JP2008114382A - Decorative body - Google Patents
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- JP2008114382A JP2008114382A JP2006297016A JP2006297016A JP2008114382A JP 2008114382 A JP2008114382 A JP 2008114382A JP 2006297016 A JP2006297016 A JP 2006297016A JP 2006297016 A JP2006297016 A JP 2006297016A JP 2008114382 A JP2008114382 A JP 2008114382A
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本発明は、基体と布体とを一体化した装飾体に関するものである。 The present invention relates to a decorative body in which a base and a cloth body are integrated.
熱収縮による締め付けと熱融着による繊維同士の固定化が同時に出来るという布体が知られている(特許文献1)。筒状基体と、該基体表面を覆う合わせ目の無い筒状布体とを接着層を介して一体化する方法が知られている(特許文献2)。 A cloth body is known in which fastening by heat shrinkage and fixation of fibers by heat fusion can be performed simultaneously (Patent Document 1). A method is known in which a cylindrical base and a seamless cylindrical cloth covering the surface of the base are integrated via an adhesive layer (Patent Document 2).
しかしながら、特許文献1に記載されている布体は、糸同士の融着や収縮により布体としての効果は優れているものの、布体の締め付けだけで基材への被覆をしている。よって、締め付けによる被覆では基材との接合力が不足しており、剥がれや基材に対する回転(位置ずれ)などが発生してしまっていた。また、特許文献2に記載されている、筒状基体と該基体表面を覆う合わせ目の無い筒状布体とを接着層を介して一体化する方法は、基体側に接着層を設けなければならないこと、布を接着する際、治具から一度外す必要があるという工程の煩雑さが問題となる。
However, although the cloth body described in
そこで、本発明は、少なくとも2種類以上の繊維を用いて、表面と裏面に露出する比率が異なるように構成される布体において、表面に露出する比率が高い繊維として天然繊維および/又は非熱融着性の合成繊維および/又は熱収縮繊維を用い、かつ裏面に露出する比率が高い繊維として熱融着繊維を用いた布体を基体に被覆して一体化したことを要旨とする。 Therefore, the present invention uses natural fibers and / or non-heat as fibers having a high ratio of being exposed on the front surface in a fabric that uses at least two types of fibers and has different ratios of being exposed on the front and back surfaces. The gist is that a base material is coated with a cloth body using heat-fusible fiber as a fiber having a high ratio exposed on the back surface and using fusible synthetic fiber and / or heat-shrinkable fiber.
本発明は、少なくとも2種類以上の繊維を用いて、表面と裏面に露出する比率が異なるように構成される布体において、表面に露出する比率が高い繊維として天然繊維および/又は非熱融着性の合成繊維および/又は熱収縮繊維を用い、かつ裏面に露出する比率が高い繊維として熱融着繊維を用いた布体を基体に被覆して一体化しているため、布体で発生する基材への接着強度を向上させると共に、布側に熱融着繊維を用いることにより、接着剤の塗布工程を省くことで生産性に優れた装飾体を提供することが出来る。 The present invention uses at least two or more types of fibers, and in a fabric configured to have different ratios exposed on the front surface and back surface, natural fibers and / or non-thermal fusion as fibers having a high ratio exposed on the surface. The base material generated in the cloth body is made by covering the base material with a cloth body using heat-synthesizing fibers and / or heat-shrinkable fibers and using a heat-fusible fiber as a fiber exposed to the back surface at a high ratio. By improving the adhesive strength to the material and using heat-bonded fibers on the fabric side, a decorative body having excellent productivity can be provided by omitting the adhesive application step.
