JP5538080B2 - Fiber liquid supply core and method for manufacturing the fiber liquid supply core - Google Patents

Fiber liquid supply core and method for manufacturing the fiber liquid supply core Download PDF

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JP5538080B2
JP5538080B2 JP2010135342A JP2010135342A JP5538080B2 JP 5538080 B2 JP5538080 B2 JP 5538080B2 JP 2010135342 A JP2010135342 A JP 2010135342A JP 2010135342 A JP2010135342 A JP 2010135342A JP 5538080 B2 JP5538080 B2 JP 5538080B2
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fiber
melting point
liquid supply
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supply core
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JP2011020443A (en
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清志 河内
大祐 渡邊
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Teibow Co Ltd
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Description

本発明は、例えば、ペン先や、芳香剤容器の芯材等、毛細管現象を利用して液体を供給するのに有用な液体供給芯に関係しており、とりわけ合成繊維を加工した繊維製液体供給芯及び該繊維製液体供給芯の製造方法に関するものである。   The present invention relates to a liquid supply core useful for supplying a liquid by utilizing a capillary phenomenon, such as a nib and a core material of a fragrance container. The present invention relates to a supply core and a method for producing the fiber liquid supply core.

繊維製液体供給芯には羊毛、アクリル繊維、ナイロン繊維、ポリエステル繊維などの繊維束を成形ダイスに通し加熱して所要の断面形状・寸法に成形し、次にメラミン、エポキシ、フェノール等の熱硬化樹脂バインダー液に浸漬せしめた後、乾燥装置で乾燥と一次硬化とを行い、さらに加熱装置に通して樹脂硬化せしめる製造方法により得られたもの(例えば、特許文献1)がある。
しかしながら、前記特許文献1に開示されたポリエステル等の合成繊維にメラミン等の熱硬化性樹脂を含浸させた繊維製液体供給芯をペン先としたものでは、熱硬化樹脂中のモノマーの未反応物がインクとの化学反応をし、目詰まり等を引き起こし、筆記時のインクかすれを発生させる場合があった。
また、前記繊維製液体供給芯では、繊維束に対する熱硬化性樹脂の付着が均等に行なわれ難く、ペン先またはペン先部までインクを運ぶ液体供給芯とした際にインク流出、インク供給を行なう毛管現象が不均一になり、インキ流出量がばらつくと言う欠点もあった。
さらに、熱硬化樹脂を繊維束に含浸させる際に樹脂を有機溶剤で希釈する必要があり、その有機溶剤は有害である事が多いため溶剤を乾燥回収するための装置を設置しなければならず、多くの設備投資費用が必要となり、コスト高を招く問題や、労働環境を悪化させる問題があった。
加えて、熱硬化性樹脂を含浸させた繊維集合体からなる繊維製液体供給芯は熱硬化樹脂と熱可塑性樹脂の混合物であり、硬化後に不可逆となるものである為、リサイクル不可能であった。
A fiber bundle of fiber, such as wool, acrylic fiber, nylon fiber, and polyester fiber, is heated through a forming die to form the required cross-sectional shape and dimensions, followed by thermosetting melamine, epoxy, phenol, etc. There is one obtained by a manufacturing method (for example, Patent Document 1) in which the resin binder liquid is dipped in the resin binder liquid, dried and primary cured with a drying apparatus, and further cured through a heating apparatus.
However, in the case of using a fiber liquid supply core in which a synthetic fiber such as polyester disclosed in Patent Document 1 is impregnated with a thermosetting resin such as melamine as a pen tip, an unreacted product of the monomer in the thermosetting resin May chemically react with the ink, causing clogging and the like, and may cause ink fading during writing.
Further, in the fiber liquid supply core, it is difficult for the thermosetting resin to be evenly adhered to the fiber bundle. When the liquid supply core transports ink to the pen tip or the pen tip portion, ink outflow and ink supply are performed. There was also a drawback that the capillary phenomenon became non-uniform and the ink outflow amount varied.
Furthermore, when impregnating the fiber bundle with the thermosetting resin, it is necessary to dilute the resin with an organic solvent, and since the organic solvent is often harmful, an apparatus for drying and recovering the solvent must be installed. However, a lot of capital investment costs were required, and there were problems that caused high costs and worsened the working environment.
In addition, a fiber liquid supply core made of a fiber assembly impregnated with a thermosetting resin is a mixture of a thermosetting resin and a thermoplastic resin, and becomes irreversible after curing, so it cannot be recycled. .

