JP2007282881A - Conductive insole, and antistatic shoe - Google Patents

Conductive insole, and antistatic shoe Download PDF

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JP2007282881A
JP2007282881A JP2006114117A JP2006114117A JP2007282881A JP 2007282881 A JP2007282881 A JP 2007282881A JP 2006114117 A JP2006114117 A JP 2006114117A JP 2006114117 A JP2006114117 A JP 2006114117A JP 2007282881 A JP2007282881 A JP 2007282881A
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conductive
surface side
insole
shoe
layer
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JP4982104B2 (en
JP2007282881A5 (en
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Mikio Tenkai
幹雄 天海
Hitomi Mogi
ひと美 茂木
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Achilles Corp
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Achilles Corp
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Abstract

<P>PROBLEM TO BE SOLVED: To provide a conductive insole which has no feeling of a foreign object, and is useful as the insole for an antistatic shoe having a good cushioning property and useful when being used combined with a shoe-sole having a comparatively high electric resistance, and to provide an antistatic shoe. <P>SOLUTION: This conductive insole 1 is disposed with an upper surface side conductive layer 3 on the upper surface side of an elastic layer 2, and a lower surface side conductive layer 4 on the lower surface side. The elastic layer has insulation and electrically conducts both conductive layers by a conductive thread 6 for an edge stitch 5 which is applied on a peripheral edge of the insole. The antistatic shoe 11 are constituted in such a manner that a conductive shoe-sole 10 which is molded by injection is directly bonded to the lower surface side conductive layer of the conductive insole in which an upper leather lower edge section is sewn to the peripheral edge. Alternatively, the antistatic shoes 11 has the lower surface side conductive layer being adhesive, which directly adheres to the conductive shoe-sole 10. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

本発明は、クッション性が良好で、甲皮下縁部に縫合されるとともに通電性靴底と組み合わせて使用される通電性中底、および前記通電性中底を有する帯電防止性靴に関する。   The present invention relates to an electrically conductive insole that is satisfactorily cushioned, stitched to the instep subcutaneous edge and used in combination with an electrically conductive shoe sole, and an antistatic shoe having the electrically conductive insole.

従来、人体に静電気を蓄積させないために種々の帯電防止性靴が提案されている。   Conventionally, various antistatic shoes have been proposed in order not to accumulate static electricity in the human body.

帯電防止性靴の開発のポイントは、人体から靴底の接地面までの通電経路を形成するにあたって、製造コストの上昇を抑えるとともに履き心地を通常の靴と同等程度までに引き上げることである。   The point of development of antistatic shoes is to suppress the increase in manufacturing cost and raise the comfort to the same level as that of ordinary shoes in forming a current-carrying path from the human body to the ground contact surface of the shoe sole.

一般に、靴底は、発泡倍率を上げてクッション性を向上させると、耐磨耗性、引張強度などの物性が不足するため、適度の硬さの材料にて作製される。このことは、通常の靴底においても通電性の靴底においても同様である。そのため、靴へのクッション性の付与は、靴底の上面に、弾性体を有する中敷きあるいは中底を装着することによってなされる。しかしながら、弾性を有するとともに通電性を有する材料は高価である。
したがってクッション性に富む帯電防止性靴の費用対性能比率は、絶縁性弾性体を用い、これに如何にして通電経路を形成するかによるところが大きいことになる。
特許文献1には、厚み3mmの天然ゴムスポンジの上面及び下面にカーボン繊維を10mm間隔で織り込んだポリエステル製織布を貼着し、この貼着体の踏付部において上面及び下面を連絡するように銅を蒸着したポリエステル糸を二本、間隔5mmで縫着して得た靴中敷きが開示されている。
実開平3−102906号公報
In general, a shoe sole is made of a material having an appropriate hardness because physical properties such as wear resistance and tensile strength are insufficient when the foaming ratio is increased to improve cushioning properties. This is the same for both normal shoe soles and conductive shoe soles. Therefore, cushioning is imparted to the shoe by attaching an insole having an elastic body or an insole to the upper surface of the shoe sole. However, materials having elasticity and conductivity are expensive.
Therefore, the cost-to-performance ratio of the antistatic shoe rich in cushioning depends largely on how the insulating elastic body is used and the energization path is formed.
In Patent Document 1, a polyester woven fabric in which carbon fibers are woven at intervals of 10 mm is attached to the upper and lower surfaces of a natural rubber sponge having a thickness of 3 mm, and the upper and lower surfaces are communicated with each other at the stepped portion of the attached body. Discloses a shoe insole obtained by sewing two polyester yarns having copper deposited thereon at an interval of 5 mm.
Japanese Utility Model Publication No. 3-102906

特許文献1の考案において、10mm間隔でカーボン繊維を織り込んだ布帛の使用は、カーボン繊維の使用量が少ないためにコスト面で有利であり、また、踏付部において、上面、下面の導通を図ることは、人体と靴底と間の通電経路を形成するには好適である。しかしながら、導電糸を上面と下面とに連絡することは、使用者に異物感を抱かせるものである。
また、靴底部分の電気抵抗を低く設定すると、感電防止、製造コスト、物性の面で不利になることがあるが、逆に電気抵抗を高く設定した場合では、靴底が全面から静電気を流すようにされていないと、極端に静電気放出性が悪化することがある。例えば、特許文献1のように、下面の織布が10mm間隔のストライプ状の通電経路を有するような場合は、この通電経路と接地面とを比較的短い距離で結んでいるあたりでは静電気を多く流すが、それ以外の部分では静電気をほとんど流さない部分があり、静電気の放出が十分になされないことがある。
本発明は、異物感が無くクッション性が良好な帯電防止性靴の中底として有用な通電性中底、および帯電防止性靴を提供すること第一目的とし、さらに電気抵抗の比較的高い靴底と組み合わせて使用するときに有用な通電性中底、および帯電防止性靴を提供すること第二目的とする。
In the idea of Patent Document 1, the use of a fabric in which carbon fibers are woven at intervals of 10 mm is advantageous in terms of cost because the amount of carbon fibers used is small, and the upper and lower surfaces are electrically connected in the stepping portion. This is suitable for forming an energization path between the human body and the shoe sole. However, connecting the conductive yarn to the upper surface and the lower surface makes the user feel a foreign object.
If the electrical resistance of the shoe sole is set low, it may be disadvantageous in terms of electric shock prevention, manufacturing cost, and physical properties. Conversely, if the electrical resistance is set high, the shoe sole will carry static electricity from the entire surface. Otherwise, the electrostatic discharge property may be extremely deteriorated. For example, as in Patent Document 1, when the woven fabric on the lower surface has a stripe-shaped energization path with an interval of 10 mm, a large amount of static electricity is generated when the energization path and the ground plane are connected at a relatively short distance. Although there is a part that hardly flows static electricity in other parts, the static electricity may not be sufficiently discharged.
The first object of the present invention is to provide an electrically conductive insole useful as an insole for antistatic shoes having no foreign matter feeling and good cushioning properties, and an antistatic shoe, and further having a relatively high electrical resistance. A second object is to provide an electrically conductive insole useful in combination with a sole, and an antistatic shoe.