基材は、金属や樹脂、木材、石材など平面・曲面を形成できるものでればよく、特に限定されない。また、この材質は1種または2種以上の混合物であってもよい。金属の例としては、金、銀、白金等の貴金属、ステンレス、真鍮等の合金、アルミニウム、マグネシウム等の軽金属やチタン等が挙げられるが、真鍮、ステンレス、アルミニウムが加工性、材料単価の点から好ましい。樹脂の例としてはポリ塩化ビニル(PVC)、ポリ塩化ビニリデン(PVDC)、ポリエチレン樹脂(PS)、アクリロニトリルスチレン樹脂(AS)、アクリロニトリルスチレンブタジエン樹脂(ABS)、メタクリル樹脂(PMMA)、ポリアセタール樹脂(POM)、ポリアミド樹脂(PA)、ポリカーボネート樹脂(PC)、ポリエチレンテレフタラート樹脂(PET)、四フッ化エチレン樹脂(PTFE)が挙げられる。基材の成形は、プレス、切削加工、鍛造、鋳造、射出、押出成形等の方法を用いて行えば良く、特に限定されるものではない。基材の色は、布の発色を良くするため反射率の高い白系の色が好ましく、金属の場合は、塗装層を設け着色しておくことが望ましい。塗膜層は、原則として一般の塗装法、印刷法により形成されれば良く、特に限定されるものではない。また、意匠性向上の目的で下層からの反射率を高めるために、樹脂や金属軸上にめっきを施しても良い。原則として、めっき皮膜は、一般のめっき手法により形成されれば良く、特に限定されるものではない。 The base material is not particularly limited as long as it can form a plane / curved surface such as metal, resin, wood, and stone. The material may be one kind or a mixture of two or more kinds. Examples of metals include noble metals such as gold, silver and platinum, alloys such as stainless steel and brass, light metals such as aluminum and magnesium, titanium, etc., but brass, stainless steel and aluminum are from the point of workability and material unit price. preferable. Examples of the resin include polyvinyl chloride (PVC), polyvinylidene chloride (PVDC), polyethylene resin (PS), acrylonitrile styrene resin (AS), acrylonitrile styrene butadiene resin (ABS), methacrylic resin (PMMA), and polyacetal resin (POM). ), Polyamide resin (PA), polycarbonate resin (PC), polyethylene terephthalate resin (PET), and tetrafluoroethylene resin (PTFE). The base material may be formed using a method such as pressing, cutting, forging, casting, injection, or extrusion molding, and is not particularly limited. The base color is preferably a white color with high reflectivity in order to improve the color of the cloth. In the case of metal, it is desirable to provide a coating layer and color it. The coating layer may be formed by a general coating method or printing method in principle, and is not particularly limited. Moreover, in order to increase the reflectance from the lower layer for the purpose of improving the designability, plating may be performed on the resin or the metal shaft. In principle, the plating film may be formed by a general plating method and is not particularly limited.
布体は、少なくとも2種類以上の繊維を用いて、表面と裏面に露出する比率が異なるように構成されるものとする。すなわち、布体は、表面には天然繊維又は/および非熱融着性の合成繊維又は/および熱収縮繊維が、裏面には熱融着繊維が多く出るように構成されるものとする。熱融着繊維は天然繊維・合成繊維・熱収縮繊維と併用してもかまわない。ここで用いる繊維は、天然繊維は綿、麻、毛、絹、合成繊維は熱融着性を有さないポリエステル、ナイロン、アクリルなどが挙げられる。毛羽立ちなどを考慮すると天然繊維より合成繊維の方が好ましいが、特に限定されるものではない。また、熱収縮繊維、熱融着繊維は、それぞれ熱を加えることで収縮、接着する機能があれば材質、物性等は特に限定はされないが、熱収縮繊維は乾熱収縮率(SHD)が20%以上のもの、また基材の材質が樹脂の場合も考慮して熱融着繊維の融点はなるべく低い方が好ましい。ちなみに、乾熱収縮率(SHD)が20%未満の繊維にあっては、基材との接着不良と言う問題が発生してしまい、又、熱融着繊維の融点が90℃以上の繊維にあっては、樹脂への接着が困難と言う問題がありあまり好ましくない。布体の構成方法としては、織物、編物、組物が挙げられるが、布体を形成できれば良く特に限定されない。織り方の例としては、平織り・綾織り・朱子織り・袋織りなどが挙げられる。編み方の例として、経編み、緯編み、丸編みなどが挙げられる。組物の例としては、平打組物、丸打組物が挙げられる。平面状の布体と筒状基体を接着する場合は、合わせ目が出来、この合わせ目において編んだ柄が合わない、合わせ目がほつれる等の装飾性が低下するという問題点があるため、軸体・塗布具容器の装飾として用いる場合は、筒状形態の布が好ましい。 A fabric shall be comprised so that the ratio exposed to the surface and a back surface may differ using at least 2 or more types of fiber. That is, the fabric is configured such that a large amount of natural fibers and / or non-heat-synthetic synthetic fibers or / and heat-shrinkable fibers appear on the surface, and many heat-sealable fibers appear on the back surface. The heat fusion fiber may be used in combination with natural fiber, synthetic fiber, or heat shrinkable fiber. Examples of the fibers used here include cotton, hemp, hair, silk as natural fibers, and polyester, nylon, acrylic, and the like as synthetic fibers that do not have heat fusibility. In consideration of fluffing and the like, synthetic fibers are preferable to natural fibers, but are not particularly limited. The heat-shrinkable fiber and the heat-fusible fiber are not particularly limited in material and physical properties as long as they have a function of shrinking and bonding by applying heat, but the heat-shrinkable fiber has a dry heat shrinkage (SHD) of 20 %, And the melting point of the heat-sealing fiber is preferably as low as possible in consideration of the case where the base material is resin. Incidentally, in the case of fibers having a dry heat shrinkage ratio (SHD) of less than 20%, there is a problem of poor adhesion to the base material. In such a case, there is a problem that adhesion to the resin is difficult, which is not preferable. Examples of the construction method of the cloth body include a woven fabric, a knitted fabric, and a braid. Examples of weaving methods include plain weave, twill weave, satin weave, and bag weave. Examples of knitting methods include warp knitting, weft knitting, and circular knitting. Examples of braids include flat braids and round braids. When bonding a flat cloth body and a cylindrical substrate, there is a problem that a joint is made, and the knitted pattern does not match at this joint, and the decorative properties such as the joint fraying deteriorate, When used as a decoration for the shaft body and applicator container, a cloth in a cylindrical shape is preferable.