これに対し、低融点重合体を含む一種類の熱融着性複合繊維を多数束ねて繊維集合体を構成し、この繊維集合体を、前記低融点重合体の融点以上に加熱して、前記低融点重合体を溶融結着させる製造方法により得られた筆記具用ペン芯(例えば、特許文献2)がある。
この従来技術は、より具体的に説明すれば、例えば、高融点の重合体を同芯状に低融点の重合体で被覆した鞘芯型複合繊維や(特許文献2の第2図参照)、一半部が高融点の重合体で他半部が低融点の重合体である接合型複合繊維(特許文献2の第3図参照)、高融点の重合体と低融点の重合体の層を交互に配置した多層型複合繊維(特許文献2の第4図参照)等、一本の繊維について融点の異なる部分を形成した複合繊維のみが用いられている。
しかしながら、前記従来技術(特許文献2)のように、複合繊維のみを使用する製造方法では、繊維製液体供給芯の外径不良発生等と言った成形不具合が発生するばかりでなく、使用する複合繊維によって溶融結着の役割を成すバインダー部分(前記低融点の重合体)の割合が自ずと規定されてしまい、硬さや空隙の割合である気孔率のコントロールをし難いと言った問題点がある。
また、熱融着繊維として使用可能な合成繊維は市場に流通している熱融着性複合繊維のみに限定されると言った問題点や、ペン先製造工程である研磨工程においてバインダー部分が溶け、研磨面に樹脂の溶融による目詰まりが発生し、ペン先として安定したインクフローを得られない、またはインクフローが少なくなる等の問題がある。
特公昭53−16736号公報 特公昭54−688号公報
On the other hand, a fiber assembly is formed by bundling a large number of one kind of heat-fusible conjugate fibers including a low-melting polymer, and the fiber assembly is heated to a temperature equal to or higher than the melting point of the low-melting polymer, There is a pen core for a writing instrument (for example, Patent Document 2) obtained by a production method in which a low melting point polymer is melt-bound.
More specifically, for example, this conventional technique is a sheath-core type composite fiber in which a high melting point polymer is coated with a low melting point polymer concentrically (see FIG. 2 of Patent Document 2), Bonded conjugate fiber (see Fig. 3 of Patent Document 2), one half of which is a high-melting polymer and the other half is a low-melting polymer, alternating layers of high-melting polymer and low-melting polymer Only a composite fiber in which a part having a different melting point is formed for one fiber, such as a multilayer type composite fiber (see FIG. 4 of Patent Document 2) arranged in the above is used.
However, as in the prior art (Patent Document 2), in the manufacturing method using only the composite fiber, not only the molding defect such as the outer diameter defect of the fiber liquid supply core occurs but also the composite used. There is a problem that it is difficult to control the porosity, which is the ratio of hardness and voids, because the ratio of the binder portion (the low melting point polymer) that plays a role of fusion bonding with fibers is naturally defined.
In addition, the synthetic fiber that can be used as a heat-bonding fiber is limited to only the heat-fusible composite fiber that is distributed in the market, and the binder part melts in the polishing process that is a nib manufacturing process. There is a problem that clogging due to melting of the resin occurs on the polished surface, and a stable ink flow cannot be obtained as a pen tip, or the ink flow is reduced.
Japanese Patent Publication No.53-16736 Japanese Patent Publication No.54-688