本発明の通電性中底は、弾性層の上面側に上面側通電性層、下面側に下面側通電性層が配置される中底であって、弾性層は絶縁性であり、中底の周縁部に施された縁縫いの導電糸により、両通電性層が導通されることを特徴とする。   The conductive insole of the present invention is an insole in which the upper surface side conductive layer is disposed on the upper surface side of the elastic layer and the lower surface side conductive layer is disposed on the lower surface side, and the elastic layer is insulative, Both conductive layers are electrically connected to each other by a conductive thread for edge sewing applied to the peripheral edge.

また、発明者らは、帯電防止性靴において、接足面側は、人体による湿気の上昇があるために特許文献1に記載のあるようなカーボン繊維を10mm間隔で織り込んだポリエステル製織布で形成すれば、靴下を履いた人体であっても人体が発する湿気により、靴下を履いた人体とこのカーボン繊維との間に生じる電気抵抗は数MΩ以下であり、実用上問題視するような静電気放出性の低下はないとのとの知見を得た。   In addition, in the antistatic shoes, the inventors are made of a polyester woven fabric in which carbon fibers as described in Patent Document 1 are woven at 10 mm intervals on the side of the contact surface because of the increase in moisture due to the human body. If formed, the electrical resistance generated between the human body wearing the socks and the carbon fiber due to the moisture generated by the human body even if the human body is wearing the socks is several MΩ or less, and static electricity that is regarded as a problem in practical use. The knowledge that there was no decline in releasability was obtained.

すなわち、好ましい態様の通電性中底は、上面側通電性層として、導電糸が少なくとも一本または適当な間隔で織り込まれるか編み込まれて作られる布帛を用い、前記導電糸が少なくとも第一趾中足骨頭ないし第二趾中足骨骨頭あたりを通るようにされており、下面側通電性層として、網状、膜状又はシート状の通電性のものを用いる。   That is, the conductive insole according to a preferred embodiment uses, as the upper surface side conductive layer, at least one conductive yarn or a fabric made by weaving or knitting at an appropriate interval, and the conductive yarn is at least in the first cocoon. It is designed to pass through the head of the toe or the second metatarsal bone, and a conductive material in the form of a mesh, film or sheet is used as the lower-side conductive layer.

本発明の帯電防止性靴は、上記の通電性中底を用いた帯電防止性靴であって、甲皮下縁部が周縁部に縫合された通電性中底の下面側通電性層に、射出または注入により成形される通電性靴底が直に接合してなることを特徴とする。   An antistatic shoe according to the present invention is an antistatic shoe using the above-described conductive insole, and is injected into the lower conductive layer on the bottom of the conductive insole where the instep subcutaneous edge is stitched to the periphery. Or the electroconductive shoe sole shape | molded by injection | pouring is joined directly, It is characterized by the above-mentioned.

本発明のもう一つの態様の帯電防止性靴は、上記の通電性中底を用いた帯電防止性靴であって、甲皮下縁部が周縁部に縫合された通電性中底の下面側通電性層に、通電性靴底が直に接合してなり、下面側通電性層は、弾性層の下面側に通電性靴底を接着する導電性接着剤が固化した層であることを特徴とする。   An antistatic shoe according to another aspect of the present invention is an antistatic shoe using the above-described conductive insole, wherein the underside energization of the conductive insole has an instep subcutaneous edge sewn to the peripheral edge. The conductive shoe sole is directly bonded to the conductive layer, and the lower conductive layer is a layer in which a conductive adhesive for bonding the conductive shoe sole to the lower surface side of the elastic layer is solidified. To do.

好ましい態様の帯電防止性靴は、通電性中底の下面側通電性層の単位面積あたりの電気抵抗が1MΩ以下であり、通電性靴底の体積固有抵抗率が100M〜10000MΩ・cmである。   In the antistatic shoe of a preferred embodiment, the electrical resistance per unit area of the lower conductive layer of the conductive middle sole is 1 MΩ or less, and the volume specific resistivity of the conductive shoe sole is 100 M to 10,000 MΩ · cm.

本発明の通電性中底は、弾性体として絶縁性のものを用いているので製造コスト面で有利なことはもちろん、周縁部が縁縫いによりしっかりしているので中底の周縁部と甲皮の下縁部との縫合が行いやすいという効果を奏する。また、この通電性中底は、上面側通電性層と下面側通電性層との導通が、中底の周縁部に施された導電糸によって行われるので、異物感が無くクッション性が良好である。
好ましい態様の通電性中底は、布帛に用いた導電糸により足から通電性中底自体へ静電気を流す経路を形成するものであり、その上、下面側通電性層が、網状、膜状又はシート状の通電性のものであるので下面側通電性層から通電性靴底への静電気の流れを下面側通電性層全面にわたり均等にすることができ、通電性靴底の静電気放出性能を良好に引き出す。
The electrically conductive insole of the present invention uses an insulating material as an elastic body, which is advantageous in terms of manufacturing cost, and of course, because the periphery is firmly secured by edge stitching, the periphery of the insole and the upper There is an effect that it is easy to sew with the lower edge portion. In addition, since this conductive midsole is electrically connected to the upper conductive layer and the lower conductive layer by conductive yarns applied to the peripheral edge of the midsole, there is no sense of foreign matter and cushioning is good. is there.
The electroconductive insole of a preferred embodiment forms a path through which static electricity flows from the foot to the electroconductive insole itself by the conductive yarn used for the fabric, and the lower surface side electroconductive layer has a net-like, film-like or Since it is a sheet-like conductive material, the flow of static electricity from the lower-surface conductive layer to the conductive shoe sole can be made uniform over the entire lower-surface conductive layer. Pull out.

