WO2006028032A1 - Heat releasing article - Google Patents

Abstract

Heat releasing articles such as a cushion capable of developing high heat-releasing property and permeability and eliminating the need of separately using devices such as an electric fan. The cushion comprises heat-releasing fins (11) in which a metal wire is wound in a coiled state to form winding units, the entire part thereof is continuously formed flat, and the adjacent winding units are displaced from each other to form space parts (112) and contact parts (113) and an external body (21) having a contact surface for placing a heat-released body thereon and storing the heat-releasing fins (11). The cushion is so formed that the heat-releasing fins (11) are disposed along the contact surface and comprises a heat-releasing route part (12) prompting heat transfer at least between the heat-releasing fins and the heat-released body.

Description

 Specification

 Heat dissipation article

 Technical field

 [0001] The present invention relates to a heat dissipation article such as a cushion cushion having heat dissipation.

 Background art

 [0002] Conventionally, various heat radiating articles such as cushions with improved heat dissipation are known. This makes it possible to use it in a comfortable state, for example, even when sitting on a cushion for a long time without sweating and getting the clothes wet.

 For example, in (Patent Document 1), the bag body is separated into a plurality of storage chambers so as to be in contact with each other at the center of the bag body, and at least a pair of openings smaller than the body portion are provided in the hollow body portion. A cushion is provided in which the filler made of greaves is accommodated in each accommodation chamber.

 [0003] Further, in Patent Document 2, an approximately parallel plane cooling flow passage formed in the vicinity of a portion of the elastic member in contact with the body, an inflow port through which air flows into the cooling flow passage, and An outlet for allowing air to flow out of the cooling passage, an electric fan provided on the inlet side or the outlet side, and a connecting flow passage provided between the electric fan and the cooling passage, Cooling that cools the body by dissipating the heat generated by physical strength by increasing the temperature gradient with the body by circulating the ambient air at a temperature lower than the body temperature almost parallel to the body surface in the cooling flow passage. The mattress is listed!

 [0004] Each of the products described above can obtain a certain degree of heat dissipation by circulating air, but it has a problem that it does not have sufficient performance and requires a large force device such as an electric fan. Therefore, the development of a heat radiating member with further improved heat radiating performance without using a complicated device has been desired.

 Patent Document 1: Japanese Patent Laid-Open No. 9299190

 Patent Document 2: International Publication WO01Z015573

 Disclosure of the invention

 Problems to be solved by the invention

[0006] In view of the above conventional situation, the present invention can exhibit high heat dissipation and air permeability, The purpose is to provide various heat dissipating products such as cushions that do not require the use of a fan or other device.

 Means for solving the problem

 [0007] In order to solve the above-mentioned problem, the present invention is wound into a metal wire cacoil shape to form a winding unit, and the whole is continuously formed flat, and adjacent winding units are displaced from each other. A radiating fin having a gap and a contact portion, and an exterior body having a contact surface on which a heat radiating body is placed and housing the radiating fin, wherein the radiating fin is disposed along the contact surface, Provided is a bedding having a heat radiation path portion that promotes heat transfer to at least the heat radiating body.

 [0008] According to the above configuration, since the heat dissipating fins having a large surface area obtained by using the coiled metal wire are housed inside the bedding exterior body, they are received from the contact surface of the bedding with the heat sink. It is possible to efficiently transfer heat to the heat dissipation path and dissipate heat. In addition, heat is conducted to the entirety of the heat radiating fins through the close contact portion of the winding unit, and the heat radiating performance is improved. Furthermore, since the air gap of the radiating fin has air permeability, the heat conducted to the entire radiating fin is released. Since the heat radiating path is provided adjacent to the heat radiating fins, heat is released to the outside of the bedding and heat retention is prevented.

 In addition, the radiating fin is obtained by continuously forming a coiled metal wire in a flat shape, and has flexibility, so that the force is dispersed when the radiated body is placed.

 Here, the coil shape is not limited to the one wound in a circular shape, but includes various shapes such as a polygon such as a triangle or a rectangle, an ellipse or a star. The bedding here is a concept including pillows, mattresses, cushions, and the like.

 [0009] In addition, the present invention provides a winding unit in which a winding unit is formed by being wound into a metal wire rod S-coil shape, and the entire winding unit is formed in a flat and continuous manner, and adjacent winding units are displaced from each other. And a heat radiating fin having a contact portion and an exterior body having a contact surface on which a heat radiating body is placed and housing the heat radiating fin on a filler, the heat radiating fin being disposed along the contact surface. A floor slip prevention mat having a heat radiation path portion that promotes heat transfer with at least the heat radiating body.

[0010] According to the above configuration, heat dissipation with a large surface area obtained by using a coiled metal wire. Since the fins are housed inside the exterior body of the floor slip prevention mat, the heat received from the contact surface with the heat sink of the floor slip prevention mat can be efficiently transferred to the heat dissipation path and can be dissipated. In addition, heat is conducted to the entire heat dissipating fin through the close contact portion of the winding unit, and the heat dissipating performance is improved. In addition, since air flows through the gap, the propagation of bacteria at the pressure ulcer site is prevented, and a clean state is maintained.

 [0011] Further, the present invention provides a winding unit formed by winding a metal wire rod coil into a coil shape, and the whole is continuously formed flat, and adjacent winding units are displaced from each other. A heat dissipating fin having a gap portion and a contact portion; and a substantially horseshoe-shaped exterior body that houses the heat dissipating fin and covers a toilet seat, and a flat surface of the heat dissipating fin is a heat radiation of the exterior body. It is a toilet seat cover having a heat radiation path portion that is arranged so as to be parallel to a seating surface on which the body is placed and promotes heat transfer with at least the heat radiating body.

 [0012] According to the above configuration, the heat dissipating fin having a large surface area obtained by using the coiled metal wire is housed inside the horseshoe-shaped exterior body serving as the toilet seat cover, so that the person using the toilet seat The heat from can be efficiently radiated and a comfortable feeling of use can be obtained. In addition, heat is conducted to the entirety of the heat radiating fins through the close contact portion of the winding unit, and the heat radiating performance is improved. Furthermore, since air circulates through the space | gap part of a radiation fin, air permeability is also improved.

 [0013] In addition, the present invention provides a winding unit in which a winding unit is formed by being wound into a metal wire rod S-coil shape, and the entire winding unit is formed flat continuously, and adjacent winding units are displaced from each other. And a heat dissipating fin having a contact portion and an exterior body that accommodates the heat dissipating fin and covers a backrest portion or a seat surface of the chair, and the exterior body includes an attachment structure for attaching to the chair, the heat dissipating fin Is a chair cover that is disposed along a contact surface of the exterior body in contact with the heat radiating body and has a heat radiation path portion that promotes heat transfer with at least the heat radiating body.

[0014] According to the above configuration, the heat dissipating fin having a large surface area obtained by using the coiled metal wire is housed in the exterior body serving as the chair cover, so that heat from the person using the chair is obtained. The heat can be efficiently radiated and a comfortable feeling of use can be obtained. In addition, heat is conducted to the entire heat dissipating fin through the close contact portion of the winding unit, and heat dissipating performance is improved. Furthermore, since air circulates through the space | gap part of a radiation fin, it becomes a highly breathable chair cover. [0015] In addition, the present invention provides a winding unit formed by winding a metal wire rod S coil, and the entire winding unit is continuously formed in a flat belt shape, and adjacent winding units are displaced from each other. A hat comprising a heat dissipating fin having a gap portion and a contact portion, a crown portion covering the head portion, and a folded portion attached along the inner peripheral edge of the crown portion, the hat being provided on the crown portion of the folded portion It is a cap having a heat radiation path part that promotes heat transfer with at least the head, wherein the heat radiation fins are arranged along the facing side.

In the present invention, the winding unit is formed by winding the metal wire rod S into a coil shape, and the whole is continuously formed in a flat belt shape, and adjacent winding units are displaced from each other. A hat provided with a radiating fin having a gap portion and a contact portion, and a crown portion that accommodates the radiating fin and covers the head, wherein the radiating fin is disposed along an inner peripheral edge of the crown portion; It is a cap having a heat radiation path portion that promotes heat transfer with at least the head.

 [0017] According to the above configuration, since the heat radiation fin having a large surface area obtained by using the coiled metal wire is housed along the crown portion of the cap, the heat received by the head force is efficiently outside. It is possible to transfer heat to and dissipate heat. In addition, heat is conducted to the entire heat dissipating fin through the close contact portion of the winding unit, and the heat dissipating performance is improved. In addition, air permeability is ensured by the gaps of the radiating fins.

 [0018] Further, the present invention is a hermet comprising a protective member that covers an outer side and a buffer member provided inside the protective member, and is wound around a metal wire material in a coiled form. The heat dissipating fins, which are continuously formed flat as a whole and have adjacent gap units displaced from each other and having gap portions and contact portions, are formed on the inner surface of the buffer member from the top to the periphery. It is a helmet that is provided with a force.

 [0019] According to the above configuration, since the heat radiation fin having a large surface area obtained by using the coiled metal wire is provided on the cushioning member of the helmet, the heat received from the head is efficiently transferred to the outside, It is possible to dissipate heat. In addition, heat is conducted to the entire heat radiation fin through the close contact portion of the winding unit, and the heat radiation performance is improved. Further, the air permeability is ensured by the gap portion of the auxiliary heat fin.

[0020] Further, according to the present invention, a winding unit is formed by winding the metal wire rod S into a coil shape. The whole is continuously formed in a flat band shape, and adjacent winding units are displaced from each other so that the heat dissipating fin has a gap and a contact part, and the heat dissipating fin is provided and the elastic ring is in contact with the head. A hair band comprising a band body, and a plurality of the heat dissipating fins arranged in a circumferential direction along the inner peripheral surface of the band body, and having a heat radiation path portion that promotes heat transfer with at least the head. It is.

 [0021] According to the above configuration, the heat dissipating fin having a large surface area obtained by using the coiled metal wire is provided on the band main body, and the heat received from the head is efficiently transferred to the outside to be dissipated. Is possible. In addition, heat is conducted to the entire heat dissipating fin through the close contact portion of the winding unit, and the heat dissipating performance is improved. In addition, air permeability is ensured by the gaps of the radiating fins.

 [0022] Further, the present invention is a shoe including a nol and an upper member that is fixed on the nol and covers a foot surface, and a metal wire rod is formed in a coil shape on the upper portion of the upper member. This is a shoe in which a winding unit is formed by being rotated and the whole is continuously formed flat, and adjacent winding units are displaced from each other and provided with heat radiation fins having a gap portion and a contact portion.

 [0023] Further, the present invention is a shoe comprising a nol and an upper member fixed on the nol and covering a foot surface, wherein a metal wire is wound in a coil shape on a toe portion of the upper member. In this shoe, the winding unit is formed and the whole is continuously formed flat, and adjacent winding units are displaced from each other and provided with heat radiation fins having gap portions and contact portions.

 [0024] Further, the present invention is a shoe comprising a nol and an upper member fixed on the nol and covering a foot surface, wherein a metal wire is wound in a coil shape on a heel portion of the upper member. In this shoe, a winding unit is formed and the whole is continuously formed flat, and adjacent winding units are displaced from each other and provided with heat radiation fins having gap portions and contact portions.