汚れ防止および布の発色向上の目的で布上からコーティング層を形成しても良い。材質は、アクリル系、メラミン系、ウレタン系、フッ素系、シリコン系などが挙げられる。防汚性、耐久性の観点からフッ素樹脂系が好ましいが、特に限定されるものではない。また、意匠性を向上させるためコーティング層を着色してもかまわない。コーティング層の着色は、市販の顔料・染料を接着剤に混ぜることにより行うことが出来る。 A coating layer may be formed on the cloth for the purpose of preventing dirt and improving the color of the cloth. Examples of the material include acrylic, melamine, urethane, fluorine, and silicon. From the viewpoint of antifouling properties and durability, a fluororesin system is preferable, but it is not particularly limited. Further, the coating layer may be colored in order to improve design properties. The coating layer can be colored by mixing a commercially available pigment / dye into the adhesive.
(実施例1)
以下、本発明の実施例により、具体的に説明する。
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株))を用いた。筒状の布は、図1に示すように熱融着繊維とポリエステルを使用し、ポリエステルの糸束を2本浮かせて1本沈ませるように組み、熱融着繊維の糸束がなるべく基体側へ露出するように(織物で言うなら綾織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 1)
The present invention will be specifically described below with reference to examples.
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. Polyester was used as the synthetic fiber, and a heat-bonding fiber Joiner H type (Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealing fiber. As shown in FIG. 1, the cylindrical cloth uses heat-bonding fibers and polyester, assembles two polyester yarn bundles so that they float and sink one, and the heat-bonding fiber yarn bundles are as close to the substrate as possible. The round punched product was prepared so as to have the same diameter as that of the substrate so as to be exposed to the surface (in the case of a woven fabric, a twill weave). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例2)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)を用いた。筒状の布は、図1に示すように熱融着繊維とポリエステルを使用し、ポリエステルの糸束を2本浮かせて1本沈ませるように組み、熱融着繊維の糸束がなるべく基体側へ露出するように(織物で言うなら綾織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 2)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, and a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealing fiber. As shown in FIG. 1, the cylindrical cloth uses heat-bonding fibers and polyester, assembles two polyester yarn bundles so that they float and sink one, and the heat-bonding fiber yarn bundles are as close to the substrate as possible. The round punched product was prepared so as to have the same diameter as that of the substrate so as to be exposed to the surface (in the case of a woven fabric, a twill weave). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例3)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)を用いた。筒状の布は、図2に示すように熱融着繊維とポリエステルを使用し、ポリエステルの糸束を3本浮かせて1本沈ませるように組み、熱融着繊維の糸束がなるべく基体側へ露出するように(織物で言うなら綾織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 3)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, and a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealing fiber. As shown in FIG. 2, the cylindrical cloth uses heat-bonding fibers and polyester, and is assembled so that three polyester yarn bundles are floated and one is sunk. The round punched product was prepared so as to have the same diameter as that of the substrate so as to be exposed to the surface (in the case of a woven fabric, a twill weave). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例4)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)を用いた。筒状の布は、図3に示すように熱融着繊維とポリエステルを使用し、ポリエステルの糸束を4本浮かせて1本沈ませるように組み、熱融着繊維の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
Example 4
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, and a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealing fiber. As shown in FIG. 3, the tubular fabric uses heat-bonded fibers and polyester, and is assembled so that four polyester yarn bundles float and sink one, and the heat-bonded fiber yarn bundles are as close to the substrate side as possible. The round punched product was made to have almost the same diameter as the above-mentioned substrate so that it was exposed to the surface (in the case of woven fabric, the procedure of satin weaving). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例5)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)を用いた。筒状の布は、図3に示すように熱融着繊維とポリエステルを使用し、ポリエステルの糸束を4本浮かせて1本沈ませるように組み、熱融着繊維とポリエステルの糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 5)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, and a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealing fiber. As shown in FIG. 3, the cylindrical cloth uses heat-bonding fibers and polyester, and assembles four polyester yarn bundles so that one floats and sinks one, and heat-bonding fibers and polyester yarn bundles are as much as possible. A round punched product was made to have substantially the same diameter as that of the substrate so as to be exposed to the substrate side (in the case of woven fabric, the procedure of satin weave). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例6)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、図3に示すように熱融着繊維と熱収縮繊維とポリエステルを使用し、ポリエステルの糸束を4本浮かせて1本沈ませるように組み、熱融着繊維と熱収縮繊維の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 6)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex, and a polyester fiber (manufactured by Toyobo) as the heat-shrinkable fiber. As shown in FIG. 3, the cylindrical cloth uses heat-bonded fibers, heat-shrinkable fibers, and polyester. As shown in FIG. In order to expose the fiber bundle as much as possible to the substrate side (in the case of a woven fabric, the procedure of satin weave), a round braided product was produced with substantially the same diameter as the substrate. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例7)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)を用いた。筒状の布は、図3に示すように熱融着繊維と木綿糸を使用し、木綿糸の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 7)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. The natural fiber used was cotton thread, and the heat-sealable fiber was a heat-sealable fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex. As shown in FIG. 3, the cylindrical cloth uses heat-bonding fibers and cotton yarn, and assembles so that four yarn bundles of cotton yarn are floated and one is sunk. A round punched product was made to have substantially the same diameter as that of the substrate so as to be exposed to the substrate side (in the case of woven fabric, the procedure of satin weave). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例8)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)を用いた。筒状の布は、図3に示すように熱融着繊維と木綿糸を使用し、木綿糸の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維と木綿糸の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 8)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. The natural fiber used was cotton thread, and the heat-sealable fiber was a heat-sealable fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex. As shown in FIG. 3, the cylindrical cloth uses heat-bonding fibers and cotton yarns, and assembles four cotton yarn bundles so that they float and sink one, and heat-bonding fibers and cotton yarns. In order to expose the bundle as much as possible to the substrate side (in the case of woven fabric, the procedure of satin weaving), a round punched product was prepared with the same diameter as that of the substrate. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例9)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、図3に示すように熱融着繊維と熱収縮繊維と木綿糸を使用し、木綿糸の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維と熱収縮繊維の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
Example 9
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Cotton yarn was used as the natural fiber, heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealable fiber, and polyester-based (manufactured by Toyobo) as the heat-shrinkable fiber. As shown in FIG. 3, the cylindrical cloth uses heat-bonding fibers, heat-shrinkable fibers, and cotton yarn, and assembles so that four yarn bundles of cotton yarn float and sink one, A round punched product was made to have the same diameter as that of the base so that the heat-shrinkable fiber bundle was exposed to the base as much as possible (in the case of woven fabric, the procedure of satin weave). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例10)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)を用いた。筒状の布は、図3に示すように熱融着繊維とポリエステル、木綿糸を使用し、ポリエステルと木綿糸の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 10)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. The natural fiber was cotton yarn, the synthetic fiber was polyester, and the heat fusion fiber was a heat fusion fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex. As shown in FIG. 3, the cylindrical cloth uses heat-bonding fibers, polyester, and cotton yarn, and assembles so that four yarn bundles of polyester and cotton yarn float and sink one, In order to expose the yarn bundle to the substrate side as much as possible (in the case of woven fabric, the procedure of satin weaving), a round punched product was produced with substantially the same diameter as the substrate. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例11)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)を用いた。筒状の布は、図3に示すように熱融着繊維とポリエステル、木綿糸を使用し、ポリエステルと木綿糸の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維とポリエステルの糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 11)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. The natural fiber was cotton yarn, the synthetic fiber was polyester, and the heat fusion fiber was a heat fusion fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex. As shown in FIG. 3, the cylindrical cloth uses heat-bonding fibers, polyester, and cotton yarn, and assembles so that four yarn bundles of polyester and cotton yarn float and sink one, In order to expose the polyester yarn bundle to the substrate side as much as possible (in the case of woven fabric, the procedure of satin weaving), a round punched product was produced with substantially the same diameter as the substrate. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例12)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)を用いた。筒状の布は、図3に示すように熱融着繊維とポリエステル、木綿糸を使用し、ポリエステルと木綿糸の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維と木綿糸の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 12)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. The natural fiber was cotton yarn, the synthetic fiber was polyester, and the heat fusion fiber was a heat fusion fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex. As shown in FIG. 3, the cylindrical cloth uses heat-bonding fibers, polyester, and cotton yarn, and assembles so that four yarn bundles of polyester and cotton yarn float and sink one, A round punched product was made to have substantially the same diameter as that of the substrate so that the yarn bundle of cotton yarn was exposed to the substrate side as much as possible (in the case of woven fabric, the procedure of satin weaving). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例13)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、図3に示すように熱融着繊維と熱収縮繊維、ポリエステル、木綿糸を使用し、ポリエステルと木綿糸の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維と熱収縮繊維の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 13)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Natural yarn is cotton yarn, synthetic fiber is polyester, heat-sealing fiber is heat-bonding fiber Joiner H type (Fujibow Co., Ltd.) with a yarn diameter of 56 dtex, and heat-shrinkable fiber is polyester-based (manufactured by Toyobo) It was. As shown in Fig. 3, the tubular fabric is made of heat-bonded fibers, heat-shrinkable fibers, polyester, and cotton yarn. A round punched product was prepared to have the same diameter as that of the substrate so that the yarn bundle of the fusion fiber and the heat-shrinkable fiber was exposed to the substrate side as much as possible (in the case of a woven fabric, the procedure of satin weave). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例14)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、図3に示すように熱融着繊維と熱収縮繊維、ポリエステルを使用し、ポリエステルと熱収縮繊維の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 14)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex, and a polyester fiber (manufactured by Toyobo) as the heat-shrinkable fiber. As shown in FIG. 3, the cylindrical cloth uses heat-bonding fibers, heat-shrinkable fibers, and polyester, and assembles so that four yarn bundles of polyester and heat-shrinkable fibers float and sink one, and heat-bonded. In order to expose the fiber bundle as much as possible to the substrate side (in the case of a woven fabric, the procedure of satin weave), a round braided product was produced with substantially the same diameter as the substrate. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例15)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、図3に示すように熱融着繊維と熱収縮繊維、ポリエステルを使用し、ポリエステルと熱収縮繊維の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維とポリエステルの糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 15)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex, and a polyester fiber (manufactured by Toyobo) as the heat-shrinkable fiber. As shown in FIG. 3, the cylindrical cloth uses heat-bonding fibers, heat-shrinkable fibers, and polyester, and assembles so that four yarn bundles of polyester and heat-shrinkable fibers float and sink one, and heat-bonded. A round punched product was made to have substantially the same diameter as the base so that the yarn bundle of fibers and polyester was exposed to the base side as much as possible (in the case of woven fabric, the procedure of satin weave). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例16)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、図3に示すように熱融着繊維と熱収縮繊維、ポリエステルを使用し、ポリエステルと熱収縮繊維の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維と熱収縮繊維の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 16)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex, and a polyester fiber (manufactured by Toyobo) as the heat-shrinkable fiber. As shown in FIG. 3, the cylindrical cloth uses heat-bonding fibers, heat-shrinkable fibers, and polyester, and assembles so that four yarn bundles of polyester and heat-shrinkable fibers float and sink one, and heat-bonded. A round punched product was prepared to have the same diameter as that of the substrate so that the yarn bundle of the fibers and the heat-shrinkable fibers was exposed to the substrate side as much as possible (in the case of woven fabric, the procedure of satin weave). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例17)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、図3に示すように熱融着繊維と熱収縮繊維、木綿糸を使用し、木綿糸と熱収縮繊維の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 17)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Cotton yarn was used as the natural fiber, heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealable fiber, and polyester-based (manufactured by Toyobo) as the heat-shrinkable fiber. As shown in FIG. 3, the cylindrical cloth is made of heat-bonded fibers, heat-shrinkable fibers, and cotton yarn, and is assembled so that four yarn bundles of cotton yarn and heat-shrinkable fibers float and sink one. A round punched product was prepared to have the same diameter as that of the substrate so that the yarn bundle of the fused fiber was exposed to the substrate side as much as possible (in the case of woven fabric, the procedure of satin weave). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例18)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、図3に示すように熱融着繊維と熱収縮繊維、木綿糸を使用し、木綿糸と熱収縮繊維の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維と木綿糸の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 18)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Cotton yarn was used as the natural fiber, heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealable fiber, and polyester-based (manufactured by Toyobo) as the heat-shrinkable fiber. As shown in FIG. 3, the cylindrical cloth is made of heat-bonded fibers, heat-shrinkable fibers, and cotton yarn, and is assembled so that four yarn bundles of cotton yarn and heat-shrinkable fibers float and sink one. A round punched product was made to have the same diameter as that of the substrate so that the yarn bundle of the fused fiber and the cotton yarn was exposed to the substrate side as much as possible (in the case of woven fabric, the procedure of satin weave). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例19)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、図3に示すように熱融着繊維と熱収縮繊維、木綿糸を使用し、木綿糸と熱収縮繊維の糸束を4本浮かせて1本沈ませるように組み、熱融着繊維と熱収縮繊維の糸束がなるべく基体側へ露出するように(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 19)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. The natural fiber was cotton yarn, the heat-sealing fiber was a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex, and the heat-shrinkable fiber was polyester (Toyobo). As shown in FIG. 3, the cylindrical cloth is made of heat-bonded fibers, heat-shrinkable fibers, and cotton yarn, and is assembled so that four yarn bundles of cotton yarn and heat-shrinkable fibers float and sink one. A round punched product was prepared to have the same diameter as that of the substrate so that the yarn bundle of the fusion fiber and the heat-shrinkable fiber was exposed to the substrate side as much as possible (in the case of a woven fabric, the procedure of satin weave). The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例20)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)を用いた。筒状の布は、丸編み(両面編み)により、表面はポリエステル、裏面は熱融着繊維によって構成されるよう上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 20)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, and a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealing fiber. The cylindrical cloth was produced by circular knitting (double-sided knitting) so that the surface thereof was made of polyester and the back surface was made of heat-sealed fibers so as to have the same diameter as that of the substrate. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例21)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)を用いた。筒状の布は、丸編み(両面編み)により、表面は木綿糸、裏面は熱融着繊維によって構成されるよう上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 21)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, and a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealing fiber. The cylindrical cloth was produced by circular knitting (double-sided knitting) so that the front surface was made of cotton yarn and the back surface was made of heat-bonded fibers so as to have the same diameter as that of the substrate. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例22)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)を用いた。筒状の布は、丸編み(両面編み)により、表面はポリエステルと木綿糸、裏面は熱融着繊維によって構成されるよう上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 22)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. The natural fiber was cotton yarn, the synthetic fiber was polyester, and the heat fusion fiber was a heat fusion fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex. The cylindrical cloth was produced by circular knitting (double-sided knitting), with the front surface being made of polyester and cotton yarn, and the back surface being made of heat-sealing fibers so as to have substantially the same diameter as the substrate. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例23)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、丸編み(両面編み)により、表面はポリエステルと熱収縮繊維、裏面は熱融着繊維によって構成されるよう上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 23)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex, and a polyester fiber (manufactured by Toyobo) as the heat-shrinkable fiber. The cylindrical cloth was fabricated by circular knitting (double-sided knitting) so that the surface was made of polyester and heat-shrinkable fibers, and the back surface was made of heat-bonded fibers so as to have the same diameter as that of the substrate. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例24)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、丸編み(両面編み)により、表面は木綿糸と熱収縮繊維、裏面は熱融着繊維によって構成されるよう上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 24)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Cotton yarn was used as the natural fiber, heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealable fiber, and polyester-based (manufactured by Toyobo) as the heat-shrinkable fiber. The cylindrical cloth was produced by circular knitting (double-sided knitting) so that the surface was made of cotton yarn and heat-shrinkable fibers, and the back surface was made of heat-bonded fibers so as to have substantially the same diameter as the base. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例25)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、丸編み(両面編み)により、表面はポリエステル、裏面は熱融着繊維と熱収縮繊維によって構成されるよう上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 25)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex, and a polyester fiber (manufactured by Toyobo) as the heat-shrinkable fiber. The cylindrical cloth was produced by circular knitting (double-sided knitting) so that the front surface was made of polyester and the back surface was made of heat-sealing fibers and heat-shrinkable fibers so as to have substantially the same diameter as the base. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例26)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、丸編み(両面編み)により、表面は木綿糸、裏面は熱融着繊維と熱収縮繊維によって構成されるよう上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 26)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Cotton yarn was used as the natural fiber, heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealable fiber, and polyester-based (manufactured by Toyobo) as the heat-shrinkable fiber. The cylindrical cloth was produced by circular knitting (double-sided knitting) so that the front surface was made of cotton yarn and the back surface was made of heat-sealing fibers and heat-shrinkable fibers so as to have substantially the same diameter as the substrate. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例27)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、丸編み(両面編み)により、表面はポリエステルと木綿糸、裏面は熱融着繊維と熱収縮繊維によって構成されるよう上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 27)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Natural yarn is cotton yarn, synthetic fiber is polyester, heat-sealing fiber is heat-bonded fiber Joiner H type (Fujibow Co., Ltd.) with a diameter of 56 dtex, and heat-shrinkable fiber is polyester-based (manufactured by Toyobo) It was. The cylindrical cloth was produced by circular knitting (double-sided knitting) so that the front surface was made of polyester and cotton yarn, and the back surface was made of heat-sealing fibers and heat-shrinkable fibers. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例28)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、丸編み(両面編み)により、表面はポリエステルと熱収縮繊維、裏面は熱融着繊維と熱収縮繊維によって構成されるよう上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 28)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Polyester was used as the synthetic fiber, a heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex, and a polyester fiber (manufactured by Toyobo) as the heat-shrinkable fiber. The cylindrical cloth was produced by circular knitting (double-sided knitting) so that the surface was made of polyester and heat-shrinkable fibers, and the back surface was made of heat-sealing fibers and heat-shrinkable fibers so as to have substantially the same diameter as the base. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(実施例29)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。シンナーにて50%に調整した白塗料(ハイメラアル、武蔵塗料(株)製)をスプレーにて基体表面に塗布し、150℃、20分乾燥した。天然繊維は木綿糸、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株)製)、熱収縮繊維はポリエステル系(東洋紡績製)を用いた。筒状の布は、丸編み(両面編み)により、表面は木綿糸と熱収縮繊維、裏面は熱融着繊維と熱収縮繊維によって構成されるよう上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
布上からクロスカットした後、粘着テープを用いて剥離試験を行ったところ、素材からの剥離発生はなく良好な結果が得られた(表1)。
(Example 29)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. A white paint (Hymeraal, manufactured by Musashi Paint Co., Ltd.) adjusted to 50% with thinner was applied to the substrate surface by spraying and dried at 150 ° C. for 20 minutes. Cotton yarn was used as the natural fiber, heat-bonding fiber Joiner H type (manufactured by Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealable fiber, and polyester-based (manufactured by Toyobo) as the heat-shrinkable fiber. The cylindrical cloth was produced by circular knitting (double-sided knitting) so that the surface was composed of cotton yarn and heat-shrinkable fibers, and the back surface was made of heat-bonded fibers and heat-shrinkable fibers so as to have substantially the same diameter as the substrate. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
After cross-cutting from the cloth, a peel test was performed using an adhesive tape. As a result, no peeling occurred from the material, and good results were obtained (Table 1).
(比較例1)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株))を用いた。筒状の布は、熱融着繊維とポリエステルを使用し、ポリエステルの糸を1本浮かせて1本沈ませるように組み(織物で言うなら平織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
基体と布体は接着はしたが、その強度は実施例1と比較して強度不足であった(表1)。
(Comparative Example 1)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. Polyester was used as the synthetic fiber, and a heat-bonding fiber Joiner H type (Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealing fiber. The cylindrical cloth uses heat-bonding fibers and polyester, and assembles so that one polyester yarn floats and sinks one (in the case of woven fabrics, the method of plain weaving). The same diameter was produced. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
The substrate and the fabric were bonded, but the strength was insufficient compared to Example 1 (Table 1).
(比較例2)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株))を用いた。筒状の布は、熱融着繊維とポリエステルを使用し、ポリエステルの糸を1本浮かせて2本沈ませるように組み(織物で言うなら綾織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
基体と布体は接着はしたが、その強度は実施例2と比較して強度不足であり、テープにより剥離してしまった(表1)。
(Comparative Example 2)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. Polyester was used as the synthetic fiber, and a heat-bonding fiber Joiner H type (Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealing fiber. The cylindrical cloth uses heat-bonding fibers and polyester, and assembles so that two polyester yarns float and sink two (in the case of woven fabric, the twill weave). The same diameter was produced. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
Although the substrate and the fabric were bonded, the strength was insufficient compared to Example 2 and the tape was peeled off (Table 1).