本発明の帯電防止性靴は、中底として下面側通電性層全面から静電気を均等に流すものを用いていることにより、通電性靴底は全面にわたって上面から接地面へほぼ均等に静電気を流すことができるものであり、静電気放出性が良好である。
また、好ましい態様の帯電防止性靴は、下面側通電性層の単位面積あたりの電気抵抗が1MΩ以下であるので静電気放出の水準からすれば導電性であり、そのため、いっそう下面側通電性層から通電性靴底への静電気の流れを下面側通電性層全面にわたり均等にすることができるとともに、通電性靴底の体積固有抵抗率が100M〜10000MΩ・cmであることにより、通電性靴底の厚さ及び靴底意匠にもよるが、通電性靴底の電気抵抗(通電性靴底の上面と接地面との間)が概ね1M〜200MΩとなるので、いっそう静電気放出性が良好である。
The antistatic shoe of the present invention uses an insole that allows static electricity to flow evenly from the entire lower surface side conductive layer, so that the conductive shoe sole flows static electricity almost evenly from the upper surface to the ground plane over the entire surface. It has a good electrostatic discharge property.
In addition, since the electrical resistance per unit area of the lower surface side conductive layer is 1 MΩ or less, the antistatic shoe of the preferred embodiment is conductive from the level of electrostatic discharge. The flow of static electricity to the conductive shoe sole can be made uniform over the entire lower conductive layer, and the volume specific resistivity of the conductive shoe sole is 100 M to 10,000 MΩ · cm. Although it depends on the thickness and the sole design, the electrical resistance of the conductive shoe sole (between the upper surface of the conductive shoe sole and the grounding surface) is approximately 1 M to 200 MΩ, so that the electrostatic discharge property is even better.

以下本発明を図面に基づいて説明する。
本発明の通電性中底1を、上面側(接足面側)からみた斜視図を図1に示し、下面側(接地面側)からみた斜視図を図2に示す。通電性中底1は、弾性層2の上面側と下面側とに、通電性層3、4が接合されるとともに、中底の周縁部に導電糸6によって縁縫い5(縁かがり縫い)が施されている。
The present invention will be described below with reference to the drawings.
FIG. 1 shows a perspective view of the conductive midsole 1 of the present invention as viewed from the upper surface side (foot contact surface side), and FIG. 2 shows a perspective view as viewed from the lower surface side (ground surface side). The conductive midsole 1 has conductive layers 3 and 4 joined to the upper surface side and the lower surface side of the elastic layer 2 and edge stitching 5 (edge stitching) by a conductive thread 6 on the peripheral edge of the midsole. It has been subjected.

上面側通電性層3は、編布、織布、不織布などの布帛が、中底形状とされたときに内側と周縁部との間に静電気を流す通電経路が付与された通電性ものである。この通電経路の付与は、布帛を構成する繊維や糸に導電性のものを用いても良いし、布帛に導電処理したものでも良い。導電処理としては、無電解メッキ処理、導電ポリマー処理、金属蒸着処理、導電性物質の含浸処理などが挙げられる。
その中で、上面側通電性層は、製造コスト、風合いなどの理由で以下のような布帛が好ましい。好ましい布帛は、導電糸7が少なくとも一本織り込まれるか編み込まれて作られた布帛であり、導電糸が第一趾中足骨骨頭ないし第二趾中足骨骨頭あたりを通るようにされており、好ましくは踵骨あたりも通るようにされている。以上のような部位は足圧が大きくかかる部位なので、この部位に導電糸が通るようにされていると足から通電性中底へ静電気を流しやすい。また、この布帛は導電糸が5mm間隔以上で織り込まれるか編み込まれたものが好ましい。導電糸の間隔が小さいと布帛自体の製造コストが高くなる。この布帛は、編布のときは、よこ編又はたて編の糸として導電糸を挿入して編成されたものであり、織布のときは、たて糸及びよこ糸の少なくともいずれかの糸として導電糸を挿入して織成されたものである。また、この布帛が織布のときは、挿入した導電糸7が一方の表面に現れる度合いを増やした綾織や朱子織にして、導電糸7が多く現れる側を弾性層の反対側とし、縁縫い5の導電糸6と導通しやすいようにすることが好ましい。
なお、この布帛の導電糸以外の糸としては、ポリエステル、ナイロンのフィラメント糸や紡績糸、ポリエステル、ナイロンのステープルとレーヨンのステープルや綿などの混紡糸などが使用できる。
以上のように、好ましい上面側通電性層3は、導電糸7が布帛自体を構成する糸として用いられ、さらに導電糸の使用量が少なくされているので、導電糸による異物感がないとともに材料コスト面で有利である。
The upper surface side conductive layer 3 is an electrically conductive layer in which a conductive path for flowing static electricity is provided between the inner side and the peripheral portion when a fabric such as a knitted fabric, a woven fabric, or a non-woven fabric has an insole shape. . This energization path may be imparted by using conductive fibers or yarns constituting the fabric or by conducting a conductive treatment on the fabric. Examples of the conductive treatment include electroless plating treatment, conductive polymer treatment, metal vapor deposition treatment, and impregnation treatment with a conductive substance.
Among them, the upper surface-side conductive layer is preferably a fabric as described below for reasons such as manufacturing cost and texture. A preferred fabric is a fabric made by weaving or knitting at least one conductive thread 7, and the conductive thread passes around the head of the first heel metatarsal bone or the second heel metatarsal head. Preferably, it is made to pass around the ribs. Since the above portion is a portion where a foot pressure is greatly applied, if the conductive thread passes through this portion, static electricity is likely to flow from the foot to the conductive midsole. Further, this fabric is preferably one in which conductive yarn is woven or knitted at intervals of 5 mm or more. If the distance between the conductive yarns is small, the manufacturing cost of the fabric itself increases. In the case of a knitted fabric, the fabric is knitted by inserting a conductive yarn as a weft or warp knitting yarn, and in the case of a woven fabric, the conductive yarn is used as at least one of a warp yarn and a weft yarn. It is woven by inserting. When this fabric is a woven fabric, a twill weave or satin weave with an increased degree of appearance of the inserted conductive yarn 7 on one surface is used, and the side where the conductive yarn 7 appears is the opposite side of the elastic layer, and the edge is sewn. It is preferable that the conductive yarn 6 is easily conducted.
As the yarn other than the conductive yarn of this fabric, polyester, nylon filament yarn or spun yarn, polyester, nylon staple and rayon staple or cotton blended yarn can be used.
As described above, the preferred upper surface side conductive layer 3 is made of the conductive yarn 7 used as a yarn constituting the fabric itself, and further the amount of the conductive yarn used is reduced, so that there is no foreign matter feeling due to the conductive yarn and the material. It is advantageous in terms of cost.