[0025] According to the above configuration, the upper member is provided with a large-surface-area radiating fin obtained by using a coiled metal wire, so that heat received from the inside of the upper part can be efficiently transferred to the outside. It is possible to dissipate heat. In addition, it is released through the close contact part of the winding unit. Heat is conducted to the entire heat fin, and the heat dissipation performance is improved. Furthermore, air permeability is ensured by the gaps of the radiating fins.

 [0026] Then, the present invention is configured such that the winding unit is formed by being wound into a metal wire rod S coil shape, and the entire winding unit is continuously formed flat, and adjacent winding units are displaced from each other. An insole comprising a radiating fin having a gap and a contact portion and an insole body in which flat surfaces of the radiating fin are provided in parallel.

 [0027] According to the above configuration, since the heat sink fin having a large surface area obtained by using the coiled metal wire is provided in the insole body, air permeability is ensured by the gap portion of the heat sink fin. In addition, since the heat dissipating fin obtained by using the coiled metal wire has an uneven shape, a massage effect can be obtained.

 [0028] Further, the present invention provides a winding unit in which a winding unit is formed by being wound in the shape of a metal wire rod S coil, and the entire winding unit is formed flat and the adjacent winding units are displaced from each other. And a heat radiating fin having a contact part and a protective member for covering and fixing the affected part, wherein the heat radiating fin is disposed along the inner side surface of the protective member, and at least heat transfer between the heat affected part and the affected part. A cast that is configured to prompt.

 [0029] According to the above configuration, since the heat radiation fins having a large surface area obtained by using the coiled metal wire are arranged inside the cast, the heat staying on the body side can be efficiently transferred and radiated. Is possible. In addition, heat is conducted to the entire heat radiation fin through the close contact portion of the winding unit, and the heat radiation performance is improved. Furthermore, the gaps of the heat dissipating fins make a cast with excellent air permeability.

 [0030] In addition, the present invention provides a winding unit in which a winding unit is formed by being wound into a metal wire rod S-coil shape, and the entire winding unit is continuously formed flat. And a heat-cooled sheet comprising at least one radiating fin having a contact portion and an attachment structure member for fixing the radiating fin to a heat radiating member.

[0031] According to the above configuration, the heat radiation fins having a large surface area obtained by using the coiled metal wire constitute the heat-cooled sheet, so that the heat of the body can be efficiently transferred and radiated. Become. In addition, heat is conducted to the entire heat dissipating fin through the close contact portion of the winding unit, and the heat dissipating performance is improved. In addition, the air radiating fin gaps allow for a highly breathable seat. Can be obtained.

 [0032] In addition, the present invention provides a winding unit in which a winding unit is formed by being wound into a metal wire rod S-coil shape, and the entire winding unit is continuously formed flat. And a plurality of heat dissipating fins having contact portions, and a thawing sheet formed in a planar shape so as to place an object to be thawed and having a larger area than the object to be thawed.

 [0033] According to the above configuration, the heat radiation fin having a large surface area obtained by using the coiled metal wire can efficiently transfer and dissipate the heat of the object placed on the base material. Become. In addition, heat is conducted to the entire heat dissipating fin through the close contact portion of the winding unit, and the heat dissipating performance is improved.

 [0034] Further, the present invention provides a winding unit in which a winding unit is formed by winding a metal wire rod S coil, and the entire winding unit is formed in a flat shape, and adjacent winding units are displaced from each other to form a gap. And a heat radiating fin having a contact portion, and an exterior body having a larger area than the personal computer when the heat radiating fin is accommodated and mounting a computer, and at least promotes heat transfer with the personal computer. A heat dissipation sheet for a personal computer having a heat dissipation path.

 [0035] Further, the present invention provides a metal wire rod coiled into an S-coil shape to form a winding unit and continuously formed flat as a whole, and adjacent winding units are displaced from each other to form a gap. A plurality of heat dissipating fins having a contact portion are connected to each other, and are formed in a planar shape so as to place a personal computer, and are a heat dissipating sheet for a personal computer having a larger area than the personal computer.

 [0036] According to the above configuration, the heat dissipating fin having a large surface area obtained by using the coiled metal wire can efficiently transfer the heat of the personal computer and dissipate the heat. In addition, heat is conducted to the entire radiating fin through the close contact portion of the winding unit, improving the heat radiating performance.

[0037] Further, according to the present invention, the winding unit is formed by being wound into a metal wire rod S coil shape, and the whole is continuously formed flat, and adjacent winding units are displaced from each other. A heat dissipating fin having a gap portion and a contact portion is arranged along the inner surface of a substantially cylindrical metal member for inserting a wine bottle, and is configured to promote heat transfer with at least the wine bottle. It is a wine cooler.

[0038] According to the above configuration, heat dissipation with a large surface area obtained by using a coiled metal wire. The fins can efficiently transfer and dissipate the heat of the wine bottle. Further, heat is conducted to the whole of the heat radiation fins through the close contact of the winding unit, so that a wine cooler with high heat radiation performance can be obtained.

 [0039] Further, according to the present invention, the winding unit is formed by being wound into a metal wire rod S coil shape, and the whole is continuously formed flat, and adjacent winding units are displaced from each other. A radiating fin having a gap portion and a contact portion is a jacket provided between the outer surface and the lining, and the lining contacts the heat radiating body and promotes heat transfer between at least the heat radiating body. A jacket having a heat dissipation path.

 [0040] According to the above configuration, the heat radiation fin having a large surface area obtained by using the coiled metal wire is embedded in the jacket, and the heat staying on the body side can be efficiently transferred to the outside to be radiated. It becomes possible. In addition, heat is conducted to the entire heat dissipating fin through the close contact portion of the winding unit, and the heat dissipating performance is improved. Furthermore, the air gap fins provide a jacket with excellent air permeability.

 The invention's effect

 [0041] As described above, various heat radiating articles such as beddings and floor slip mats according to the present invention provide a heat radiating fin having a large surface area obtained by winding a metal wire in a coil shape with a heat radiating member. Because it is provided in the heat dissipation path that promotes heat transfer, high heat dissipation and air permeability can be obtained. Moreover, since the metal wire wound by the coil shape is used, it has flexibility and can follow the deformation | transformation of the whole thermal radiation article favorably.

 Brief Description of Drawings

FIG. 1 is a perspective view of a bedding according to Embodiment (1) of the present invention.

 FIG. 2 is a plan view of FIG.

 FIG. 3 is a cross-sectional view taken along line AA showing the use state of the bedding according to the embodiment (1).

 [Fig. 4] (a) Enlarged view of heat dissipating fins. (b) It is CC sectional drawing of (a).

 FIG. 5 is a cross-sectional view taken along the line BB in FIG.

 FIG. 6 is a plan view of the bedding according to the embodiment (2) of the present invention.

 FIG. 7 is a plan view of a bedding according to Embodiment (3) of the present invention.

FIG. 8 is a perspective view of a bedding according to Embodiment (4) of the present invention. 9] A perspective view of the floor slip prevention mat according to the embodiment (5) of the present invention.

FIG. 10 is a sectional view taken along the line DD in FIG.

 FIG. 11 is a perspective view of a toilet seat cover according to Embodiment (6) of the present invention.

FIG. 12 is a cross-sectional view taken along line EE in FIG.

13] A perspective view of a chair cover according to Embodiment (7) of the present invention.

FIG. 14 is a sectional view taken along line FF in FIG.

圆 15] A perspective view of a cap according to Embodiment (8) of the present invention.

FIG. 16 is a cross-sectional view taken along line GG in FIG.

[17] A cross-sectional view of a cap according to Embodiment (9) of the present invention.

 FIG. 18 is a perspective view of a helmet according to Embodiment (10) of the present invention.

 FIG. 19 is a cross-sectional view taken along line H—H in FIG.

 FIG. 20 is a perspective view of a hair band according to Embodiment (11) of the present invention.

FIG. 21 is a sectional view taken along the line J J in FIG.

FIG. 22 is a KK cross-sectional view of FIG.

 FIG. 23 is a perspective view of a shoe according to Embodiment (12) of the present invention.

FIG. 24 is a sectional view taken on line L L in FIG.

 FIG. 25 is a perspective view of a shoe according to Embodiment (13) of the present invention.

FIG. 26 is a cross-sectional view taken along line MM in FIG. 25.

 FIG. 27 is a perspective view of a shoe according to Embodiment (14) of the present invention.

FIG. 28 is a sectional view taken along line NN in FIG. 27.

圆 29] A plan view of the insole according to the embodiment (15) of the present invention.

FIG. 30 is a cross-sectional view taken along the line PP in FIG. 29.

 FIG. 31 is a perspective view of a cast according to Embodiment (16) of the present invention.

FIG. 32 is a cross-sectional view taken along the line Q-Q in FIG.

 FIG. 33 is a plan view of a heat-cooled sheet according to Embodiment (17) of the present invention.

圆 34] A perspective view of a thawing sheet according to Embodiment (18) of the present invention.

[35] FIG. 35 is a perspective view of a heat dissipation sheet for a personal computer according to Embodiment (19) of the present invention.

FIG. 36 is a cross-sectional view taken along line RR in FIG. 35. 圆 37] A perspective view of a heat dissipating sheet for a personal computer according to Embodiment (20) of the present invention.圆 38] A cross-sectional view of a wine cooler according to Embodiment (21) of the present invention. 圆 39] A perspective view of a jacket according to Embodiment (22) of the present invention.

FIG. 40 is a cross-sectional view taken along the line S—S in FIG. 39.

Explanation of symbols

 1A, IB ゝ 1C, ID cushion

 IE Bed slip prevention mat

 IF Toilet seat cover

 1G chair cover

 1H ゝ 1J hat

 IK Henomet

 1L hair band

 1M, 1N, IP shoes

 1Q insole

 1R cast

 IS heat-cooled sheet

 IT thaw sheet

 1U, IV Heat sink sheet

 1W wine cooler

 IX Shacket

 11 Radiation fin

 111 Flat surface

 112 Cavity

 113 Contact area

 114 Protective members

 11a, l ib

l lx metal wire wound left-handed

l iy Metal wire wound right-handed Heat dissipation path exterior

1 fiber

2 Cavity a Seat

b Bottom

 hole

1 Gap

2 Exposed area of heat radiating material Buffer material Exterior body Knitting exterior body a Contact surface b Bottom surface

 hole

 Exterior body

1 back

2 waist

3 wire

a Contact surface b Bottom surface

 Filler

 T

 hole

Exterior body a Contact surface b Bottom surface 321, 322 threads

 323 gap

33A, 33B exterior body

331 Mounting structure

33a Contact surface

34 holes

 35 Crown

351 Head

352 Inner peripheral edge 352a Inner side

 36 collar

37 Folding part

38 Protection member

39 Shock absorber

391 The top of the head

392 Inner peripheral edge

40 Cover member

41 Hair band body 41a Inside surface

41b Outside 411, 411a, 411b hole

 42 sole

 43 Upper material

431 Upper

432 Toe

433

 434 Vent

435 Fixed part 436 Ventilation member

437 holes

 44 Bottom member

45 Insole body

451 end

 46 Covering material

461 edge

 47 Gypsum body

471, 472 hook and loop fasteners

47a exterior

47b Inside surface

48 Mounting structure

481 Connection

482 Mounting structure

483 hook and loop fastener

49 Metal wire

50, 50A, 50B exterior

50a Contact surface

50b bottom

 501 holes

 51 Metal wire

52 Metal parts

521 inner surface

522 Bottom

 523 Convex

 53 dress material

 54 Lining

55, 56 holes a width

 b Length

 c width

 d body

 el, e2 length

 f body

 g Toilet seat

 h chair

 i head

 j Cavity

 k feet

 m Object to be thawed

 n PC

 P Wine bottle

 BEST MODE FOR CARRYING OUT THE INVENTION

 Hereinafter, the present invention will be described in detail based on embodiments.