(比較例3)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株))を用いた。筒状の布は、熱融着繊維とポリエステルを使用し、ポリエステルの糸を1本浮かせて3本沈ませるように組み(織物で言うなら綾織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
基体と布体は接着はしたが、その強度は実施例3と比較して強度不足であり、テープにより剥離してしまった(表1)。
(Comparative Example 3)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. Polyester was used as the synthetic fiber, and a heat-bonding fiber Joiner H type (Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealing fiber. The cylindrical cloth uses heat-bonding fibers and polyester, and assembles so that three polyester yarns are floated and three are sunk (in the case of woven fabric, the twill weave). The same diameter was produced. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
Although the substrate and the fabric were bonded, the strength was insufficient compared to Example 3, and the substrate was peeled off by the tape (Table 1).
(比較例4)
基体として、プレス加工により得られた直径8.5mm、長さ66.8mm、厚さ0.3mmの円筒状真鍮軸を用い、その表面を電解脱脂により、洗浄した。合成繊維はポリエステル、熱融着繊維は、糸径56デシテックスの熱融着繊維ジョイナーHタイプ(フジボウ(株))を用いた。筒状の布は、熱融着繊維とポリエステルを使用し、ポリエステルの糸を1本浮かせて4本沈ませるように組み(織物で言うなら朱子織の要領)、丸打組物を上記基体とほぼ同径に作製した。作製した筒状布体の中に上記基体を挿入し、これを160℃の焼付乾燥炉内に5分間放置し、基体表面に布体を被着した。
基体と布体は接着はしたが、その強度は実施例1と比較して強度不足であり、テープにより剥離してしまった(表1)。
(Comparative Example 4)
A cylindrical brass shaft having a diameter of 8.5 mm, a length of 66.8 mm, and a thickness of 0.3 mm obtained by press working was used as a substrate, and the surface was cleaned by electrolytic degreasing. Polyester was used as the synthetic fiber, and a heat-bonding fiber Joiner H type (Fujibow Co., Ltd.) having a yarn diameter of 56 dtex was used as the heat-sealing fiber. The cylindrical cloth is made of heat-bonding fiber and polyester, and is assembled so that four polyester yarns float and sink four (in the case of woven fabric, the procedure of satin weaving) Produced to approximately the same diameter. The substrate was inserted into the produced cylindrical cloth body, which was left in a baking oven at 160 ° C. for 5 minutes, and the cloth body was adhered to the surface of the substrate.
Although the substrate and the fabric were bonded, the strength was insufficient compared to Example 1 and the tape was peeled off (Table 1).
本発明は、基体と布体とを一体化した装飾体に関するものである。その装飾体の例としては、シャープペンシルやボールペンなどの筆記具、化粧品、飲料などの容器類、台所用品など多岐にわたるものである。 The present invention relates to a decorative body in which a base and a cloth body are integrated. Examples of the decorative body include a wide variety of writing instruments such as mechanical pencils and ballpoint pens, containers such as cosmetics and beverages, and kitchen utensils.
A 表面に出る比率の多い繊維
B 裏面に出る比率の多い繊維
A Fiber with a high ratio on the surface B Fiber with a high ratio on the back
Claims (5)
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|---|---|---|---|
| JP2006297016A JP2008114382A (en) | 2006-10-31 | 2006-10-31 | Decorative body |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP2006297016A JP2008114382A (en) | 2006-10-31 | 2006-10-31 | Decorative body |
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| JP2008114382A true JP2008114382A (en) | 2008-05-22 |
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| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JP2014514194A (en) * | 2011-05-04 | 2014-06-19 | ナイキ インターナショナル リミテッド | Composite structure, footwear and method of manufacturing composite elements |
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Cited By (8)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JP2014514194A (en) * | 2011-05-04 | 2014-06-19 | ナイキ インターナショナル リミテッド | Composite structure, footwear and method of manufacturing composite elements |
| KR101549322B1 (en) | 2011-05-04 | 2015-09-01 | 나이키 이노베이트 씨.브이. | Knit component bonding |
| US9150986B2 (en) | 2011-05-04 | 2015-10-06 | Nike, Inc. | Knit component bonding |
| US10094053B2 (en) | 2011-05-04 | 2018-10-09 | Nike, Inc. | Knit component bonding |
| US11155942B2 (en) | 2011-05-04 | 2021-10-26 | Nike, Inc. | Knit component bonding |
| US11155943B2 (en) | 2011-05-04 | 2021-10-26 | Nike, Inc. | Knit component bonding |
| US11203823B2 (en) | 2011-05-04 | 2021-12-21 | Nike, Inc. | Knit component bonding |
| US11692289B2 (en) | 2011-05-04 | 2023-07-04 | Nike, Inc. | Knit component bonding |
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