the cushion side portion, the cushion front portion 102 (that is, the cushion structural component) The lower part of 2) is connected by the foam part 6. In other words, in the first embodiment, the cushion structure component 2 includes the semi-rigid foam 4, whereas in the second embodiment, the cushion structure component 2A does not include the semi-rigid foam.

  Next, the configuration of the cushion structure component 2A according to the present embodiment will be described with reference to FIGS. 7 and 8. The cushion structural component 2A is arranged so as to surround the three-dimensional reticulated structure part 3, the fan 5 fixed to the bottom surface of the three-dimensional reticulated structure part 3 by a fixing means, and the side surface and the bottom surface of the three-dimensional reticulated structure part 3 and foams. And a permeable membrane 7 into which the liquid foam material 60 that forms the foam part 6 by solidifying while being permeated.

  Unlike the first embodiment, the fan 5 further includes a second collar portion 52 in addition to the main body portion 50 and the (first) collar portion 51. The second collar portion 52 is formed substantially parallel to the first collar portion 51 so as to spread laterally from the upper portion of the main body portion in a brim-like shape. The length (width) of the second collar portion 52 is smaller than the length of the first collar portion 51. Then, a constricted portion is formed between the first collar portion 51 and the second collar portion 52, and the permeated membrane 7 is fixed to the cushion structure component 2A by fitting the constricted portion into the hole 71 of the permeation membrane. ing.

  The permeable membrane 7 is formed in a container shape or a bag shape. The vertical width of the permeable membrane 7 is longer than the thickness of the three-dimensional network structure portion 3. The vicinity of one edge of the permeable membrane 7 (near the upper end in the figure) is not narrowed, and the vicinity of the other edge (near the lower side in the figure) is connected by the bottom. Further, unlike the first embodiment, the permeation membrane 7 of the present embodiment has a square hole 71 formed near the center of the bottom, and the constricted portion of the fan 5 is fitted into the hole 71.

  Next, the configuration of the cushion structure component 2B of the modified example will be described with reference to FIGS. 9 and 10. The cushion structural component 2B is arranged so as to surround the three-dimensional reticulated structure part 3, the fan 5 fixed to the bottom surface of the three-dimensional reticulated structure part 3 by a fixing means, and the side surface and the bottom face of the three-dimensional reticulated structure part 3 and foams. And a permeable membrane 7 into which the liquid foam material 60 that forms the foam part 6 by solidifying while being permeated.

  The permeable membrane 7 is formed in a container shape or a bag shape. The vertical width of the permeable membrane 7 is longer than the thickness of the three-dimensional network structure portion 3. The vicinity of one edge of the permeable membrane 7 (near the upper end in the figure) is not narrowed, and the vicinity of the other edge (near the lower side in the figure) is connected by the bottom. The permeation membrane 7 of this embodiment accommodates the fan 5 without forming a hole (opening) near the center of the bottom.

  Next, the configuration of a specific example of the fixing means of the fan 5 will be described with reference to FIGS. 11 to 13. As shown in FIGS. 11A and 11B, the fan 5A is provided with a plurality of holes 52 and a fog ring 53 as fixing means, and the fog ring 53 is provided in the vicinity of the bottom surface of the three-dimensional net-like structure portion 3 and the holes of the fan 5A. The fan 5 </ b> A is fixed to the three-dimensional net-like structure portion 3 by passing through 52 and tightening. As shown in FIGS. 12 (a) and 12 (b), the fan 5 </ b> B is provided with a plurality of locking arms 54 as fixing means, and by locking the locking arms 54 near the bottom surface of the three-dimensional net-like structure part 3. That is, the fan 5B can be temporarily fixed to the three-dimensional net-like structure portion 3 by moving the fan 5B alternately as indicated by the arrow. As shown in FIGS. 13 (a) and 13 (b), the fan 5C includes a plurality of locking claws 55 as a fixing means, and by locking the locking claws 55 near the bottom surface of the three-dimensional net-like structure portion 3, The fan 5C can be temporarily fixed to the three-dimensional net-like structure 3. Then, the temporarily fixed fans 5 </ b> A to 5 </ b> C are fixed to the three-dimensional network structure portion 60 in the process in which the foam raw material 60 permeates and solidifies in the three-dimensional network structure portion 3. That is, since the foam raw material 60 also permeates and solidifies around the fixing means 52 to 55 of the fans 5A to 5C through the permeation membrane 7, the foam portion 6 and the three-dimensional network structure portion 3 are integrated. At the same time, the fans 5A to 5C are also integrated (mainly fixed).

(Action / effect)
Next, the actions and effects of the cushion structure component 2A (2B) of this embodiment will be listed and described.