 First, an embodiment (1) of the present invention will be described with reference to FIGS. 1 to 5 show a cushion as a bedding.

 [0045] The cushion 1A includes a plurality of radiating fins 11 formed of a coil-shaped metal wire rod and an exterior body 21 that houses the plurality of radiating fins 11. The heat radiating fins 11 are arranged along the seating surface 21a on which the person of the exterior body 21 sits. Here, the seating surface 21a is a contact surface on which the heat sink is placed. Further, the outer body 21 is provided with a hole 22 and serves as a heat release path portion that promotes heat transfer with the heat radiating body. Further, a cushioning material 23 is provided inside the exterior body 21.

As shown in FIG. 4, the heat dissipating fin 11 is formed by winding a metal wire into a coil shape to form a winding unit, and the whole is continuously formed flat, and adjacent winding units l la, l The ibs are displaced from each other and have gaps 112 and contact parts 113. Specifically, a coiled metal wire l lx wound in a left-handed manner, a coiled metal wire 1 ly wound in a right-handed manner, and a length el in the width direction and a length e2 in the longitudinal direction Misaligned by the distance and combined It is. The metal wires llx and lly are formed flatly. The heat radiation fins 11 are formed by combining the coiled metal wires llx and lly wound in different directions, so that the metal wires llx and lly are densely formed to improve heat conductivity and heat dissipation. Performance is also improved. Further, since the left-handed and right-handed metal wire materials llx and lly are intertwined, the shape of the radiating fin 11 is stable, and the coil does not stretch due to strength or the like when the coil is continuously rolled.

 [0047] The metal wires llx and lly are formed in a flat shape, and the winding units lla and lib intersect with each other while being displaced in the width direction and the longitudinal direction to form the gap portion 112 and the contact portion 113. Since the metal wires llx and lly are formed flat, the contact area of the contact portion 113 where the winding units are in contact with each other is increased. As a result, heat is quickly conducted to the entire heat release fin 11 through the contact portion 113. Further, since the coiled metal wire llx and lly force are also formed, the surface area of the entire heat dissipating fin 11 is larger than that of a heat dissipating fin using a flat plate or the like, and thus high heat dissipating performance can be obtained. Further, since the gaps 112 are formed in the gaps between the metal wires llx and lly in the radiating fins 11, the contact area between the metal wires llx and lly and the outside air is particularly large. For this reason, the air gap portion 112 functions as a vent hole through which air or the like flows, and heat can be quickly released to the outside.

 [0048] Note that the contact portion 113 in which the winding units lla and lib are in contact with each other can be fixed as described later, but may not be fixed. When the contact part 113 is not fixed, the heat dissipation fin 11 is very flexible, so that when used in a bedding such as a cushion, the body pressure can be well dispersed. .

 [0049] It should be noted that the contact portions 113 where the winding units lla and lib are in contact with each other are connected to each other by means of soldering, soldering, adhesive, adhesive, vibration welding, flash welding, or the like. Can be fixed so as not to leave. Since the contact portion 113 is fixed, the winding units lla and lib are securely adhered to each other, and the entire radiating fin 11 is not stretched against deformation and mechanical stability is improved. In addition, the thermal conductivity through the contact part 113 is also improved.

In addition, a protective member 114 is attached to the end portion of the radiation fin 11. By attaching the protective member 11 4, the metal wires llx and lly are fixed at the end, so the shape is lost. Will not occur. Examples of the material of the protective member 114 include metal materials such as aluminum, copper, silver, and gold, or alloys of these with nickel, magnesium, zinc, and key. Copper-based and aluminum-based materials are preferably used because of their excellent thermal conductivity. In particular, an aluminum-based material is preferably used because it is excellent in thermal conductivity and flexibility, is lightweight, and is low in cost.

[0051] The metal wire wound in a coil shape can be formed into a flat shape by crushing it by a known means such as rolling. In addition, a long heat radiation fin can be obtained by continuously rolling a coil fed in one direction. At this time, it is preferable to appropriately set the rolling pressure, the rolling angle, etc. so that the adjacent winding units are properly adhered to each other.

[0052] The heat radiating fin 11 can be made of various metal materials. Specific examples include metal materials such as aluminum, copper, silver, and gold, or alloys of these with nickel, magnesium, zinc, and key. Copper-based and aluminum-based materials are preferably used because of their excellent thermal conductivity. In particular, aluminum-based materials are preferably used because they are excellent in thermal conductivity and flexibility, are lightweight, and are low in cost.

 [0053] Further, as the material of the metal wire lx, lly of the heat radiating fin 11, a corrosion-resistant metal can be used. Depending on the application, it may be used in a corrosive environment and is suitable for such cases. Examples of corrosion-resistant metals include titanium, its alloys, and stainless steel.

[0054] In addition, the metal wires l lx and l ly constituting the heat radiating fin 11 can be subjected to surface treatment in order to enhance thermal conductivity and corrosion resistance, if necessary. Specific examples include copper plating and silver plating. In addition, when aluminum or an alloy thereof is used as a material, it is preferable to subject the surface to an anodic acid coating treatment (alumite treatment). As a result, the corrosion resistance is improved and the thermal resistance of the contact portions that are in close contact with each other in the winding unit is lowered, so that the overall heat dissipation can be further improved. A known process can be adopted as a treatment method. Specifically, an acid film is formed by performing electrolysis in a liquid such as oxalic acid, sulfuric acid, phosphoric acid, etc., using the treated product as an anode. Can be formed. It should be noted that any force having so-called white alumite and black alumite can be applied to the anodic acid coating treatment. [0055] In addition, a coating film containing a fly can be formed on the surface of the metal wire lx, lly, if necessary. As a result, since the ferrite has the ability to absorb electromagnetic waves, the heat dissipating fin 11 that effectively absorbs electromagnetic waves as a whole can be obtained. In particular, since the surface of the radiating fin 11 has an uneven shape because of its metal wire force, electromagnetic waves are irregularly reflected, and the effect of electromagnetic wave absorption is increased synergistically.

 As the ferrite, soft magnetic ferrite (soft ferrite) and hard magnetic ferrite (hard ferrite) are known, but either one may be used or a plurality of types may be used in combination. . Moreover, as a binder for dispersing ferrite, general substances such as acrylic resin and silicone resin can be used without particular limitation.

 [0056] Furthermore, a heat-radiating coating film is formed on the surfaces of the metal wires l lx and l ly to quickly dissipate the heat conducted through the radiation fins 11 to the outside as needed. Can do. Such a coating film can be formed from a paint containing various pigments having a heat radiation effect. Examples of pigments include carbon black, alumina, zirconia, titania, silica, dinorecon, magnesia, yttria (Y 2 O), cordierite (2MgO '2Al O-5Si

 2 3 2 3

O 2), aluminum titanate (Al 2 O 3 —TiO 2), and the like. These will eventually

2 2 3 2

 These may be used alone or in combination. Further, the amount of the pigment in the paint can be appropriately set according to the desired thermal radiation, and generally about 10 to 90 wt% is appropriate for the dry mass of the coating film. Examples of binders that are preferably resistant to deterioration by heat include acrylic resin, silicone resin, urethane resin, polyester resin, and fluorine resin.

 The appropriate thickness of the heat-radiating coating is 1-50 m. If it is less than 1 μm, the heat radiation effect becomes small, which is not preferable.

 [0057] The diameter of the radiating fin 11 (the width of the flat surface 111) can be set as appropriate according to the required radiating performance without being particularly limited. In general, as the diameter increases, the surface area increases and heat dissipation improves. Specifically, it depends on each bedding, but a few mn! ~ A few centimeters is appropriate.

[0058] Next, as the exterior body 21, since it is necessary to diffuse heat through the air to the gaps 112 of the radiating fins 11, those having air permeability are generally preferred, and synthetic fibers and natural fibers are preferred. A textile fabric is used. As synthetic fibers, various fibers such as rayon, tencel, acetate, polyester and the like can be used. As natural fibers, various fibers such as cotton, hemp, wool and silk can be used. In the embodiment (1), a woven fabric of fibers is used, and a gap 212 is formed as a heat radiation path 12 between the fibers 211. The gap 212 acts as a heat dissipation path 12 that promotes heat transfer with the heat radiating body.

[0059] In addition, the thickness of the exterior body 21 is thin in order to promote heat transfer with the heat radiating body!

 Specifically, the thickness of the exterior body 21 is 0.02mn! About 2 mm is preferable. If it is thinner than 0.02 mm, the strength of the outer casing 21 will be low, and it may be torn when used. On the other hand, if it is thicker than 2mm, heat transfer to and from the heat sink will be reduced.

 In addition, a hole 22 is provided in the seating surface 21 a of the exterior body 21 as the heat dissipation path portion 12. As shown in FIG. 2, the hole 22 has an elliptical shape having a length b and a width c. The width c of the hole 22 is longer than the width a of the radiating fin 11, and a gap portion 222 where the radiating fin 11 is not provided and a radiating fin exposed portion 223 are formed. For this reason, the heat conducted to the radiating fin 11 is released to the outside of the exterior body 21 through the gap 222 of the hole 22 that is not limited to the gap 112 of the radiating fin 11. Further, the hole 22 is formed so that the length b is longer than the width c, and the exposed area of the radiating fin 11 is large, so that the contact area between the radiating fin 11 and the heat sink is increased. And

 The size and number of holes can be set as appropriate.For example, the hole in the center part of the cushion, which is the sitting position, can be made larger than the periphery, or the number of holes in the center part can be increased to increase the The degree of exposure may be increased.

 [0061] Further, the cushioning material 23 is filled in the exterior body 21, and a general filling material such as cotton, feathers, buckwheat husks or low-resilience urethane foam can be used.

[0062] A plurality of the heat dissipating fins 11 described above are housed inside the exterior body 21, arranged in parallel, and sewn at a predetermined position to obtain a target bedding. The belt-shaped heat release fins 11 are arranged so as to protrude in the longitudinal direction of the central partial force of the cushion that is the sitting position. For this reason, the heat transmitted from the body d, which is a heat radiating body, is quickly radiated by the end force protruding in the longitudinal direction. In addition, the arrangement method of the radiation fins 11 can be set as appropriate, for example, the radiation fins 11 may be arranged so as to cross each other.

 [0063] According to the cushion 1A according to the embodiment (1), as shown in Fig. 3, in various usage forms such as a person sleeping or sitting, the radiating fins 11 are formed from the holes 22 provided in the seat surface 21a. Exposed and in direct contact with body d, which is a heat sink. Subsequently, the heat of the body d is efficiently transferred to the entire radiation fin 11 through the contact portion 113 of the radiation fin 11. The heat conducted to the entire radiation fin 11 is diffused from the gap portion 112 of the radiation fin 11 and passes through the gap portion 212 formed between the hole 22 of the exterior body 21 and the fiber 211 as the radiation path portion 12. Through the exterior body 21.