本発明が解決しようとする課題は第一には、熱硬化性樹脂を硬化剤として使用する事無く、気孔を確保して液体を所望のスピードで供給可能な筆記具用ペン先として有用な繊維製液体供給芯を提供する事にある。第二には硬度や気孔率の調整が容易である幅広い要求品質に応えられる繊維製液体供給芯を提供する事にある。そして、第三には前記繊維製液体供給芯を研磨加工した際に繊維の溶融等により研磨面の気孔を塞ぐことの無い、ペン先として安定したインクフローが得られる、研磨に耐え得る繊維製液体供給芯及び該繊維製液体供給芯の製造方法を提供する事にある。   The problem to be solved by the present invention is firstly made of a fiber useful as a pen tip for a writing instrument capable of securing pores and supplying a liquid at a desired speed without using a thermosetting resin as a curing agent. To provide a liquid supply core. The second is to provide a fiber-made liquid supply core that can meet a wide range of required qualities, with easy adjustment of hardness and porosity. And thirdly, when the fiber liquid supply core is polished, the pores of the polishing surface are not blocked by melting of the fiber, etc., and a stable ink flow is obtained as a nib, which can withstand polishing. The object is to provide a liquid supply core and a method for producing the fiber liquid supply core.

このような目的を達成するために、本発明に係る技術的手段は、少なくとも以下の構成要件を具備する。   In order to achieve such an object, the technical means according to the present invention includes at least the following constituent elements.

本発明に係る繊維製液体供給芯は、主繊維と、少なくとも外表面の一部又は全部に前記主繊維よりも融点の低い低融点部を有する熱融着繊維と、を含む二種類以上の繊維を多数混合し長手方向にそろえて束ね圧縮してなる繊維製液体供給芯であって、繊維間に連続気孔を有する状態で繊維間を熱溶融した際の前記低融点部により結着し、繊維方向を長手方向へ向けた中実棒状に形成されていることを特徴とする。   The fiber liquid supply core according to the present invention includes two or more kinds of fibers including a main fiber and a heat-sealing fiber having a low melting point part having a melting point lower than that of the main fiber on at least part or all of the outer surface. Is a fiber liquid supply core formed by mixing a large number of fibers and bundling and compressing them in the longitudinal direction, and is bound by the low melting point when the fibers are thermally melted with continuous pores between the fibers. It is characterized by being formed in the shape of a solid bar whose direction is directed in the longitudinal direction.

また、本発明に係る繊維製液体供給芯の製造方法では、前記主繊維と前記熱融着繊維を含む二種類以上の繊維を多数混合し長手方向にそろえて束ね混合繊維束を構成し、この混合繊維束を、束ね合わせ方向へ圧縮するとともに、前記熱融着繊維の低融点部の融点よりも高く且つ前記主繊維の融点よりも低い温度で加熱することで、前記低融点部を熱溶融し、その熱溶融した低融点部により繊維間を結着するようにしたことを特徴とする。   Further, in the method for manufacturing a fiber liquid supply core according to the present invention, a plurality of two or more kinds of fibers including the main fiber and the heat-fusible fiber are mixed and aligned in the longitudinal direction to form a mixed fiber bundle. The mixed fiber bundle is compressed in the bundling direction, and heated at a temperature higher than the melting point of the low melting point portion of the heat-fusible fiber and lower than the melting point of the main fiber, thereby thermally melting the low melting point portion. In addition, the fibers are bound by the heat-melted low melting point portion.

また、好ましい技術的手段では、以下の構成要件を具備する。
(1)いずれもが融点150℃以上でかつ融点の差が20℃以上である2種類以上の合成繊維を混合してなる繊維束を圧縮しつつ加熱溶融結着された連続気孔を有する繊維製液体供給体。
(2)前記繊維製液体供給体は1〜20デニールの熱融着繊維と、前記熱融着繊維の融点では溶融しない1〜20デニールの繊維とが混合され、前記熱融着繊維を溶融させて繊維間を部分的に結着した熱溶融結着加工体である事を特徴とする上記第(1)項記載の繊維製液体供給体。
(3)前記繊維製液体供給体の熱融着繊維は一つの融点のみを有する合成繊維、もしくは一部が低融点である重合体を含む複合繊維である事を特徴とする上記第(2)項記載の繊維製液体供給体。
(4)前記熱融着繊維の融点では溶融しない繊維に対する熱融着繊維の混合比率を、10/90〜90/10%の重量比率にしてある事を特徴とする上記第(3)項記載の繊維製液体供給体。
In addition, the preferred technical means includes the following constituent elements.
(1) Both are made of fibers having continuous pores that are heated and melt-bonded while compressing a fiber bundle formed by mixing two or more synthetic fibers having a melting point of 150 ° C. or higher and a difference in melting point of 20 ° C. or higher. Liquid supply body.
(2) In the fiber liquid supply body, 1 to 20 denier heat-sealing fibers and 1 to 20 denier fibers that do not melt at the melting point of the heat-sealing fibers are mixed to melt the heat-sealing fibers. The fiber liquid supply body according to the above item (1), characterized in that it is a hot melt binding processed body in which the fibers are partially bound.
(3) The above-mentioned (2), wherein the heat-fusible fiber of the fiber liquid supply body is a synthetic fiber having only one melting point or a composite fiber including a polymer having a part of a low melting point. The fiber liquid supply body according to item.
(4) Item (3) above, wherein the mixing ratio of the heat-sealing fiber to the fiber that does not melt at the melting point of the heat-sealing fiber is 10/90 to 90/10%. Fiber liquid supply body.