布帛を構成する導電糸7及び縁縫い5に用いる導電糸6は、例えば、金属繊維、炭素繊維、無電解メッキ処理繊維などを含有する糸、カーボンや導電性金属化合物を含有する糸などが挙げられる。布帛に用いる導電糸7は、10cm長さ間の電気抵抗において1KΩ以下が好ましく、100Ω以下がより好ましい。この程度以下の電気抵抗のものは静電気放出の水準からすれば導電性であり、上記布帛に織り込まれるか編み込まれた導電糸7は、人体のいずれかの部分との間の電気抵抗が小さくなったところから大量に静電気を流すことができる。すなわち、上面側通電性層3と人体とは、部分的にでもその間の電気抵抗が小さくなれば静電気は十分に流れるため、導電糸7が少なくとも一本織り込まれるか編み込まれて作られた布帛でよい。
また、縁縫いに用いる導電糸6は、10cm長さ間の電気抵抗において10KΩ以下が好ましく、1KΩ以下がより好ましい。縁縫い用の導電糸6の電気抵抗の方が高くてもよい理由は、導通させようとする距離が短いからである。
Examples of the conductive yarn 7 used for the fabric and the edge stitch 5 constituting the fabric include a yarn containing metal fiber, carbon fiber, electroless plating fiber, a yarn containing carbon or a conductive metal compound, and the like. It is done. The conductive yarn 7 used for the fabric is preferably 1 KΩ or less, more preferably 100Ω or less in terms of electrical resistance between 10 cm lengths. Those having an electrical resistance below this level are conductive from the level of electrostatic discharge, and the conductive yarn 7 woven or woven into the fabric has a low electrical resistance with any part of the human body. A large amount of static electricity can flow from the place. That is, the upper surface side conductive layer 3 and the human body are made of a fabric made by weaving or knitting at least one conductive yarn 7 because the static electricity flows sufficiently if the electrical resistance between them is reduced even partially. Good.
The conductive yarn 6 used for edge stitching is preferably 10 KΩ or less, more preferably 1 KΩ or less, in terms of electrical resistance between 10 cm lengths. The reason why the electrical resistance of the conductive thread 6 for edge sewing may be higher is that the distance to be conducted is short.

下面側通電性層4は、中底形状とされたときに、内側と周縁部との間に静電気を流す通電性のもの、具体的には網状、膜状又はシート状の通電性のものであり、上面側通電性層と同様な材料が使用できる他、金属箔や金網、導電性接着剤の固化により形成された膜のような層であってもよい。導電性接着剤の固化による場合は、縁縫い5を施した後の導電糸6の上に導電性接着剤を塗布して下面側通電性層を形成してもよい。これらの中で、下面側通電性層としては、布帛に導電性接着剤を含浸して固化させたシート状ものが、材料コスト、製造工程での他の部材との接合性などの理由で好適である。導電性接着剤は、カーボンなどの導電性物質をバインダー物質に分散させたものである。
下面側通電性層4を、メッシュ布や金網などの網状の通電性のもので形成する場合は、通電性靴底10の厚さにもよるが、この靴底10の厚さが10〜25mm程度であれば目開きが5mm以下とすることで通電性靴底10の静電気放出性能を良好に引き出すことができる。
この下面側通電性層4は、単位面積あたりの電気抵抗において1MΩ以下が好ましく、100KΩ以下がより好ましい。この程度以下の電気抵抗であることにより、下面側通電性層4から通電性靴底10への静電気の流れを下面側通電性層全面にわたりほぼ均等にすることができる。
なお、本発明のいう単位面積あたりの電気抵抗は、図6に示すように金属クリップで端部をクリップした正方形の通電性層の両端に(例えば幅1cm、長さ1cmの通電性シートの両端に)、抵抗値に応じて適当な電圧を加えたときに流れる電流値から算出する。
When the lower surface side conductive layer 4 is in the shape of an insole, it has a conductive property that allows static electricity to flow between the inner side and the peripheral portion, specifically, a mesh-like, film-like or sheet-like one. In addition, the same material as that of the upper surface side conductive layer can be used, and a layer such as a metal foil, a metal mesh, or a film formed by solidifying a conductive adhesive may be used. In the case of solidifying the conductive adhesive, the lower surface side conductive layer may be formed by applying a conductive adhesive on the conductive yarn 6 after the edge stitch 5 is applied. Among these, as the lower-surface-side conductive layer, a sheet-like material obtained by impregnating a fabric with a conductive adhesive and solidifying is preferable for reasons such as material cost and bondability with other members in the manufacturing process. It is. The conductive adhesive is obtained by dispersing a conductive material such as carbon in a binder material.
When the lower surface side conductive layer 4 is formed of a mesh-like conductive material such as a mesh cloth or a wire mesh, the thickness of the shoe sole 10 is 10 to 25 mm, although it depends on the thickness of the conductive shoe sole 10. If the degree is about, the opening of the mesh is 5 mm or less, and the electrostatic discharge performance of the conductive shoe sole 10 can be satisfactorily brought out.
The lower surface side conductive layer 4 is preferably 1 MΩ or less, more preferably 100 KΩ or less in terms of electrical resistance per unit area. By having an electrical resistance below this level, the flow of static electricity from the lower surface side conductive layer 4 to the conductive shoe sole 10 can be made substantially uniform over the entire lower surface side conductive layer.
The electrical resistance per unit area referred to in the present invention is as shown in FIG. 6 at both ends of a square conductive layer clipped at the end with a metal clip (for example, both ends of a conductive sheet having a width of 1 cm and a length of 1 cm). And) from the value of the current that flows when an appropriate voltage is applied according to the resistance value.