 [0064] Further, since hot air diffuses through the gaps 112 of the radiating fin 11 and moisture such as sweat is vaporized, it does not stuffy. In addition, since the heat radiation fins 11 are cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained.

 [0065] The heat dissipating fins 11 bend flexibly with respect to a direction perpendicular to the flat surface 111 in particular, so that they can be easily deformed according to the shape of various beddings. As shown in FIG. 3, when a person sits down, the body pressure can be well distributed following the movement of the body, and a comfortable feeling of use can be obtained. In addition, since the metal wires 11 x and l ly wound in a left-handed manner and a right-handed manner are intertwined, the shape of the radiating fin 11 is stable and does not lose its shape when used for bedding.

 [0066] Next, the bedding according to Embodiment (2) of the present invention will be described with reference to FIG.

 FIG. 6 is a plan view of the bedding according to the embodiment (2) of the present invention.

 [0067] The bedding 1B is a seat cushion on which a person or the like sits, similarly to the above-described embodiment (1), and is configured by housing the radiating fins 11 in the exterior body 24. And the exterior body 24 uses what crossed the fiber bundle alternately. A stitch 25 is formed between the fiber bundles as the heat release path 12 that promotes heat transfer with the heat radiating body. In addition, a cushioning material is provided inside the exterior body 24.

It should be noted that the configuration and the like of the radiating fin 11 itself are in accordance with the above embodiment (1). Further, the size and number of stitches 25 can be appropriately set by selecting the number and thickness of each fiber bundle. For example, the stitch of the center part of the seat cushion that is the sitting position will be larger than the surrounding Similarly, the number of fiber bundles may be reduced.

 [0069] According to the bedding according to the embodiment (2), in various usage forms such as sleeping or sitting on a person, the radiating fins 11 are exposed from the stitches 25 provided on the seating surface. Direct contact with a body. Subsequently, the heat of the body d is efficiently transferred to the entire radiation fin 11 through the contact portion 113 of the radiation fin 11. Then, the heat conducted to the entire heat radiation fin 11 is released to the outside of the exterior body 24 through the gaps 112 of the heat radiation fin 11 and the stitches 25 functioning as the heat radiation path portion 12.

 [0070] Further, since hot air diffuses through the gaps 112 of the radiating fin 11 and moisture such as sweat evaporates, it does not stuffy. In addition, since the heat radiation fins 11 are cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained.

 [0071] Since the heat radiating fins 11 bend flexibly in a direction perpendicular to the flat surface 111 in particular, they can be easily deformed according to the shape of various cushions. And when a person sits down, it can follow the movement of the body and distribute the body pressure well to obtain a comfortable feeling of use.

 [0072] And, in order to form a mesh-like thing formed by the heat dissipation path portion stitch 25,

As compared with the embodiment (1) in which the outer body 21 is provided with the holes 22, the area of the heat radiation path can be increased with the same strength.

Next, a cushion according to Embodiment (3) will be described with reference to FIG. FIG. 7 is a perspective view of a cushion according to Embodiment (3) of the present invention.

[0074] In the case of this bedding 1C, in the cushion 1B of the embodiment (2), the radiating fins 11 housed in the exterior body 24 are arranged so as to cross each other.

Note that the configuration and the like of the radiating fin 11 itself are the same as those in the above-described embodiment (1). In addition, exterior body 2

The configuration of 4 conforms to the embodiment (2).

[0076] According to the cushion 1C according to the embodiment (3), the same effects as those of the embodiment (2) are obtained. The heat dissipating fins 11 bend flexibly in the direction perpendicular to the flat surface, and by crossing the heat dissipating fins 11 at the center of the cushion 1C, the body pressure is dispersed, coupled with high heat dissipation. A comfortable feeling can be obtained.

Next, the bedding according to Embodiment (4) will be described with reference to FIG. Figure 8 shows the It is a perspective view of the bedding based on Ming's embodiment (4).

The bedding 1D is a pillow on which a person puts his / her head, and includes a heat radiating fin 11 formed of a coiled metal wire and an exterior body 26 that houses the heat radiating fin 11. The heat radiating fins 11 are arranged along the contact surface 26a on which the person's head of the outer body 26 is placed. The contact surface 26a is provided with a hole 27, which acts as a heat dissipation path 12 that promotes heat transfer with the heat sink.

 It should be noted that the configuration and the like of the radiating fin 11 itself are the same as in the above embodiment (1). The exterior body 26 has a substantially planar lower surface 26b and a contact surface 26a having an uneven shape. Further, the size and number of the holes 27 provided in the seating surface 26a can be set as appropriate, but the size is reduced to a predetermined size so that the hair is not entangled with the heat radiation fin 11. It is preferable to do. Moreover, it is preferable to use a mesh-like thing which has innumerable holes.

 [0080] According to the bedding according to the embodiment (4), the radiating fin 11 is exposed from the hole 27 provided in the seating surface 26a in various usage forms such as sleeping or sitting by a person, Direct contact with the body. Subsequently, the heat of the body is efficiently transferred to the entire radiation fin 11 through the contact portion 113 of the radiation fin 11. Then, the heat conducted to the entire radiation fin 11 is released to the outside of the exterior body 26 through the gap portion 112 of the radiation fin 11 and the hole 27 constituting the radiation path portion 12. For this reason, heat does not stay in the exterior body 21, and a comfortable feeling of use can be obtained.

 [0081] Further, since hot air diffuses through the gaps 112 of the radiating fin 11 and moisture such as sweat is vaporized, it does not stuffy. In addition, since the heat radiation fins 11 are cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained.

 [0082] Furthermore, since the heat dissipating fins 11 bend flexibly in a direction perpendicular to a flat surface in particular, they can be easily deformed and used according to the uneven shape of various beddings. And it can follow the movement of the body, disperse the body pressure well, and obtain a comfortable feeling of use.

 [0083] In the above-described embodiments (1) to (4), the cushioning material 23 is accommodated in the exterior body, and the bedding is configured without using the cushioning material. It is also possible.

In the above embodiments (1) to (4), a cushion and a pillow are shown as examples of bedding, but various beddings such as a mattress and a mattress can be similarly implemented. [0085] Next, the embodiment (5) of the present invention will be described with reference to Figs. FIG. 9 is a plan view of the floor slip prevention mat according to the embodiment (5).

 [0086] The bedsore prevention mat needs to maintain a dry state by dispersing body pressure in order to prevent the occurrence of pressure ulcers. An air mat is one of the conventional mats for preventing bedsores. The air is sent to the vinyl with a compressor and continuously inflated. The small air holes in the mat are always exhausted to dry the body. However, such a floor slip prevention mat has a drawback in that it requires air to be sent by a compressor, resulting in a large facility.

 [0087] Examples of other floor slip prevention mats include those using urethane or various gels. However, these bedsore prevention mats are mainly intended to disperse body pressure and have a problem of low air permeability.

 Therefore, in view of the above-described conventional situation, an object of the present invention is to provide a bed slip prevention mat that has high body pressure dispersibility and air permeability and does not require the use of a separate device such as a compressor. .

 The floor slip prevention mat 1E according to the embodiment (5) of the present invention includes a plurality of radiating fins 11 made of a coiled metal wire and an exterior body 28 that houses the radiating fins 11 therein. Prepare. And the radiation fin 11 is arrange | positioned along the contact surface 28a which contacts when the person of the exterior body 28 sleeps. Here, the contact surface 28a is a contact surface on which the heat sink is placed. In addition, a hole 31 is provided in the exterior body 28 to constitute a heat radiation path portion 12 that promotes heat transfer with the heat radiating body.

 Specifically, as shown in FIG. 10, a filler 29 is provided in the exterior body 28, and a core 30 for maintaining the shape of the mat is provided at the center of the filler 29. It has been. Further, a wire 283 for holding the shape of the mat is also provided at the corner portion of the exterior body 28.

[0091] A plurality of the radiating fins 11 are provided along the contact surface 28a close to the body f, and a plurality of flat surfaces 111 are arranged in parallel with the contact surface 28a of the mat. Then, as shown in FIGS. 9 and 10, it is preferably provided on the back portion 281 and the waist portion 282 which are the main contact portions with the body f. At this time, a plurality of radiating fins 11 provided on the back 281 and the waist 282 are crossed. By disposing, body pressure can be evenly distributed not only in one direction but also in the surface direction. The other configuration such as the material of the radiating fin 11 conforms to the above embodiment (1).

 [0092] Further, as the material of the filler 29 and the core material 30, a material having flexibility so as to disperse body pressure can be appropriately employed. For example, the filler 29 can be a low-resilience urethane foam or a core material 30. For example, a foamed polyurethane material having a higher elastic modulus is preferably used.

 Further, the heat radiation path portion 12 is configured by a hole 31 provided in the contact surface 28a of the exterior body 28. The size and number of the holes 31 can be set as appropriate.For example, the holes provided in the back part 281 and the waist part 282 that are the main contact parts with the body f are made larger than the surroundings, The exposure of the radiating fin 11 may be increased by increasing the number.

 [0094] The bedsore prevention mat 1E according to this embodiment (5), when used by pressure ulcer patients, the heat release fins 11 bend freely according to the body, and the body pressure is well dispersed to prevent bedsores. can do. In particular, since the heat dissipating fins 11 are provided so as to cross each other, the body pressure can be uniformly distributed in the surface direction to prevent bed slip.

 [0095] In addition, the radiating fin 11 is exposed from the hole 31 provided in the contact surface 28a, and is in direct contact with the body f which is a heat radiating member. Then, the heat of the body f is transferred to the entire radiation fin 11 through the contact portion 113 of the radiation fin 11. Then, the heat conducted to the entire heat radiating fin 11 is released to the outside of the exterior body 21 through the gap portion 112 of the heat radiating fin 11 and the hole 31 which is the heat radiating path portion 12. In particular, since the radiating fins 11 are provided in cross contact with each other, it is possible to transfer heat in the surface direction through the contact portion between the radiating fins 11 with the heat of the body f. As a result, the patient's heat can be quickly dissipated, and the affected area can be prevented from being stuffy and kept clean.

 [0096] Further, since hot air diffuses through the gaps 112 of the radiating fin 11 and moisture such as sweat is vaporized, it does not stuffy. In addition, since the heat radiation fins 11 are cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained.

Further, the configuration of the floor slip prevention mat 1E is not limited to the examples of FIGS. 9 and 10, and various configurations may be adopted on condition that the radiating fins 11 are housed inside the outer package. it can. For example, when a silicone gel sheet is laminated inside the filler It is done. In FIG. 9, a plurality of heat dissipating fins 11 are arranged on the back part 281 and the waist part 282.For example, along the direction in which the body pressure is distributed to the elbow part, etc., where floor slippage is likely to occur. Therefore, the radiation fins 11 can be arranged.

 Next, an embodiment (6) of the present invention will be described with reference to FIGS. 11 and 12. FIG. 11 is a perspective view of a toilet seat cover 1F according to Embodiment (6).

 [0099] Conventionally, as the toilet seat cover, a toilet seat cover used instead of a heating toilet seat can be used. However, such a toilet seat cover has a problem such as stuffiness when used in summer, so it was often removed in summer.

 [0100] Therefore, an object of the present invention is to provide a toilet seat cover having high heat dissipation and air permeability that does not get steamed even when used in summer in view of the above-described conventional situation.