このような特徴を有することで本発明は以下の作用効果を奏する。
主繊維と熱融着繊維とを含む二種類以上の繊維を混合してなる構造であるため、その混合比率の調整によって、硬さの調整や気孔率の調整を容易に行うことができ、ひいては、気孔を確保して液体を所望のスピードで供給可能な筆記具用ペン先として有用であり、且つ幅広い要求品質に応えられる繊維製液体供給芯を提供することができる。
すなわち、複合繊維のみを用いた従来技術(特許文献2参照)では、例えば、同繊維密度設計で硬さ調整や気孔率の調整をする場合(換言すれば、繊維密度を変えずに硬さや気孔率の調整をしようとした場合)、複合繊維の高融点部分と低融点部分の比率を調整しなければならず、そのためには使用する複合繊維の種類を変更する必要が生じる。しかしながら、本願発明では、使用する繊維の種類を変更する必要はなく、使用する繊維の混合比率の調整によって容易に対応することができる。
By having such characteristics, the present invention has the following effects.
Since it is a structure formed by mixing two or more kinds of fibers including the main fiber and the heat-sealing fiber, the adjustment of the mixing ratio can easily adjust the hardness and the porosity, and consequently Thus, it is possible to provide a fiber liquid supply core that is useful as a pen tip for a writing instrument that can secure pores and supply a liquid at a desired speed and can meet a wide range of required qualities.
That is, in the prior art using only the composite fiber (see Patent Document 2), for example, when adjusting the hardness and porosity with the same fiber density design (in other words, the hardness and porosity without changing the fiber density) If the ratio is to be adjusted), it is necessary to adjust the ratio of the high melting point portion and the low melting point portion of the composite fiber, which requires changing the type of the composite fiber to be used. However, in this invention, it is not necessary to change the kind of fiber to be used, and it can be easily handled by adjusting the mixing ratio of the fibers to be used.

また、熱融着繊維より融点の高い主繊維となる合成繊維を10%以上混ぜて成形すれば、寸法精度改善等の成形安定化を図る事が出来、且つバインダー分となる熱融着繊維を任意の割合で変更することにより、ペン先硬度や気孔率のコントロールを容易に行うことができ、ペン先設計に自由度のある繊維製液体供給芯を提供することができる。   In addition, if 10% or more of the synthetic fiber, which is the main fiber having a higher melting point than the heat-sealing fiber, is mixed and molded, the molding stability such as improvement in dimensional accuracy can be achieved, and the heat-sealing fiber serving as the binder can be obtained. By changing the ratio at an arbitrary ratio, it is possible to easily control the nib hardness and the porosity, and it is possible to provide a fiber liquid supply core having a degree of freedom in nib design.

また、低融点部の融点が170℃以上であり、外面の少なくとも一部に研磨面が形成された発明とすれば、研磨面に樹脂の溶融による目詰まりが発生するのを防ぐことができる。
特に、主繊維と低融点部の融点のいずれもが170℃以上で、その融点差が20℃よりも大きく繊維径が1〜20デニールの2種類以上の合成繊維を用いれば、研磨性や成形性や毛細管形成の安定した筆記具用ペン先用繊維製液体供給芯を提供することができる。
Also, if the melting point of the low melting point portion is 170 ° C. or higher and the polishing surface is formed on at least a part of the outer surface, it is possible to prevent clogging due to melting of the resin on the polishing surface.
In particular, if two or more kinds of synthetic fibers having a melting point difference of more than 20 ° C. and a fiber diameter of 1 to 20 denier are used, both the main fiber and the low melting point have a melting point of 170 ° C. or higher. It is possible to provide a liquid supply core made of a fiber for a pen tip for a writing instrument, which has stable properties and capillary formation.