弾性層2は、ポリウレタン、ポリエチレン、エチレン酢酸ビニル共重合体などの合成樹脂製発泡体をシート状に成形した絶縁性弾性体が好適であり、また、繊維材で形成したウェブ、不織布、パイル生地なども使用できる。弾性体の厚さは、中底を甲皮に縫合する必要があるので2〜6mmとすると良い。   The elastic layer 2 is preferably an insulating elastic body obtained by forming a synthetic resin foam such as polyurethane, polyethylene, or ethylene vinyl acetate copolymer into a sheet shape, and a web, a nonwoven fabric, or a pile fabric formed of a fiber material. Etc. can also be used. The thickness of the elastic body is preferably 2 to 6 mm because it is necessary to sew the insole to the crust.

中底の周縁部に施す縁縫い5は、直線縫い、複列縫い、千鳥縫いなどの縫い方でよいが、JISL0120に説明されている縁かがり縫いが好適である。縁かがり縫いは、例えば図3に示すように中底の端面に糸のループが現れるようにされているものであり、糸により弾性層が歪む程度の張力で縫いを施すと良い。その際、導電糸7が織り込まれるか編み込まれたて作られた布帛を上面側通電性層3として用いる場合は、導電糸6の送り部分Lが存在する側を、上面側通電性層側と一致させることにより、縁かがり縫いの導電糸6と布帛の導電糸7との導通が確実なものとなる。縁縫いを、縁かがり縫いによって行えば、中底の周縁部がよりしっかりして、甲皮の下縁部との縫合がいっそう行いやすい。   The edge stitch 5 applied to the peripheral edge of the midsole may be a straight stitch, a double row stitch, a staggered stitch or the like, but the edge stitch described in JISL0120 is suitable. In the edge stitching, for example, as shown in FIG. 3, a thread loop appears on the end face of the insole, and it is preferable that the thread is sewn with a tension that causes the elastic layer to be distorted by the thread. In that case, when using the fabric made by weaving or knitting the conductive yarn 7 as the upper surface side conductive layer 3, the side where the feeding portion L of the conductive yarn 6 exists is the upper surface side conductive layer side. By making them coincide with each other, the conduction between the conductive yarn 6 for edge stitching and the conductive yarn 7 for fabric is ensured. If the edge stitching is performed by edge stitching, the peripheral edge of the insole is more firm and the lower edge of the upper is more easily sewn.

通電性中底1においては、上面側通電性層3の第一ないし第二趾中足骨骨頭あたりの導電糸7と、ちょうどこの位置の下側面に相当する位置の下面側通電性層4との間の電気抵抗が1MΩ以下であることが好ましく、100KΩ以下がより好ましい。この電気抵抗が1MΩ以下が好ましい理由は、本発明がより効果を発揮するのは、靴底の電気抵抗(靴底の上面と接地面との間)が概ね1MΩ以上のものであり、靴底の電気抵抗と同程度であれば靴底の静電気放出を阻害する要因とはならないと考えられるからである。   In the conductive middle sole 1, the conductive thread 7 around the first or second heel metatarsal head of the upper conductive layer 3, and the lower conductive layer 4 at a position just corresponding to the lower side of this position, Is preferably 1 MΩ or less, more preferably 100 KΩ or less. The reason why the electrical resistance is preferably 1 MΩ or less is that the present invention is more effective because the electrical resistance of the shoe sole (between the top surface of the shoe sole and the grounding surface) is approximately 1 MΩ or more. This is because it is considered that it is not a factor that inhibits the discharge of static electricity from the shoe sole if it is comparable to the electrical resistance of the shoe.

通電性靴底10は、中底周縁部を甲皮下縁部に縫合して袋状にした図4に示すような甲材9を靴型(ラストモールド)に被せ、これと底型(ボトムモールド)などに組み合わせて靴底成形空間を形成し、この空間に通電性靴底材料を射出又は注入することにより、成形されると同時に中底及び甲皮下縁部に直に接合する方式による靴底であってもよいし、中底周縁部を甲皮下縁部に縫合して袋状にした甲材9を靴型に被せ、中底の下面に導電性接着剤を塗布し、ここに通電性靴底を直に接合する方式による靴底であってもよい。後者の方式で用いる導電性接着剤は、固化することにより本発明でいう下面側通電性層4となる。
なお、中底周縁部と甲皮下縁部との縫合は、両者を合掌状に重ねるとともに両者の端面を揃えて縫合する方式が作業性がよい。また、中底周縁部と甲皮周縁部との縫合には、糸として導電性のものを用いる必要はない。
The conductive shoe sole 10 is covered with a shoe mold (last mold) and a bottom mold (bottom mold) as shown in FIG. ) To form a sole forming space, and by injecting or injecting a conductive sole material into this space, the sole is molded and directly joined to the insole and the instep subcutaneous edge at the same time. It is also possible to cover the shoe 9 with a bag-shaped upper 9 that is stitched to the inferior edge of the insole, and a conductive adhesive is applied to the lower surface of the insole. It may be a shoe sole that directly joins the shoe sole. The conductive adhesive used in the latter method becomes the lower surface side conductive layer 4 in the present invention by solidifying.
In addition, as for the sewing of the midsole peripheral edge portion and the instep subcutaneous edge portion, a method in which both are overlapped in a palm-like manner and the both end surfaces are aligned and stitched is good. In addition, it is not necessary to use a conductive thread for stitching between the mid-sole peripheral part and the crust peripheral part.