 This toilet seat cover 1F is configured by housing the radiating fins 11 on which the coil-shaped metal wire rods are also formed in a substantially horseshoe-shaped exterior body 32. The other configuration such as the material of the radiating fin 11 conforms to the above embodiment (1). The toilet seat g is covered with the exterior body 32, and the heat radiating fins 11 are arranged so that the flat surface 111 thereof is parallel to the seat surface 32a of the exterior body 32. The heat radiating fins 11 are bent with respect to the direction parallel to the flat surface 111 and arranged along the shape of the exterior body.

 [0102] The exterior body 32 is formed of a piled fabric obtained from the yarns 321 and 322. The exterior body 32 has innumerable voids 323 in the raised portion, and constitutes the heat radiation path portion 12 that promotes heat transfer with the heat radiating body.

 [0103] In this embodiment, since the radiating fin 11 is easily bent even in a direction parallel to the flat surface, it can be easily followed along the outer body 32 having a substantially horseshoe shape. It becomes. In addition, the heat of the person using the toilet seat g is transmitted to the radiating fin 11 that also serves as the metal wire rod, and is quickly transferred to the entire radiating fin 11 through the connection portion 113 of the heat radiating fin 11. Then, the heat conducted to the entire radiation fin 11 is released to the outside of the exterior body 32 through the gap 112 of the radiation fin 11 and the gap 323 of the exterior body 32.

[0104] Further, since hot air diffuses and moisture such as sweat evaporates through the gap 112 of the radiating fin 11 and the gap 323 of the outer package 32, it does not stuffy. In addition, since the fins are cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained. Next, an embodiment (7) of the present invention will be described with reference to FIG. 13 and FIG. FIG. 13 is a perspective view of the chair cover 1G according to the embodiment (7).

 [0106] As chair covers, those using woven fabrics that have both conventional strength and fiber strength are known, but those that take air permeability into account are often steamed when used for a long time. There was a problem that germs propagated in the field due to moisture.

 [0107] In view of the above-described conventional situation, an object of the present invention is to provide a chair cover having high heat dissipation and air permeability without being steamed even in summer.

 [0108] This chair cover 1G accommodates the heat radiating fins 11 on which the coil-shaped metal wire rods are also formed inside the exterior bodies 33A and 33B that cover the back portion of the chair h and the seat surface portion. It is roughly structured. A plurality of radiating fins 11 are arranged along a contact surface 33a that comes into contact with a heat radiating body such as a human body of the exterior bodies 33A and 33B. Further, the contact surface 33a with the heat radiating member is provided with a hole 34, which constitutes a heat radiating path portion 12 that promotes heat transfer with the heat radiating member. Note that. The configuration of the radiating fin 11 itself conforms to the above embodiment (1).

 [0109] Further, the exterior bodies 33A and 33B are provided with an attachment structure portion 331 for attachment to the seat surface or backrest of the chair h. As the mounting structure portion, various means such as an elastic body such as rubber, a string, and a hook-and-loop fastener can be used.

 [0110] According to the chair cover 1G according to the embodiment (7), as shown in FIGS. 13 and 14, the surface area when the metal wire is flattened is large when a person sits! Since the radiating fin 11 is exposed from the hole 34 provided in the contact surface 33a, the radiating fin 11 is in direct contact with the body, which is the heat radiating body, and the heat of the body is quickly transmitted to the radiating fin 11. Then, the heat of the body can be transmitted to the entire radiation fin 11 through the contact portion 113 of the radiation fin 11. Then, the heat conducted to the entirety of the heat radiating fin 11 is released to the outside of the exterior bodies 33A and 33B through the gaps 112 of the heat radiating fin 11 and the holes 34 constituting the heat radiating path portion 12.

 [0111] Further, heat diffuses through the gaps 112 of the heat radiating fins 11 and the holes 34 constituting the heat radiating path 12, and moisture such as sweat does not evaporate, so that it does not stuffy. In addition, since the radiation fins are cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained.

Furthermore, FIG. 15 and FIG. 16 show an embodiment (8) of the present invention. Figure 15 shows the form of this implementation. It is a perspective view of the cap which concerns on a state (8).

 Conventionally, as a hat with improved air permeability, a hat with improved air permeability using a mesh material or the like is known. However, there is a problem that simply using a mesh material cannot sufficiently release heat.

 [0114] In view of the above-described conventional situation, an object of the present invention is to provide a hat that has high heat dissipation and air permeability and that sufficiently releases heat.

 [0115] The cap 1H includes a crown portion 35 that covers the head portion and a collar portion 36, and is configured by attaching a folded portion 37 along the inner peripheral edge portion 352a of the crown portion 35. A heat radiating fin 11 on which a coil-shaped metal wire rod is also formed is provided along the circumferential direction with respect to the side 37a of the folded portion 37 facing the crown portion 35. The other configuration such as the material of the radiating fin 11 conforms to the above embodiment (1).

 [0116] Further, the folded portion 37 uses a mesh having air permeability, and the gap portion of the mesh constitutes a heat radiation path portion that promotes heat transfer with the heat radiating body. Similarly, a breathable mesh is used for the peripheral portion 352 of the crown portion 35, and a heat dissipation path portion in which the gap portion of the mesh releases heat transferred from the heat dissipation fin 11 to the outside of the cap 1H. Acts as. In addition to the mesh, it is possible to function as a path portion by providing a hole or the like.

 [0117] According to this embodiment, when the cap is attached to the head i, the folded-back portion 37 attached along the inner peripheral edge of the crown portion 35 contacts the forehead portion of the person. The heat of the person's forehead is provided in the folded portion 37 and is transmitted to the heat radiating fins 11 through the mesh voids constituting the heat radiating path. The heat conducted to the radiating fin 11 is quickly transmitted to the entire radiating fin 11 through the contact portion 113. Then, the heat transmitted to the entirety of the radiating fin 11 is released to the outside of the cap 1H through the gap portion 112 of the radiating fin 11 and the gap portion of the crown portion that also has mesh force. For this reason, the forehead part of the human body has a particularly large amount of heat generation, but it is possible to quickly dissipate heat by wearing the cap of the present embodiment.

[0118] In the human body, the forehead portion has a particularly large amount of perspiration, but the hot air diffuses through the voids 112 of the heat dissipating fins 11, so that moisture such as sweat does not vaporize. Ma In addition, since the heat radiation fins 11 are cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained. Further, since the heat dissipating fins 11 can be bent in a direction perpendicular to the flat surface, the heat dissipating fins 11 can follow the deformation of the cap well.

 Furthermore, the embodiment (9) of the present invention will be described with reference to FIG. FIG. 17 is a cross-sectional view of the cap 1J according to this embodiment (9).

 [0120] Hat 1J is the same as that of Embodiment (8), in which radiating fin 11 is provided along the inner peripheral edge 352a of crown 35, and does not have a folded portion. The other configuration such as the material of the radiating fin 11 conforms to the above embodiment (1). Other configurations such as the material of the crown portion 35 are in accordance with the above embodiment (8).

 [0121] According to this embodiment, the same effect as in the above embodiment (8) can be obtained. In addition, since there is no folded portion and the radiating fin 11 directly contacts the forehead portion of the human body, the heat of the forehead portion can be quickly transmitted to the radiating fin 11.

 [0122] Next, embodiment (10) of the present invention is shown in FIGS. FIG. 18 is a perspective view of the helmet 1K according to this embodiment (10).

 Conventionally, as a helmet with improved air permeability, there are known helmets using a material having air permeability as a cushioning member with a hole provided in a protective member covering the outside. However, in any case, sufficient heat dissipation performance was not obtained, and there were problems such as stuffiness during use.

 [0124] In view of the above-described conventional situation, an object of the present invention is to provide a helmet having high heat dissipation and air permeability.

 [0125] The helmet 1K is schematically configured by a protection member 38 that covers the outside, and a buffer member 39 provided inside the protection member 38. A plurality of heat radiation fins 11 are attached in the direction from the top 391 to the peripheral edge 392 of the buffer member 39 so as to be along the inner side surface 39a of the buffer member 39. A covering member 40 is provided further inside the radiating fin 11. In addition, other configurations such as the material of the heat radiating fin 11 conform to the above embodiment (1).

[0126] The protective member 38 is for covering the outermost side when worn on the human body, and is a reinforced plastic. There will be equal power. Further, the buffer member 39 is provided inside the protective member 38 and also serves as a foam member. Further, the covering member 40 uses a mesh having air permeability, and the gap portion of the mesh constitutes a heat radiation path portion that promotes heat transfer with the heat radiating member. In addition to the mesh, it is also possible to configure the heat dissipation path by providing holes or the like.

[0127] When the helmet 1K is attached to the head i, as shown in FIG. 19, a cavity j is formed near the top of the head. According to the present embodiment, the heat retained in the cavity j is conducted to the radiating fin 11 through the gap of the covering member 40. The heat dissipating fins 11 are provided from the top portion 391 toward the peripheral portion 392 so that heat is quickly transferred to the peripheral portion 392 and released to the outside of the helmet 1K.

 In the embodiment (10), the radiating fin 11 is attached along the inner surface of the buffer member 39 from the top 391 toward the peripheral 392. From the center of the top to the periphery The heat dissipating fins 11 may be arranged radially by directing the part 392.

 [0129] Next, an embodiment (11) of the present invention will be described with reference to Figs. FIG. 20 is a perspective view of the hairband according to this embodiment (11).

 [0130] As a hair band, one using a pile fabric having a fiber strength such as cotton or polyester has been known. However, such a hair band has a problem that sufficient heat dissipation performance cannot be obtained!

 [0131] Therefore, in view of the above-described conventional situation, an object of the present invention is to provide a hair band having sufficient heat dissipation and air permeability.

 [0132] Hair band 1L according to embodiment (11) includes heat dissipating fins 11 formed of a coil-shaped metal wire, and an elastic ring-shaped band main body 41 that houses heat dissipating fins 11. A plurality of heat dissipating fins 11 are arranged in the circumferential direction so that the flat surface 111 is along the inner peripheral surface, and a plurality of heat dissipating fins 11 are provided on the band body 40. In order not to be displaced, the radiating fins 11 are stitched together to form a bag body in which the radiating fins 11 are stored. The other configuration, such as the material of the radiating fin 11, conforms to the above embodiment (1).

[0133] Further, in the band body 41, a hole 41a is provided in the inner surface 41a that comes into contact with the head when worn on the head, so that the radiating fin 11 is exposed from the hole 41la. It is composed. Further, the hole 411a constitutes a heat radiation path portion 12 that promotes heat transfer with the heat radiating body. Furthermore, the outer side surface 41b to be externally provided is similarly provided with a 41 lb hole, which acts as a path for releasing heat to the outside of the hair band 1L. The ring-shaped band main body 41 can be made of a breathable mesh or the like.

[0134] According to the present embodiment, when the hair band 1L is attached to the head, the heat radiating fins 11 are exposed from the holes 41 la provided in the inner side surface 41a, and the head that is a heat radiating body. Contact directly. Subsequently, the heat of the head is efficiently transferred to the entire radiation fin 11 through the contact portion 113 of the radiation fin 11. The heat conducted to the entirety of the heat radiating fin 11 is released to the outside of the hairband main body 41 through the gap 112 of the heat radiating fin 11 and the hole 4 ib provided on the outer surface 4 lb.

 [0135] Further, hot air diffuses through the gaps 112 of the radiating fins 11, and moisture such as sweat does not vaporize because it evaporates. In addition, since the heat radiation fins 11 are cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained.