また、バインダー分となる熱融着繊維を複合繊維に限定せず、前記熱融着繊維の融点では溶融しない主繊維となり得る繊維よりも融点の低い単一重合体からなる合成繊維でも良いものとし、熱融着繊維に選択の幅を持たせた事により、設計に自由度のある繊維製液体供給芯を提供することができる。   In addition, the heat-sealing fiber serving as a binder is not limited to a composite fiber, and may be a synthetic fiber made of a single polymer having a lower melting point than a fiber that can be a main fiber that does not melt at the melting point of the heat-sealing fiber, By providing the heat-sealing fiber with a range of choice, it is possible to provide a fiber liquid supply core having a degree of freedom in design.

また、主繊維の太さよりも熱融着繊維の太さを細くすれば、主繊維周りの結着箇所が増えて繊維間の接着強度が上がるため、耐久性及び耐圧縮性を向上させることができ、特にペン先として用いるのに好適な繊維製液体供給芯を提供することができる。   In addition, if the thickness of the heat-sealing fiber is made thinner than the thickness of the main fiber, the number of binding sites around the main fiber is increased and the adhesion strength between the fibers is increased, so that durability and compression resistance can be improved. In particular, a fiber liquid supply core suitable for use as a nib can be provided.

また、本発明品の熱硬化樹脂を使用しない繊維製液体供給芯は有機溶剤を使用しない事となり、溶剤を乾燥回収するための装置の設置が不要となるばかりでなく、そのための多くの設備投資費用も不要となり、ひいては生産コストを下げ、有機溶剤揮発による労働環境も悪化させずに繊維製液体供給芯を提供することができる。
また、近年世界的な関心が高いリサイクル性に関しても、PET/LPETやPA66/PA6と言った同一系素材であれば、リサイクルが可能と考えられ、環境に優しいメリットのある繊維製液体供給芯を提供することができる。
In addition, the fiber liquid supply core that does not use the thermosetting resin of the present invention does not use an organic solvent, so that not only the installation of a device for drying and recovering the solvent is unnecessary, but also a lot of capital investment for that purpose. Costs can be eliminated, and as a result, production costs can be reduced, and a fiber liquid supply core can be provided without deteriorating the working environment caused by volatilization of organic solvents.
In addition, with regard to recyclability, which has become a worldwide concern in recent years, it is considered that recycling is possible with the same material such as PET / LPET and PA66 / PA6. Can be provided.

繊維製液体供給芯の一実施例を示す側面図。The side view which shows one Example of the fiber-made liquid supply cores. 繊維製液体供給芯の一実施例の拡大横断面を示す模式図。The schematic diagram which shows the expanded cross section of one Example of the fiber-made liquid supply cores. 繊維製液体供給芯の他の実施例の拡大横断面を示す模式図。The schematic diagram which shows the expanded cross section of the other Example of the fiber-made liquid supply core. 熱硬化樹脂を使用する製造方法の一例を示す模式図。The schematic diagram which shows an example of the manufacturing method which uses a thermosetting resin. 本発明品の製造方法の一例を示す模式図。The schematic diagram which shows an example of the manufacturing method of this invention goods. 本発明品の繊維製液体供給芯で作られた筆記用ペン先の一例を示す斜視図。The perspective view which shows an example of the pen point for writing made with the fiber-made liquid supply core of this invention product.

本発明について、以下具体的に説明する。   The present invention will be specifically described below.