通電性靴底の材料は、導電性金属化合物、カーボン、界面活性剤などを混入したゴム、合成樹脂が使用できる。通電性靴底を構成する材料の体積固有抵抗率(JISK6911)は100M〜10000MΩ・cmであることが好ましい。体積固有抵抗率が100MΩ・cm未満であると製造コスト、物性の面で不利であり、10000MΩ・cm超であると靴底の上面と接地面との間の電気抵抗が200MΩ程度以上となることがあり、ひいては帯電防止性靴の静電気放出性が極端に悪化することがある。   As a material for the conductive shoe sole, a conductive metal compound, carbon, rubber mixed with a surfactant, or a synthetic resin can be used. The volume resistivity (JISK6911) of the material constituting the conductive shoe sole is preferably 100 M to 10,000 MΩ · cm. If the volume resistivity is less than 100 MΩ · cm, it is disadvantageous in terms of production cost and physical properties, and if it exceeds 10000 MΩ · cm, the electrical resistance between the upper surface of the shoe sole and the grounding surface is about 200 MΩ or more. As a result, the electrostatic discharge of the antistatic shoe may be extremely deteriorated.

(実施例1)・・通電性中底Aの作製
上面側通電性層3として、導電糸7をたて糸として10mm間隔で朱子織にて織り込んで導電糸が表面に現れる度合いを高めた朱子織布を準備した。導電糸7は導電性繊維とポリエステルフィラメント糸を撚糸した10cm長さ間の電気抵抗が100Ωのものである。弾性層2として、厚さ3.5mm、比重0.2のエチレン酢酸ビニル重合体の発泡体からなる絶縁性の弾性体を準備した。下面側通電性層4として、カーボン含有の導電性接着剤を平織布に含浸・固化させた単位面積あたりの電気抵抗が15KΩのカーボン含有平織布を準備した。これらの上面側通電性層、弾性層、下面側通電性層をこの順で接着剤にて接合して三層構造のシートを作製し、これを靴に合った形状に裁断したのち、10cm長さ間の電気抵抗が6KΩの導電糸6でその周縁部に図3に示す縁かがり縫い5を施して靴サイズ26cm用の通電性中底Aを作製した。
この通電性中底の第二趾中足骨骨頭あたりの導電糸7と、この導電糸の位置の下面側に相当する位置の下面側通電性層との間の電気抵抗は50KΩであった。
(Example 1)-Production of conductive middle sole A As the upper conductive layer 3, a satin woven fabric in which conductive yarns 7 are woven with satin weaving at intervals of 10 mm as warps to increase the degree of appearance of the conductive yarns on the surface. Prepared. The conductive yarn 7 has an electric resistance of 100Ω between 10 cm lengths obtained by twisting a conductive fiber and a polyester filament yarn. As the elastic layer 2, an insulating elastic body made of an ethylene vinyl acetate polymer foam having a thickness of 3.5 mm and a specific gravity of 0.2 was prepared. A carbon-containing plain woven fabric having an electric resistance of 15 KΩ per unit area prepared by impregnating and solidifying a plain-woven fabric with a carbon-containing conductive adhesive as the lower surface side conductive layer 4 was prepared. These upper surface side conductive layer, elastic layer, and lower surface side conductive layer are joined together in this order with an adhesive to produce a three-layer structure sheet, which is cut into a shape that matches the shoe, and is 10 cm long A conductive thread 6 having an electrical resistance of 6 KΩ was applied with edge stitching 5 shown in FIG. 3 at the periphery thereof to produce a conductive midsole A for a shoe size of 26 cm.
The electrical resistance between the conductive thread 7 around the second mid-metatarsal bone head of the conductive midsole and the lower-surface conductive layer at a position corresponding to the lower surface side of the position of the conductive thread was 50 KΩ.

(実施例2)・・通電性中底Bの作製
下面側通電性層として、カーボン含有平織布の単位面積あたりの電気抵抗が200KΩのものを用いた以外は、実施例1と同様にして通電性中底Bを作製した。
この通電性中底の第二趾中足骨骨頭あたりの導電糸7と、この導電糸の位置の下面側に相当する位置の下面側通電性層との間の電気抵抗は700KΩであった。
(Example 2)-Preparation of conductive middle bottom B As in the case of Example 1, except that the lower surface side conductive layer used was a carbon-containing plain woven fabric having an electric resistance per unit area of 200 KΩ. An electrically conductive insole B was produced.
The electrical resistance between the conductive thread 7 around the second mid-metatarsal bone head of the conductive midsole and the lower surface side conductive layer at a position corresponding to the lower surface side of the position of the conductive thread was 700 KΩ.

(実施例3)・・帯電防止性靴Aの作製
実施例1の通電性中底Aを用いて、この中底Aに甲皮下縁部を縫合して袋状の甲材を作製し、これを靴型に被せて射出成形法による体積固有抵抗率が2050MΩ・cmの通電性靴底を通電性中底Aの下面に直に接合して帯電防止性靴Aを作製した。
なお、靴底材料としては、四級アンモニウム塩を混合した発泡倍率2倍程度のポリウレタン原料を用い、靴底は平均厚さ15mmに成形した。この帯電防止性靴AのJIST8103に準拠して測定した電気抵抗は30MΩであった。
(Example 3) Preparation of anti-static shoe A Using the conductive insole A of Example 1, a bag-shaped upper material was prepared by stitching the instep subcutaneous edge to the insole A. Was put on a shoe mold, and an electrically conductive shoe sole having a volume resistivity of 2050 MΩ · cm by an injection molding method was directly joined to the lower surface of the electrically conductive insole A to produce an antistatic shoe A.
In addition, as a shoe sole material, a polyurethane raw material having a foaming ratio of about 2 times mixed with a quaternary ammonium salt was used, and the shoe sole was molded to an average thickness of 15 mm. The electric resistance of this antistatic shoe A measured in accordance with JIST8103 was 30 MΩ.

(実施例4)・・帯電防止性靴Bの作製
通電性中底Aを通電性中底Bに変更した以外は、実施例3と同様にして帯電防止性靴を作製した。この帯電防止性靴のJIST8103による電気抵抗は30MΩであった。
Example 4 Production of Antistatic Shoes B Antistatic shoes were produced in the same manner as in Example 3 except that the conductive insole A was changed to the conductive insole B. The electric resistance of this antistatic shoe according to JIST8103 was 30 MΩ.