 [0136] Furthermore, since a plurality of heat dissipating fins 11 are provided along the circumferential direction of the elastic hair band body, it can be easily expanded and contracted when worn on the head. In addition, the heat dissipating fins 11 are flexibly bent especially in the direction perpendicular to the flat surface 111 and easily deformed according to usage conditions such as mounting and dismounting, so that a comfortable feeling of use can be obtained. The

 Furthermore, the embodiment (12) of the present invention will be described with reference to FIG. 23 and FIG. FIG. 23 is a perspective view of a shoe according to this embodiment (12).

 [0138] As shoes, those using a breathable mesh material or the like as an upper member are known. However, it is not enough just to increase the breathability of the shoes, especially when used for a long time, there is a problem that the inside of the shoes gets muddy.

 [0139] In view of the above-described conventional situation, an object of the present invention is to provide a shoe having high heat dissipation and high heat dissipation performance even when the shoe is used for a long time.

[0140] The shoe 1M mainly includes a sole 42 and an upper member 43 that is fixed on the sole 42 and covers the surface of the foot. A heat radiating fin 11 formed of a coiled metal wire is attached in parallel to the contact surface that contacts the foot of the upper part 431. In addition The other configuration such as the material of the heat dissipating fin 11 conforms to the above embodiment (1).

 [0141] Further, the upper portion 431 uses a mesh having air permeability, and the gap portion of the mesh acts as a heat radiation path portion for releasing heat to the outside of the shoe 1M. In addition to the mesh, it is also possible to configure the heat dissipation path by providing holes or the like.

 [0142] Further, as described above, the heat dissipating fins 11 provided on the upper part 431 should be fixed so that the metal wire rods are not separated from each other by means of welding or the like, with the contact portions 113 in which the winding units are in contact with each other. Is preferred. In this way, even when severe deformation is applied to the upper part 431 due to the movement of the foot, the radiating fin 11 can follow flexibly without stretching.

 [0143] According to the present embodiment, the radiating fin 11 is provided on the contact surface in contact with the foot of the upper part 431, so that the heat of the foot, which is the radiating member, is efficiently transferred to the radiating fin 11. Can conduct. Then, heat can be transferred to the entire radiation fin 11 via the contact portion 113 of the radiation fin 11. The heat conducted to the entirety of the radiating fin 11 is released to the outside of the shoe through the gap 112 of the radiating fin 11 and the gap of the mesh.

 [0144] Further, since hot air diffuses through the gap 112 of the radiating fin 11 and moisture such as sweat is vaporized, it does not stuffy. In addition, since the heat radiation fins 11 are cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained.

 [0145] Furthermore, a shoe according to Embodiment (13) of the present invention will be described with reference to Figs. FIG. 25 is a perspective view of a shoe according to this embodiment (13).

 [0146] In the shoe 1N, in the shoe of the above embodiment (12), the radiating fins 11 that can also obtain a coiled metal wire force are attached along the inner surface of the toe portion 432 of the upper member 43. Specifically, the toe portion 432 is provided at a portion where the reinforcing portion 434 does not exist. The other configuration such as the material of the radiating fin 11 conforms to the above embodiment (1).

[0147] The toe portion 432 of the upper member 43 uses a mesh having air permeability, and the gap portion of the mesh acts as a heat radiation path portion that releases heat to the outside of the shoe _1N . In addition to the mesh, it is possible to function with the heat dissipation path by providing holes.

[0148] As described above, the heat dissipating fins 11 provided on the toe portion 432 have the winding units in contact with each other. It is preferable to fix the contact portions so that the metal wires are not separated by means such as welding. In this way, even when a severe deformation is applied to the upper member 43 due to the movement of the foot, the radiating fin 11 can follow flexibly without stretching.

 [0149] According to the shoe of the embodiment (13), the heat dissipating fins 11 are provided on the contact surface of the toe portion 432 that comes into contact with the toes of the foot. Heat can be conducted to the fin 11. Then, heat can be transferred to the entire heat radiation fin 11 through the contact portion 113 of the heat radiation fin 11. The heat conducted to the entirety of the radiating fin 11 is released to the outside of the shoe through the gap 112 of the radiating fin 11 and the gap of the mesh. For this reason, the toe portion 432 is particularly likely to retain heat, but can quickly be released to the outside of the shoe 1N without retaining heat.

 [0150] In addition, the toes of the toes are well secreted, such as sweat. Hot air diffuses through the gaps 112 of the heat dissipating fins 11, and moisture such as sweat does not evaporate. In addition, since the heat radiation fins 11 are cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained.

 [0151] Furthermore, a shoe according to Embodiment (14) of the present invention will be described with reference to Figs. FIG. 27 is a perspective view of a shoe according to this embodiment (14).

 [0152] In the shoe 1P, in the shoe of the above embodiment (12), the radiating fins 11 formed from a coiled metal wire are attached to the upper member 433. Specifically, the radiating fins 11 are provided along the inner surface of the cushioning material 436 provided on the inner surface of the flange 433. The inner side surface of the cushioning material 436 is a contact surface that comes into contact with the buttocks of the foot. The other configuration such as the material of the heat dissipating fin 11 conforms to the above embodiment (1).

 [0153] The collar 433 of the upper member 43 is generally made of leather, synthetic resin or the like. The flange 433 is provided with a hole 437 to maintain air permeability, and acts as a heat dissipation path. Further, the cushioning material 436 uses a mesh having air permeability, and the void portion of the mesh acts as a heat radiation path portion that releases heat to the outside of the shoe 1P. In addition to the mesh, it is possible to make the heat dissipation path portion function by providing holes or the like in a woven fabric made of synthetic fiber or natural fiber.

[0154] As described above, the heat dissipating fins 11 provided in the flange part 433 preferably fix the contact parts where the winding units are in contact with each other so that the metal wires are not separated by means such as welding. Yes. In this way, even when severe deformation is applied to the buttocks 433 due to the movement of the foot, the radiating fin 11 can follow flexibly without stretching.

 [0155] According to the shoe 1P according to the embodiment (14), the radiating fins 11 are provided on the contact surface that comes into contact with the heel portion of the heel portion 433. Heat can be efficiently conducted to the radiation fin 11. Then, heat can be transferred to the entire radiation fin 11 via the contact portion 113 of the radiation fin 11. The heat conducted to the entirety of the radiating fin 11 is released to the outside of the shoe through the gap 112 of the radiating fin 11 and the gap of the mesh. For this reason, the heel part 433 is particularly likely to retain heat, but can quickly be released to the outside of the shoe 1P without retaining heat.

 [0156] Further, hot air diffuses through the gaps 112 of the radiating fin 11, and moisture such as sweat is vaporized, so that it does not stuffy. In addition, since the heat radiation fins 11 are cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained.

 [0157] Further, an insole 1Q according to the embodiment (15) of the present invention will be described with reference to Figs. FIG. 29 is a plan view of an insole according to this embodiment (15).

 [0158] The insole 1Q is generally configured by a radiating fin 11 formed by a coiled metal wire rod and an insole body 45 provided with the radiating fin 11. A covering member 46 is provided so as to cover the radiating fins 11, and is fixed by sewing at end portions 451 and 4 61 of the insole body 45 and the covering member 46. The other configuration such as the material of the radiating fin 11 conforms to the above embodiment (1).

 [0159] Further, the covering member 46 uses a mesh having air permeability, and the gap portion of the mesh constitutes a heat radiation path portion that promotes heat transfer with the sole, which is a heat radiating body. And the radiation fin 11 is exposed from the space | gap part of a mesh. In addition to the mesh, it is possible to function as a heat dissipation path by providing a hole or the like in a woven fabric made of synthetic fiber or natural fiber.

[0160] In the radiating fin 11 provided in the insole body 45, as described above, it is preferable to fix the contact portions where the winding units are in contact with each other so that the metal wires are not separated by means such as welding. In this way, even if the insole 1Q undergoes severe deformation due to the movement of the foot, the radiating fin 11 can follow flexibly without stretching. [0161] The insole 1Q according to the embodiment (15) is used in shoes. According to this embodiment, when the foot is worn, the radiating fins 11 are exposed from the voids of the mesh of the covering member 46, and are in direct contact with the sole, which is the heat radiating member. Heat is transferred to the radiation fin 11. In that case, it contacts in a buttocks part and a toe part also in a sole. Subsequently, the heat of the soles is transferred to the entire radiating fin 11 through the contact portion 113 of the radiating fin 11. Then, the heat conducted to the entire radiation fin 11 is released to the outside of the insole 1Q through the gap 112 of the radiation fin 11 and the heat radiation path provided in the covering member 46. At this time, the part of the sole of the sole does not come into contact with the insole 1Q, so heat can be easily released. Insole The heat released as 1Q force is released to the outside of the shoe through the gap between the foot and the shoe and the space provided in the shoe. For this reason, it is possible to quickly release the insole to the outside of 1Q without causing heat to stay.

 [0162] Further, hot air diffuses through the gap 112 of the radiating fin 11, and moisture such as sweat is vaporized, so that it does not stuffy. And since the radiation fin 11 is cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained. Furthermore, since the radiating fins 11 obtained using the coiled metal wire have an uneven shape, a massage effect can be obtained.

 Next, a cast according to Embodiment (16) of the present invention will be described with reference to FIGS. 31 and 32. FIG. 31 is a perspective view of a cast according to this embodiment (16).

 [0164] The cast was often used for a long time, and the stuffiness at the site of the cast was often a problem. Examples of casts for preventing stuffiness include those using rayon fibers having high water absorption. In addition, there are other materials that use a breathable mesh material, but none of them has a sufficient anti-steaming effect.

 [0165] In view of the above-described conventional situation, an object of the present invention is to provide a cast that has high heat dissipation and air permeability and has a sufficient anti-steaming effect.

[0166] The cast 1R is schematically configured by disposing heat radiating fins 11 formed from a coiled metal wire rod inside a protective member 47 for covering and fixing the affected area. When the radiating fins 11 are provided, the flat surface 111 of the radiating fins 11 is arranged along the inner side surface 47b of the cast 1R. In addition, about other structures, such as a material of the radiation fin 11, it applies to said Embodiment (1). [0167] As the protective member 47, general plaster, hydraulic polyester material, or the like can be used. In addition, when providing the radiating fin 11, for example, the radiating fin 11 is previously embedded in a cloth having good air permeability, and the cloth 1 is applied to the affected area, and then the material of the cast 1R is molded and cured. Can do. The protective member 47 is provided with hook-and-loop fasteners 472 and 471 at the ends of the outer surface 47 and the inner surface 47b so that the cast 1R can be attached and detached.

 [0168] According to this embodiment, the heat is diffused by the heat dissipating fins 11 made of a heat-powered coil-shaped metal wire confined inside the cast 1R and quickly radiated. In addition, while the cast 1R is securely fixed to the affected area via the radiation fin 11, air flows through the gap, so that the inside of the cast 1R can be kept cool and clean.

 The other configuration such as the material of the radiating fin 11 conforms to the above embodiment (1).

 [0169] Next, FIG. 33 shows a heat-cooled sheet according to Embodiment (17) of the present invention. FIG. 33 is a plan view of the heat-cooled sheet according to this embodiment (17).