本発明に係る繊維製液体供給芯1は、主繊維と、少なくとも外表面の一部又は全部に前記主繊維よりも融点の低い低融点部を有する熱融着繊維と、を含む2種類以上の合成繊維を混合して混合繊維束を構成し、この混合繊維束を、束ね合わせ方向へ圧縮しつつ、前記熱融着繊維の低融点部の融点よりも高く且つ前記主繊維の融点よりも低い温度で加熱することで、前記低融点部を熱溶融し、その熱溶融した低融点部により繊維間を結着するとともに、繊維間に連続気孔を形成して、所用の硬さ・気孔率・寸法に成形し、その後、指定の長さにカットする製造方法により、繊維方向を長手方向へ向けた中実棒状に形成される。   The fiber liquid supply core 1 according to the present invention includes two or more kinds of main fiber and a heat-sealing fiber having a low melting point part having a melting point lower than that of the main fiber on at least part or all of the outer surface. A synthetic fiber is mixed to form a mixed fiber bundle, and the mixed fiber bundle is compressed in the bundling direction, and is higher than the melting point of the low melting point portion of the heat-sealing fiber and lower than the melting point of the main fiber. By heating at a temperature, the low melting point portion is thermally melted, and the low melting point portion that has been melted by heat binds the fibers and forms continuous pores between the fibers. It is formed into a solid rod shape in which the fiber direction is directed in the longitudinal direction by a manufacturing method in which the fiber is formed into dimensions and then cut to a specified length.

前記主繊維は、熱融着繊維の融点では溶融しない、つまりは成形加工温度では溶融しない繊維である。
この主繊維の具体例としては、アクリル繊維、ポリエステル繊維、ナイロン繊維、ビニロン繊維、ポリアミド繊維、ポリプロピレン繊維、ポリエチレン繊維、塩化ビニル繊維、アセテート繊維、などが挙げられる。
The main fiber is a fiber that does not melt at the melting point of the heat-fusible fiber, that is, does not melt at the molding temperature.
Specific examples of the main fiber include acrylic fiber, polyester fiber, nylon fiber, vinylon fiber, polyamide fiber, polypropylene fiber, polyethylene fiber, vinyl chloride fiber, and acetate fiber.

また、前記熱融着繊維は、少なくとも外表面の一部又は全部に前記主繊維よりも融点の低い低融点部を有する繊維であり、前記低融点部が、成形加工時に溶融し、繊維製液体供給芯のバインダー繊維としての役割を果たす。
前記熱融着繊維であって、繊維全体が前記低融点部であるものの具体例としては、低融点ポリアミド繊維、低融点ポリプロピレン繊維、低融点ポリエステル繊維、低融点ポリエチレン繊維などの単一重合体からなる低融点繊維が挙げられる。
また、前記熱融着繊維であって、外表面の一部又は全部に前記主繊維よりも融点の低い低融点部を有するものの具体例としては、繊維外周部の一部が低融点ポリエステル重合体(低融点部)で残部が高融点ポリエステル重合体からなる複合繊維、繊維外周部の一部が低融点重合体である6ナイロン(低融点部)で残部が高融点重合体であるナイロン66からなる複合繊維、外周部の一部が低融点のポリブチレンテレフタレート(低融点部)で残部が高融点のポリエチレンテレフタレートからなる複合繊維、その他公知の芯鞘型や多層型などの複合重合体素材からなる複合繊維などが挙げられる。
The heat-sealing fiber is a fiber having a low melting point part having a melting point lower than that of the main fiber on at least a part or all of the outer surface, and the low melting point part melts at the time of molding processing, Serves as a binder fiber for the supply core.
Specific examples of the heat-fusible fiber, the entire fiber of which is the low-melting point portion, are composed of a single polymer such as a low-melting polyamide fiber, a low-melting polypropylene fiber, a low-melting polyester fiber, or a low-melting polyethylene fiber. A low melting point fiber is mentioned.
Further, as a specific example of the heat-fusible fiber having a low melting point part having a melting point lower than that of the main fiber on a part or all of the outer surface, a part of the outer peripheral part of the fiber is a low melting point polyester polymer. (Low melting point portion) with the remainder being a high melting point polyester polymer composite fiber, part of the fiber outer periphery is a low melting point polymer 6 nylon (low melting point portion) and the remainder is a high melting point polymer nylon 66 From composite fibers made of polybutylene terephthalate (low melting point part) with a low melting point and a high melting point polyethylene terephthalate in the outer periphery, and other known composite polymer materials such as core-sheath type and multilayer type And the like.