(実施例5)・・帯電防止性靴Cの作製
下面側通電性層として、通電性中底Aにおけるカーボン含有平織布を変更して、カーボンを含有しない平織布を用いた以外は、実施例1と同様にして中底を作製し、この中底に甲皮下縁部を縫合して袋状の甲材を作製し、これを靴型に被せてから中底の下面の平織布及び縁かがり縫いの導電糸の露出部分に導電性接着剤を塗布したのち、別途作製の体積固有抵抗率が500MΩ・cmのカーボン含有のゴム製靴底を接合して帯電防止性靴Cを作製した。この帯電防止性靴のJIST8103による電気抵抗は5MΩであった。
また、この帯電防止性靴の靴底部分を削り取って、導電性接着剤の固化した膜状の部分(下面側通電性層)の単位面積あたりの電気抵抗を測定したところ50KΩであった。
(Example 5) ·· Preparation of antistatic shoe C As the lower surface side conductive layer, except for changing the carbon-containing plain woven fabric in the conductive middle bottom A and using a plain woven fabric not containing carbon, The insole is produced in the same manner as in Example 1, and the undercut edge is sewn to the insole to produce a bag-like upper. Then, after applying a conductive adhesive to the exposed portion of the conductive yarn for edge stitching, an antistatic shoe C was prepared by bonding a separately-made carbon-containing rubber shoe sole having a volume resistivity of 500 MΩ · cm. . The electric resistance of this antistatic shoe according to JIST8103 was 5 MΩ.
Further, the bottom portion of this antistatic shoe was scraped off, and the electric resistance per unit area of the film-like portion solidified with the conductive adhesive (lower conductive layer) was measured to be 50 KΩ.

(実施例6)・・通電性中底Dの作製
下面側通電性層として、通電性中底Aにおけるカーボン含有平織布を変更して、上面側通電性層と同じ朱子織布を用いた以外は、実施例1と同様にして通電性中底Dを作製した。
この通電性中底の第二趾中足骨骨頭あたりの導電糸と、この導電糸の位置の下面側に相当する位置の下面側通電性層との間の電気抵抗は200KΩであった。
(Example 6)-Preparation of conductive midsole D As the lower conductive layer, the carbon-containing plain woven fabric in the conductive conductive bottom A was changed, and the same satin woven fabric as the upper conductive layer was used. Except for the above, an electrically conductive insole D was produced in the same manner as in Example 1.
The electrical resistance between the conductive thread around the second mid-metatarsal bone head of the conductive midsole and the lower surface side conductive layer at a position corresponding to the lower surface side of the position of the conductive thread was 200 KΩ.

(実施例7)・・帯電防止性靴Dの作製
通電性中底Dを用いて、実施例3と同様にして帯電防止性靴Dを作製した。この帯電防止性靴のJIST8103による電気抵抗は90MΩであり、この値は実施例3の3倍であり、やや靴底の静電気放出性能を引き出せないものであった。
Example 7 Production of Antistatic Shoes D Antistatic shoes D were produced in the same manner as Example 3 using the conductive insole D. The electric resistance of this antistatic shoe according to JIST8103 was 90 MΩ, which was three times that of Example 3, and the electrostatic discharge performance of the shoe sole could not be brought out.

(実施例8)・・通電性中底Eの作製
下面側通電性層として、通電性中底Aにおけるカーボン含有平織布を変更して、目開き2mmのメッシュ布の無電解メッキ処理品(単位面積あたりの電気抵抗は10Ω以下)を用いた以外は、実施例1と同様にして通電性中底Eを作製した。
この通電性中底の第二趾中足骨骨頭あたりの導電糸7と、この導電糸の位置の下面側に相当する位置の下面側通電性層との間の電気抵抗は10Ω以下であった。
(Embodiment 8)-Preparation of conductive middle bottom E As the lower conductive layer, the carbon-containing plain woven fabric in the conductive middle bottom A was changed, and the electroless plating product of mesh cloth with 2 mm openings ( An electrically conductive insole E was prepared in the same manner as in Example 1 except that the electrical resistance per unit area was 10Ω or less.
The electrical resistance between the conductive thread 7 around the second mid-metatarsal bone head of the conductive midsole and the lower conductive layer at a position corresponding to the lower surface of the conductive thread position was 10Ω or less. .

(実施例9)・・帯電防止性靴Eの作製
通電性中底Eを用いて、実施例3と同様にして帯電防止性靴Dを作製した。この帯電防止性靴のJIST8103による電気抵抗は30MΩであった。
なお、以上において、導電糸、下面側通電性層に関する部分の電気抵抗の測定は、1KΩ未満は印加電圧3V、1KΩ以上は印加電圧9Vで行った。
Example 9 Production of Antistatic Shoes E Antistatic shoes D were produced in the same manner as in Example 3 using the conductive insole E. The electric resistance of this antistatic shoe according to JIST8103 was 30 MΩ.
In addition, in the above, the measurement of the electrical resistance of the part regarding the conductive yarn and the lower surface side conductive layer was performed at an applied voltage of 3 V for less than 1 KΩ and an applied voltage of 9 V for 1 KΩ or more.

実施例3、4、5、7、9の帯電防止性靴は、縁かがり縫いした中底を用いたので、製造過程において中底周縁部と甲皮下縁部との縫合が行いやすいものであった。また、これらの帯電防止性靴は異物感が無く良好なクッション性を示した。   In the antistatic shoes of Examples 3, 4, 5, 7, and 9, since the insole that was sewed on the edge was used, it was easy to sew the periphery of the insole and the instep subcutaneous edge in the manufacturing process. It was. Moreover, these antistatic shoes showed a good cushioning property with no foreign matter feeling.

本発明の通電性中底を説明するために一部を切り欠いた上面側斜視説明図。The upper surface side perspective explanatory drawing which notched one part in order to demonstrate the electroconductive insole of this invention. 本発明の通電性中底の下面側斜視説明図。The lower surface side perspective explanatory drawing of the electroconductive inside bottom of this invention. 縁かがり縫いの説明図。Explanatory drawing of edge stitching. 通電性中底と甲皮との縫合の態様の説明図。Explanatory drawing of the aspect of suturing with an electroconductive insole and a crust. 本発明の帯電防止性靴を説明するために半分を切り欠いた側面説明図。Side explanatory drawing which notched half in order to demonstrate the antistatic shoes of this invention. 電気抵抗測定の説明図。Explanatory drawing of an electrical resistance measurement.