[0170] As a heat-cooled sheet, a sheet using a gel is conventionally known. The heat-cooled sheet using this gel is configured such that the gel absorbs and releases heat. However, since gel does not have sufficient heat dissipation performance, it has to be replaced after it has been used for a certain period of time.

[0171] In view of the above-described conventional situation, an object of the present invention is to provide a heat-cooled sheet that has high heat dissipation and air permeability and can maintain the effect for a long time.

[0172] The heat-cooled sheet 1S is schematically configured by including a plurality of heat radiation fins 11 formed of a coiled metal wire force and an attachment structure member 48 for fixing the heat radiation fins 11 to the heat radiating member. Has been. In addition, about other structures, such as a material of the radiation fin 11, it applies to said Embodiment (1).

[0173] The mounting structure member 48 is composed of a fixing member 481 and a connection member 482 of the radiating fins 11. As the fixing member 481, a hook-and-loop fastener 483, a hook or the like can be used. Further, as the connecting member 482, an elastic member such as rubber is preferably used.

[0174] In the heat-cooled sheet 1S of this embodiment, the radiating fins 11 are in direct contact with the forehead of the human body. And is fixed by the mounting structure member 48. According to this embodiment, the heat generated by the person's forehead is transmitted to the radiation fins 11 that are in direct contact. The heat transmitted to the heat radiating fin 11 is transmitted to the entire heat radiating fin through the contact portion 113 of the heat radiating fin. Since the gap 112 of the radiating fin 11 has air permeability, heat is released into the air through the gap 112.

 [0175] Further, hot air diffuses through the gap 112 of the radiating fin 11, and moisture such as sweat is vaporized, so that it does not stuffy. In addition, since the heat radiation fins 11 are cooled by the heat of vaporization of moisture, a comfortable feeling of use can be obtained.

 Next, the thawing sheet 1T according to Embodiment (18) of the present invention will be described with reference to FIG. FIG. 34 is a perspective view of the thawing sheet 1T according to this embodiment (18).

 [0177] As a thawing sheet, a sheet using a carbonaceous ceramic having high thermal conductivity is conventionally known. This thawing sheet using carbonaceous ceramic is thawing by heat exchange at the contact surface with the object to be thawed. However, when such a sheet is used, there is a problem that the surface area is not sufficient, so that thawing cannot be performed quickly. In addition, there is a problem that the material is expensive. Further, as other thawing sheets, those made of flat aluminum plates are conventionally known. However, since it is a flat plate, it has a problem that its surface area is small and it is insufficient to obtain heat for thawing.

 [0178] In view of the above-described conventional situation, an object of the present invention is to provide a thawing sheet having a high surface area and capable of thawing an object to be thawed quickly.

 [0179] The thawing sheet 1T has a schematic configuration in which a plurality of heat dissipating fins 11 formed by a coiled metal wire rod are connected and arranged. Specifically, a plurality of heat radiation fins 11 arranged in parallel are connected by a metal wire 49. The thawing sheet 1T has a large area with respect to the thawing target object m. Other configurations such as the material of the heat radiating fin 11 conform to the above embodiment (1).

[0180] In the present embodiment, the object to be thawed m is placed and used on the top surface of the thawing sheet 1T. According to this embodiment, not only the heat of the outside air is directly transmitted to the object to be thawed m but also the bottom force of the object to be thawed m can transmit heat through the heat radiation fin 11. Specifically, since the radiating fin 11 has a large surface area, a large amount of heat from the outside air is generated on the surface of the radiating fin 11. It will be transmitted to the surface. The heat transmitted to the surface of the radiating fin 11 is transmitted to the central portion of the radiating fin 11 on which the object to be thawed m is placed due to the temperature gradient. At this time, since the heat dissipating fins 11 have the contact portions 113, heat is quickly transmitted. The heat accumulated in the center of the radiating fin 11 is given to the object to be thawed m and is quickly thawed.

 [0181] Further, as the thawing progresses, the drip leaks from the object to be thawed. However, since the radiating fin 11 has the gap 112, the drip can be discharged to the lower surface of the thawing sheet 1T. For this reason, it is possible to defrost without leaving a drip on the thawing sheet 1T.

 [0182] In the above embodiment (18), the plurality of heat dissipating fins 11 are connected using a metal wire, but soldering, soldering, adhesive, adhesive, vibration welding, flashing, etc. Each radiating fin 11 can be fixed so as not to be separated by means such as welding.

 Next, a personal computer heat dissipation sheet 1U according to the embodiment (19) of the present invention will be described with reference to FIGS. 35 and 36. FIG. FIG. 35 is a perspective view of the personal computer heat-dissipating sheet 1 U according to this embodiment (19).

 [0184] As a heat-dissipating sheet for a personal computer, a sheet in which a gel is encapsulated in the exterior is known. The heat dissipation sheet for personal computers using this gel is configured so that the gel absorbs and releases heat. However, since gel does not have sufficient heat dissipation performance, it has to be replaced after it has been used for a certain period of time.

 [0185] In view of the above-described conventional situation, the present invention has an object to provide a heat dissipation sheet for a personal computer having high heat dissipation and air permeability and capable of maintaining heat dissipation over a long period of time. And

[0186] The heat radiating sheet 1U for personal computers is roughly configured by housing the heat radiating fins 11 formed of a coil-shaped metal wire force in a substantially rectangular outer casing 50. The flat surface of the heat radiating fin 11 is arranged so as to be parallel to the contact surface 50a of the exterior body 50 with the personal computer. Specifically, the exterior body 50 is sewn at an intermediate position so that it can be folded in half with respect to the longitudinal direction, and is divided into two bag bodies 50A and 50B. The heat dissipating fins 11 are arranged in the bags 50A and 50B, and are sewn and fixed to the exterior body 50. At this time, the direction in which the radiation fins 11 are arranged is provided along the longitudinal direction of the exterior body. In addition, the exterior body 50 is provided with a hole 501 between the PC body n which is a heat sink. The heat dissipating path section 12 that promotes heat transfer is constructed.

 [0187] The personal computer heat radiation sheet 1U of the above-described embodiment uses the personal computer body placed on the contact surface 50a. According to this embodiment, the radiating fin 11 is exposed from the hole 501 provided in the contact surface 50a of the exterior body 50, and the PC main body n force, which is the radiating body, is also directly transferred to the heat. Subsequently, the heat of the personal computer main body n is efficiently transferred to the entire radiation fin 11 through the contact portion 113 of the radiation fin 11. Then, the heat conducted to the entire radiation fin 11 is released to the outside of the exterior body 50 through the gap 112 of the radiation fin 11 and the hole 501 acting as the radiation path portion 12. For this reason, the heat generated from the personal computer main body n is quickly dissipated from the lower surface, and it is possible to prevent an excessive temperature rise of the personal computer main body n.

 [0188] In the above embodiment (19), the radiating fin 11 is sewn and fixed to the exterior body 50. However, the exterior body 50 is sewn at regular intervals to form a bag body. One radiating fin 11 can be arranged in each bag.

 [0189] Next, a personal computer heat dissipation sheet IV according to Embodiment (20) of the present invention will be described with reference to FIG. FIG. 37 is a perspective view of a personal computer heat dissipation sheet IV according to this embodiment (20).

 [0190] The heat dissipating sheet IV for a personal computer has a schematic structure in which a plurality of heat dissipating fins 11 formed from a coiled metal wire rod are connected and arranged. Specifically, a plurality of radiating fins 11 arranged in parallel are connected by a metal wire 51. As the personal computer heat dissipation sheet 1 V, a sheet having a large area with respect to the computer main body n is used. Further, the heat radiating fins 11 are arranged so that the PC body n is placed and protrudes in the direction of the partial force length. In addition, about the other structures, such as a material of the radiation fin 11, it applies to said Embodiment (1).

[0191] The personal computer heat radiation sheet IV of this embodiment is used with the personal computer main body n placed on the upper surface thereof. According to this embodiment, the heat generated from the PC main body is transmitted to the heat release fin 11 that is in direct contact. The heat transferred to the heat radiating fin 11 is transferred to the entire heat radiating fin through the contact portion 11 3 of the heat radiating fin. Since the gap 112 of the radiating fin 11 has air permeability, heat is released into the air through the gap 112. At this time, the heat release sheet for PC IV force Nosocon main body has a larger surface area than n, so it can be easily put into the air. Heat can be released. In particular, since the radiating fins 11 are in direct contact with the personal computer main body n, it is possible to obtain the same degree of radiating performance in a small area as compared with the heat radiating sheet for a notebook computer of the above embodiment (19).

 [0192] In the above embodiment (20), the plurality of heat dissipating fins 11 are connected using a metal wire, but soldering, soldering, adhesive, adhesive, vibration welding, flashing, etc. Each radiating fin 11 can be fixed so as not to be separated by means such as welding.

 Next, a wine cooler 1W according to Embodiment (21) of the present invention will be described with reference to FIG. FIG. 38 is a cross-sectional view of the wine cooler 1W according to this embodiment (21).

 [0194] Conventionally, as a wine cooler, a cylindrical one using stainless steel or aluminum is known. A wine bottle is stored in an inner tube, and the outside is cooled by ice to cool the wine bottle. However, the inner surface of the cylinder of the wine cooler was flat and did not carry enough cold energy to cool the wine bottle.

 [0195] In view of the above-described conventional situation, an object of the present invention is to provide a wine cooler having a high cooling effect.

 [0196] In the wine cooler 1W, the radiating fins 11 formed of a coiled metal wire are arranged on the inner surface 521 of the substantially cylindrical metal member 52 for inserting the wine bottle P. It is roughly structured. Note that the flat surface of the radiating fin 11 is disposed so as to be parallel to the inner surface 521 of the metal member 52. The heat radiation fin 11 can be fixed to the inner surface by means of soldering, soldering, adhesive, adhesive, vibration welding, flash welding, or the like. Other configurations such as the material of the fin 11 conform to the above embodiment (1).

 [0197] Specifically, the metal member 52 has a reverse taper shape by being directed toward the bottom surface 522. Further, the bottom surface 522 of the metal member 52 is provided with a convex portion 523 that fits into the concave portion of the bottom portion of the wine bottle p.

[0198] According to this embodiment, when the wine cooler 1W is immersed in ice water or the like, cold heat is transferred to the metal member 52, and a coil with a large surface area provided along the inner surface 521 of the metal member 52 is provided. Conducted to the heat dissipating fin 11 which is also a metal wire rod. And since the radiating fin 11 has a large surface area, the heat is quickly diffused and inserted into the inner surface 521 of the wine cooler 1W. The entered wine bottle P is quickly cooled.

 [0199] In addition, the radiating fins 11 provided on the inner surface 521 of the metal member 52 are formed by flattening a coiled metal wire, and serve as a spring when the wine bottle 1W is inserted. It functions and the wine bottle p is securely fixed to the inner surface of the wine cooler 1W. For this reason, even when the wine cooler 1W falls down, the wine bottle p does not pop out of the wine cooler 1W.

 [0200] The jacket according to the embodiment (22) of the present invention will be described with reference to Figs. FIG. 39 is a view of the jacket according to this embodiment (22).