(1) As described above, the cushion structure component 2A (2B) of the present embodiment is formed by a plurality of elastic resin wire rods being bent while being intertwined with each other and being bonded to each other at a plurality of bonding points. The three-dimensional reticulated structure part 3, the fan 5 fixed to the bottom surface of the three-dimensional reticulated structure part 3 by the fixing means, the side surface and the bottom surface of the three-dimensional reticulated structure part 3 are arranged so as to surround them, and by foaming and solidifying The liquid-permeable foam raw material 60 forming the foam part 6 is permeable to the permeation film 7. With such a configuration, the work cost and the number of harnesses can be reduced by integrating the three-dimensional net-like structure portion 3 and the fan 5 and solidifying the foam material 60 while foaming it. Therefore, the air conditioning sheet can be manufactured inexpensively and efficiently.

  In the process in which the foam raw material 60 permeates and solidifies through the permeable membrane 7, the foam raw material 60 also permeates and solidifies around the fixing means 52 to 55 of the fans 5A to 5C, so that the foam portion 6 and the three-dimensional net shape. At the same time that the structure 3 is integrated, the fans 5A to 5C are also integrated (fixed).

(2) Further, a hole 71 is formed in the bottom of the permeable membrane 7, and a constricted portion is formed in the fan 5, so that the hole 71 of the permeable membrane 7 fits into the constricted portion of the fan 5. ing. As described above, by fixing the permeable membrane 7 to the fan 5 fixed to the three-dimensional network structure portion 3, the permeable membrane 7 can be easily fixed. Thereby, the cushion structure component 2A (2B) can be integrated.

  Furthermore, the fan 5 may be formed without forming a hole in the bottom of the permeable membrane 7. That is, if the permeable membrane 7 is made of a material that expands and contracts and the fan 5 and the three-dimensional net-like structure portion 3 are accommodated while the permeable membrane 7 is extended, the cushion structural component 2A (2B) can be integrated. In this way, the work of integrating the cushion structure parts 2A (2B) can be simplified. In this case, the permeable membrane 7 that covers the fan 5 needs to be removed in a later step.

(3) Further, the fixing means is the fog ring 53, the latch arm 54, or the latch claw 55. With such fixing means, the foam raw material 60 can be wrapped around the fixing means and fixed. Even if a predetermined error occurs in the fixed position, the cooling effect is not significantly changed because the cool air is dispersed in a wide range by the net-like structure of the three-dimensional net-like structure portion 3.

(4) Then, in the method for manufacturing the joined body of the three-dimensional network structure portion 3 and the foam body portion 6 of this embodiment, a plurality of elastic resin wire rods are entwined with each other and curved while being bonded to each other at a plurality of bonding points. A step of preparing the three-dimensional network structure portion 3 formed by the above, the liquid foam raw material 60, the fan 5 having the fixing means, and the permeation membrane 7; the fixing means on the bottom surface of the three-dimensional network structure portion 3. The step of fixing the fan 5 by means of; the step of covering the side surface and the bottom surface of the three-dimensional network structure portion 3 with the permeation membrane 7; the three-dimensional network structure portion 3 covered with the permeation membrane 7 and the liquid foam raw material 60. A step of disposing in a mold; a step of impregnating the three-dimensional network structure portion 3 with a liquid foam raw material 60 through the permeation membrane 7; and a step of solidifying the foam raw material 60 while foaming it. . For this reason, the work cost and the number of harnesses can be reduced by integrating the three-dimensional net-like structure part 3 and the fan 5 and then solidifying the foam material 60 while foaming it. Therefore, the air conditioning sheet can be manufactured inexpensively and efficiently.

  Note that other configurations and operational effects are substantially the same as those in the above-described embodiment, and therefore description thereof will be omitted.

  Although the embodiment of the present invention has been described in detail above with reference to the drawings, the specific configuration is not limited to this embodiment, and a design change that does not depart from the gist of the present invention is not limited to the present invention. included.

  For example, in Example 1, the case where the foam raw material 60 does not wrap around the semi-rigid foam 4 of the cushion structure component 2 has been described, but the present invention is not limited to this, and the foam may be provided below the semi-rigid foam 4. The raw material 60 may wrap around.

  Further, although the case where the permeable membrane 7 is pushed into the slit 42 of the semi-rigid foam 4 has been described in the first embodiment, the invention is not limited to this, and the permeable membrane 7 can be fixed by another fixing means.