符号の説明Explanation of symbols

1・・・通電性中底、2・・・弾性層、3・・・上面側通電性層、4・・・下面側通電性層、5・・・縁縫い(縁かがり縫い)、6・・・導電糸、7・・・導電糸、8・・・甲皮、9・・・甲材、10・・・通電性靴底、11・・・帯電防止性靴。 DESCRIPTION OF SYMBOLS 1 ... Conductive insole, 2 ... Elastic layer, 3 ... Upper surface side conductive layer, 4 ... Lower surface side conductive layer, 5 ... Edge stitching (edge stitching), 6. .. Conductive yarn, 7... Conductive yarn, 8 .. upper, 9 .. upper, 10 .. conductive shoe sole, 11 .. antistatic shoe.

Claims (5)

弾性層の上面側に上面側通電性層、下面側に下面側通電性層が配置される中底であって、
弾性層は絶縁性であり、
中底の周縁部に施された縁縫いの導電糸により、両通電性層が導通されることを特徴とする通電性中底。
An insole in which an upper surface side conductive layer is disposed on the upper surface side of the elastic layer and a lower surface side conductive layer is disposed on the lower surface side,
The elastic layer is insulating,
An electrically conductive insole characterized in that both electrically conductive layers are electrically connected by edge-sewn conductive threads applied to the peripheral edge of the insole.
上面側通電性層は、導電糸が少なくとも一本または適当な間隔で織り込まれるか編み込まれて作られる布帛であるとともに、導電糸が少なくとも第一趾中足骨頭ないし第二趾中足骨骨頭あたりを通るようにされており、
下面側通電性層は、網状、膜状又はシート状の通電性のものであることを特徴とする請求項1に記載の通電性中底。
The upper surface side conductive layer is a fabric made by weaving or knitting at least one conductive yarn or at an appropriate interval, and the conductive yarn is at least around the head of the first heel metatarsal bone or the second heel metatarsal bone. To pass through,
The electroconductive insole according to claim 1, wherein the lower surface side electroconductive layer is a net-like, film-like or sheet-like electroconductive layer.
請求項1又は2に記載の通電性中底を有する帯電防止性靴であって、
甲皮下縁部が周縁部に縫合された通電性中底の下面側通電性層に、射出または注入により成形される通電性靴底が直に接合してなることを特徴とする帯電防止性靴。
An antistatic shoe having an electrically conductive insole according to claim 1 or 2,
An antistatic shoe characterized in that a conductive shoe sole formed by injection or injection is directly joined to a lower conductive layer of a conductive midsole having a subcutaneous instep edge stitched to a peripheral portion. .
請求項1又は2に記載の通電性中底を有する帯電防止性靴であって、
甲皮下縁部が周縁部に縫合された通電性中底の下面側通電性層に、通電性靴底が直に接合してなり、
下面側通電性層は、弾性層の下面側に通電性靴底を接着する導電性接着剤が固化した層であることを特徴とする帯電防止性靴。
An antistatic shoe having an electrically conductive insole according to claim 1 or 2,
The conductive shoe sole is directly joined to the lower conductive layer of the conductive insole where the instep subcutaneous edge is stitched to the peripheral edge,
The antistatic shoe, wherein the lower conductive layer is a layer in which a conductive adhesive that bonds the conductive shoe sole to the lower surface of the elastic layer is solidified.
通電性中底の下面側通電性層の単位面積あたりの電気抵抗が1MΩ以下であり、通電性靴底の体積固有抵抗率が100M〜10000MΩ・cmであることを特徴とする請求項3又は4に記載の帯電防止性靴。   5. The electrical resistance per unit area of the lower surface side conductive layer of the conductive middle sole is 1 MΩ or less, and the volume specific resistivity of the conductive shoe sole is 100 M to 10,000 MΩ · cm. Antistatic shoes described in 1.
JP2006114117A 2006-04-18 2006-04-18 Conductive insoles and antistatic shoes. Active JP4982104B2 (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
ES2382321A1 (en) * 2010-02-12 2012-06-07 Francisco Mendi, S.L Driver footwear (Machine-translation by Google Translate, not legally binding)
KR102643800B1 (en) * 2023-01-30 2024-03-06 주식회사 플라이어 Multifunctional electromagnetic wave absorber based on embroidery process and clothing manufactured therefrom
KR102643804B1 (en) * 2023-01-30 2024-03-06 주식회사 플라이어 Method of manufacturing multifunctional electromagnetic wave absorber using embroidery pattern structure

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS59115902U (en) * 1983-09-22 1984-08-04 アキレス株式会社 antistatic shoes
JPS6375206U (en) * 1986-11-07 1988-05-19
JPH01291804A (en) * 1988-05-20 1989-11-24 Shitsuku:Kk Antistatic footwear and component therefor and machining thereof
JP2002223805A (en) * 2000-11-30 2002-08-13 Achilles Corp Electrically conductive shoe
JP2003310301A (en) * 2002-04-24 2003-11-05 Hiroshima Kasei Ltd Antistatic shoes

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS59115902U (en) * 1983-09-22 1984-08-04 アキレス株式会社 antistatic shoes
JPS6375206U (en) * 1986-11-07 1988-05-19
JPH01291804A (en) * 1988-05-20 1989-11-24 Shitsuku:Kk Antistatic footwear and component therefor and machining thereof
JP2002223805A (en) * 2000-11-30 2002-08-13 Achilles Corp Electrically conductive shoe
JP2003310301A (en) * 2002-04-24 2003-11-05 Hiroshima Kasei Ltd Antistatic shoes

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
ES2382321A1 (en) * 2010-02-12 2012-06-07 Francisco Mendi, S.L Driver footwear (Machine-translation by Google Translate, not legally binding)
KR102643800B1 (en) * 2023-01-30 2024-03-06 주식회사 플라이어 Multifunctional electromagnetic wave absorber based on embroidery process and clothing manufactured therefrom
KR102643804B1 (en) * 2023-01-30 2024-03-06 주식회사 플라이어 Method of manufacturing multifunctional electromagnetic wave absorber using embroidery pattern structure

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