 [0201] As a conventional jacket or garment with improved heat dissipation, a substantially parallel flat cooling flow passage formed in the vicinity of the portion of the elastic member in contact with the body, and air is introduced into the cooling flow passage. An inlet for discharging air from the cooling flow passage, an electric fan provided on the inlet side or the outlet side, and a connection flow passage provided between the electric fan and the cooling flow passage. It has an electric fan to increase the temperature gradient with the body by circulating ambient air having a temperature lower than the body temperature in the cooling flow passage substantially parallel to the body surface, and dissipates the heat generated from the body. Cooling clothing that cools the body is known. However, the products as described above have a problem that a large amount of power such as a conduction fan is required as well as sufficient performance to obtain a certain degree of heat dissipation by circulating air. Therefore, it was desired to develop a jacket with heat dissipation without using a complicated device.

 Accordingly, an object of the present invention is to provide a jacket that can exhibit high heat dissipation and air permeability and that does not require the use of a device such as a conductive fan.

 [0203] The jacket IX is schematically configured by radiating fins 11 formed of a coil-shaped metal wire force embedded between the outer surface 53 and the lining 54 of the jacket. The lining 54 is provided with a hole 56, which constitutes the heat dissipation path 12 that promotes heat transfer with the heat sink. In addition, a hole 55 is provided in the outer surface 53, and it acts as a heat release path part for releasing heat to the outside of the jacket IX. It is also possible to use a breathable mesh or the like for the outer material 53 and the lining material 54.

[0204] Other configurations such as the material of the radiating fin 11 are the same as those in the embodiment (1). Sway. In addition, it is preferable to place the radiating fins 11 along the direction where the movement of the body is not restricted, especially on the back side where heat can be trapped.

[0205] In addition, the size and number of holes 55 and 56 provided in the outer surface 53 and the lining 54 of the jacket IX can be appropriately set. For example, the holes 56 provided in the back side portion etc. where heat is easily accumulated It is also possible to increase the degree of exposure of the radiating fins 11 by making it larger than the surrounding area, or by providing a larger number. In the present embodiment, the holes 55 and 56 are provided as the heat dissipation path, but the heat dissipation path 12 can also be configured by using a mesh-like fabric having high air permeability.

 [0206] According to the jacket IX according to the embodiment (22), when the jacket IX is mounted on the upper body of the body, the radiating fins 11 are exposed from the holes 56 provided in the lining 54, and the heat radiated The body is in direct contact with the body, and heat is transferred to the radiation fins 11. Further, the heat inside the jacket is also transferred to the radiation fin 11 exposed from the hole 56. Then, the heat is efficiently transferred to the entire heat dissipating fin 11 through the contact portion 113 of the heat dissipating fin 11. Further, the heat conducted to the entirety of the radiating fin 11 is released to the outside of the jacket IX through the gap 112 of the radiating fin 11 and the hole 55 provided in the outer surface 53. For this reason, a comfortable feeling of use can be obtained without causing the body heat to stay inside the jacket.

 [0207] Further, since hot air diffuses through the gaps 112 of the radiating fin 11 and moisture such as sweat is vaporized, it does not stuffy. In addition, since the fins are cooled by the heat of vaporization of moisture, a comfortable feeling can be obtained.

 [0208] Further, the jacket of the present invention is suitably used as work clothes used in factories and the like. Many work clothes are relatively thick, and the physical strength of the work sheds a lot of heat and sweat, but using the jacket IX of this embodiment can provide a comfortable feeling during work. .

[0209] In the above embodiments (1) to (22), the metal wire wound in the shape of a circular coil is used. However, the present invention is not limited to this. That is, a coiled metal wire wound in various shapes such as a polygon such as a triangle and a rectangle, an ellipse, and a star other than a circle can be used. When a coiled metal wire wound in a square shape is used, adjacent winding units overlap each other, increasing the contact area and increasing thermal conductivity. Rise. In addition, when a coiled metal wire wound in a complicated shape such as a star shape is used, the heat dissipation performance is improved because the surface area is increased.

 In the above embodiments (1) to (22), a metal wire having a circular cross section is used, but a metal wire having a deformed surface may be used. The deformed surface includes (a) polygonal shape, (b) star shape, (c) wire shape by twisting multiple metal wires, (d) rectangular shape (tape shape) As described above, various shapes can be adopted. In particular, the star shape, the wire shape and the like have a particularly complicated shape force, and the surface area is increased, so that the heat release performance is improved. Further, it is possible to form a flaw in the deformed surface by forming a flaw in the wire material such as a wire flaw.

Claims

The scope of the claims

 [1] Metal wire material s Coiled to form a winding unit, and the whole is continuously formed flat. Adjacent winding units are displaced from each other to have a gap and a contact portion. A heat dissipating fin and an exterior body having a contact surface on which the heat dissipating member is placed and housing the heat dissipating fin, wherein the heat dissipating fin is disposed along the contact surface and at least between the heat dissipating member; A bedding having a heat dissipation path that facilitates heat transfer.

 [2] Metal wire rod S is wound into a coil shape to form a winding unit and the whole is continuously formed flat, and adjacent winding units are displaced from each other to have a gap portion and a contact portion. A heat dissipating fin and an exterior body having a contact surface on which a heat radiating member is placed and housing the heat radiating fin on a filler, wherein the heat radiating fin is disposed along the contact surface, and at least the heat radiating A floor slip prevention mat having a heat dissipation path that promotes heat transfer with the body.

 [3] Metal wire rod S is wound into a coil shape to form a winding unit and the whole is continuously formed flat, and adjacent winding units are displaced from each other to have a gap and a contact portion. A heat dissipating fin and a protective member for covering and fixing the affected part, wherein the heat dissipating fin is disposed along the inner surface of the protective member, and at least promotes heat transfer with the affected part. A cast made up of.

 [4] Metal wire rod S is wound into an S-coil to form a winding unit and the whole is continuously formed flat, and adjacent winding units are displaced from each other to have a gap and a contact portion. A heat-cooled sheet comprising at least one radiating fin and an attachment structure member for fixing the radiating fin to a heat radiating member.

 [5] Metal wire rod S is wound into a coil shape to form a winding unit and the whole is continuously formed flat, and adjacent winding units are displaced from each other to have a gap and a contact portion. A heat dissipation fin and an exterior body having a larger area than that of the personal computer when the heat dissipation fin is accommodated and a personal computer is placed, and at least a heat dissipation path portion that promotes heat transfer with the personal computer. A heat dissipation sheet for personal computers.

[6] Metal wire rod S is wound into a coil shape to form a winding unit and the whole is continuously formed flat, and adjacent winding units are displaced from each other to have a gap and a contact portion. A plurality of radiating fins are connected and formed in a planar shape to place a personal computer. A heat-dissipating sheet for personal computers with a larger area.

[7] Metal wire rod S is wound into a coil shape to form a winding unit, and the whole is continuously formed flat, and adjacent winding units are displaced from each other to have a gap portion and a contact portion. A jacket in which a radiating fin is provided between an outer surface and a lining, wherein the lining is in contact with a heat radiating body and has a heat radiating path portion that promotes heat transfer between at least the radiating body.

 [8] Metal wire rod S is wound into a coil shape to form a winding unit, and the whole is continuously formed into a flat band, and adjacent winding units are displaced from each other so that a gap and a contact portion are formed. A hat having a radiating fin having a head, a crown portion covering the head portion, and a folded portion attached along the inner periphery of the crown portion, on the side of the folded portion facing the crown portion A hat having a heat radiation path portion that is disposed along the heat radiation fins and promotes heat transfer with at least the head.

 [9] Metal wire rod S is wound into a coil shape to form a winding unit and continuously formed into a flat strip as a whole, and adjacent winding units are displaced from each other so that a gap portion and a contact portion are formed. And a crown part that houses the radiation fin and covers the head part, wherein the radiation fin is disposed along the inner peripheral edge of the crown part, and at least the head part is provided. A hat having a heat dissipation path that promotes heat transfer between the cap and the cap.

 [10] A helmet composed of a protective member covering the outside and a buffer member provided inside the protective member, wherein the metal wire is wound in a coil shape to form a winding unit, A helmet in which the whole is continuously formed flat, and adjacent winding units are displaced from each other so that heat-radiating fins having gap portions and contact portions are provided on the inner surface of the cushioning member toward the head portion force peripheral portion. .

[11] Metal wire rod S is wound into a coil shape to form a winding unit and continuously formed into a flat strip as a whole, and adjacent winding units are displaced from each other so that a gap portion and a contact portion are formed. And a ring-shaped band body which is provided with the heat radiation fin and comes into contact with the head, and a plurality of the heat radiation fins are provided in a circumferential direction so as to be along the inner peripheral surface of the band main body. A hair band that is disposed and has a heat dissipation path that promotes heat transfer with at least the head.

[12] A radiating fin which is wound into a metal wire cacoil shape to form a winding unit and is continuously formed in a flat shape, and adjacent winding units are displaced from each other to have a gap and a contact portion. And an insole body in which flat surfaces of the radiating fins are provided in parallel.

 [13] A radiating fin in which a winding unit is formed by being wound into a metal wire rod coil shape, and the entire winding unit is continuously formed flat, and adjacent winding units are displaced from each other to have a gap portion and a contact portion. A thawing sheet having a larger area than the thawing object, the thawing object being formed in a planar shape so that the thawing object is placed.

 [14] Metal wire rod S is wound into a coil shape to form a winding unit and the whole is continuously formed flat, and adjacent winding units are displaced from each other to have a gap portion and a contact portion. A wine cooler in which heat dissipating fins are arranged along an inner surface of a substantially cylindrical metal member for inserting a wine bottle, and are configured to promote heat transfer with at least the wine bottle.

 [15] A radiating fin that is wound into a metal wire coiled coil shape to form a winding unit and is continuously formed in a flat shape, and adjacent winding units are displaced from each other to have a gap portion and a contact portion. And a substantially horseshoe-shaped exterior body that houses the radiation fin and covers the toilet seat, and the flat surface of the radiation fin is parallel to the seat surface on which the heat radiating body of the exterior body is placed. A toilet seat cover that has a heat radiation path portion that is arranged so as to promote heat transfer with at least the heat radiating body.

 [16] Metal wire rod S is wound into a coil shape to form a winding unit and the whole is continuously formed flat, and adjacent winding units are displaced from each other to have a gap portion and a contact portion. A heat dissipating fin, and an external body that houses the heat dissipating fin and covers a backrest portion or a seating surface of the chair, wherein the exterior body includes an attachment structure for attaching to the chair, and the heat dissipating fin is the exterior body. The chair cover which is arrange | positioned along the contact surface which contact | connects the to-be-heat-dissipated body, and has a thermal radiation path part which accelerates | stimulates heat transfer between the said to-be-radiated body.

[17] A shoe comprising a knur and an upper member fixed on the knot and covering the surface of the foot, and the upper part of the upper member is wound in the form of a metal wire S coil. The turn unit is formed and the whole is continuously formed flat, and adjacent winding units are mutually connected. A shoe in which a heat dissipating fin having a gap portion and a contact portion is provided.

 [18] A shoe comprising a knur and an upper member fixed on the knot and covering the surface of the foot, wherein the upper member has a toe portion wound with a metal wire S coil. A shoe in which a unit is formed and the whole is continuously formed flat, and adjacent winding units are displaced from each other and provided with heat radiation fins having a gap portion and a contact portion.

 [19] A swivel comprising a knur and an upper member fixed on the knot and covering the surface of the foot, wherein a metal wire is wound in a coil shape on the buttocks of the upper member. Is formed, and the whole is continuously formed flat, and adjacent winding units are displaced from each other so that a radiating fin having a gap portion and a contact portion is provided.