In addition, in Examples 1 and 2, an example in which the three-dimensional network structure 3 is used as the highly breathable elastic body has been described, but the present invention is not limited to this, and any member having excellent breathability may be used. Here, the highly breathable elastic body refers to an object having an air permeability (cc / cm ² / sec) of 20 cc / cm ² / sec or more and exhibiting elasticity, and is deformed when a load is applied. Is an object that has the property of returning to its original shape when unloaded. As the highly air-permeable elastic body, the three-dimensional network structure portion 3 as described in the embodiment is most preferable. The highly breathable elastic body is a three-dimensional reticulated cushion formed by fibers (woven, woven, randomly solidified), foamed plastic (foamed PP, foamed EVA, polyurethane foam, etc.), non-woven fabric. , Hard cotton, and other foam materials; and the like. In particular, a polyurethane foam that has been subjected to a non-membrane treatment is preferable because the air permeability and hardness can be arbitrarily adjusted. These elastic bodies may be used alone or in combination of two or more.

  Further, in the first and second embodiments, the configuration in which the three-dimensional net-like structure portion 3 is arranged at the position near the thigh when seated has been described, but the present invention is not limited to this, and as shown in FIGS. 14 and 15. The present invention can be applied even to a configuration in which the three-dimensional net-like structure portion 3 is arranged at a position that becomes the buttocks and the back when seated.

1: Cushion structure 2: Cushion structure parts 3: Three-dimensional mesh structure (highly breathable elastic body)
4: Semi-rigid foam; 41: Opening part; 42: Slit 5: Fan; 50: Body part; 51: Color part 6: Foam part; 60: Foam material 7: Permeation membrane; 71: Hole 90: Jig

Claims (10)

A highly breathable elastic body having breathability and elasticity,
A semi-rigid foam superposed on the bottom surface of the highly breathable elastic body, having an opening, and a semi-rigid foam,
A fan fitted into the opening, having a collar portion sandwiched between the highly breathable elastic body and the semi-rigid foam, and a fan,
A highly permeable elastic body and a permeation membrane which is arranged so as to surround the side surfaces of the semi-rigid foam, and which allows a liquid foam raw material that forms a foam part by solidifying while foaming to penetrate. , Cushion structure parts. A slit is formed on the bottom surface of the semi-rigid foam,
The cushion structure component according to claim 1, wherein the permeable membrane is formed in a tubular shape, and is fixed to the semi-rigid foam by pushing one end edge vicinity into the slit. A highly breathable elastic body having breathability and elasticity,
A fan fixed to the bottom surface of the highly breathable elastic body by fixing means,
A permeation membrane that is arranged so as to surround the side surface and the bottom surface of the highly air-permeable elastic body, and is capable of permeating a liquid foam raw material that forms a foam part by solidifying while foaming,
Equipped with
The permeation membrane is disposed so as to cover at least a part of the fan so that the foam raw material also permeates around the fixing means of the fan and is solidified.
Cushion structure parts.   A hole is formed in a bottom portion of the permeable membrane, and a constricted portion is formed in the fan so that the hole of the permeable membrane fits in the constricted portion of the fan. The cushion structure part described in 3.   The cushion structure component according to claim 3 or 4, wherein the fixing means is a fog ring, a retaining arm, or a retaining claw. The permeable membrane is a cloth formed of fibers,
The cushion structure component according to any one of claims 1 to 5, wherein the fibers forming the cloth are covered with a resin so that a surface thereof is not exposed.   The cushion structure component according to any one of claims 1 to 6, wherein the permeable membrane is a non-woven fabric formed of monofilament fibers.   The cushion structure component according to any one of claims 1 to 7, wherein the permeable membrane is a resin film having any of a hole portion and a slit portion. A step of preparing a highly breathable elastic body having breathability and elasticity, a liquid foam material, a semi-rigid foam having an opening, a fan having a collar portion, and a permeable membrane;
Fitting the fan into the opening, and sandwiching the collar between the semi-rigid foam and the highly breathable elastic body;
Covering the side surfaces of the highly breathable elastic body and the semi-rigid foam in which the collar portion is sandwiched with the permeable membrane;
Arranging the highly breathable elastic body and the semi-rigid foam covered with the permeable membrane, and the liquid foam material in a mold;
Impregnating the highly breathable elastic body with the liquid foam material through the permeable membrane;
And a step of solidifying the foam material while foaming the foam material, the method for producing a joined body of a highly breathable elastic body and a foam part. A step of preparing a highly breathable elastic body having breathability and elasticity, a liquid foam raw material, a fan having fixing means, and a permeable membrane;
Fixing the fan to the bottom surface of the highly breathable elastic body by the fixing means;
Covering the side surface and the bottom surface of the highly breathable elastic body with the permeable membrane;
Arranging the highly breathable elastic body covered with the permeable membrane and the liquid foam raw material in a mold;
Impregnating the highly breathable elastic body with the liquid foam material through the permeable membrane;
And a step of solidifying the foam material while foaming the foam material, the method for producing a joined body of a highly breathable elastic body and a foam part.