本発明の繊維製液体供給芯において、筆記用ペン先または液体供給芯としての有用な硬さ、気孔率、寸法等の品質を得る為には、バインダー分となる熱融着繊維の混合比率は10%〜90%が好ましく、更には前記繊維製液体供給芯の硬さ、気孔率、寸法精度等の品質バラツキの安定性と言った観点からは、熱融着繊維の混合比率は20%〜80%とするのが好ましい。また、繊維製液体供給芯をペン先形状に研磨加工する際に溶融結着樹脂分が少ないものは繊維ほぐれ、バサケが発生し、研磨加工時の形状安定性が確保されない事からも熱融着繊維を20%以上とするのが好ましい。   In the fiber liquid supply core of the present invention, in order to obtain quality such as writing pen tip or liquid supply core useful hardness, porosity, dimensions, etc., the mixing ratio of the heat-sealing fibers as the binder component is: 10% to 90% is preferable. Further, from the viewpoint of stability of quality variation such as hardness, porosity and dimensional accuracy of the fiber liquid supply core, the mixing ratio of the heat-sealing fibers is 20% to 80% is preferable. In addition, when the fiber liquid supply core is ground into a nib shape, the material with a small amount of molten binder resin will loosen the fibers and cause salmon, and heat fusion will not ensure the shape stability during polishing. The fiber is preferably 20% or more.

また、前記主繊維と前記低融点部は、研磨加工時に熱溶融した繊維によって気孔が塞がれてしまうようなことを防止する観点から、両方とも融点が170℃以上であることが好ましく、更に好ましくは、両方とも融点が180℃以上とされる。
更に、前記主繊維と前記低融点部の融点の差は、成形加工時の温度制御を容易にする観点から、20℃よりも大きいことが好ましく、より好ましくは40℃以上とされる。
The main fiber and the low melting point part preferably both have a melting point of 170 ° C. or higher from the viewpoint of preventing pores from being blocked by the fiber melted during the polishing process. Preferably, both have a melting point of 180 ° C. or higher.
Furthermore, the difference between the melting points of the main fiber and the low melting point is preferably greater than 20 ° C., more preferably 40 ° C. or more, from the viewpoint of facilitating temperature control during molding.

本発明の実施の態様を実施例に基づいて説明する。   Embodiments of the present invention will be described based on examples.

表1には、本発明の繊維製液体供給芯の実施例について比較例とともに示す。   Table 1 shows examples of the fiber liquid supply core of the present invention together with comparative examples.

前記表1の比較例1では、LPETの融点が180℃となるPET/LPET複合繊維 [4d]100%(熱融着繊維のみ)を繊維密度4,000d/mm2となる様、設計されたスライバーを金型[ノズル状]内に通過させLPETバインダー分(低融点部)を溶融結着させ繊維を長手方向に集束した繊維製液体供給芯を得たものを例示している。しかし、複合繊維100%では外径精度が悪く、またスジワレ等外観不良も見られる繊維製棒状体しか出来ず、安定した繊維製液体供給芯を得るに至らなかった。なお、前記PETはポリエチレンテレフタレート、前記LPETは低融点ポリエチレンテレフタレート、前記dはデニールを意味する。   In Comparative Example 1 of Table 1 above, a sliver designed so that the density of PET / LPET composite fiber [4d] 100% (heat-bonded fiber only) with a melting point of LPET of 180 ° C. is 4,000 d / mm 2 is used. An example is shown in which a fiber liquid supply core is obtained in which a LPET binder (low melting point portion) is passed through a mold [nozzle shape] and the fibers are converged in the longitudinal direction. However, with 100% composite fiber, the outer diameter accuracy was poor, and only a fiber rod-like body with poor appearance such as stripes could be produced, and a stable fiber liquid supply core could not be obtained. The PET means polyethylene terephthalate, the LPET means low melting point polyethylene terephthalate, and the d means denier.

比較例2には260℃融点のPET繊維[4d](主繊維のみ)を100%で繊維密度4,000d/mm2となる様、設計されたスライバーを金型[ノズル状]内に通過させ成形した結果を例示している。前記PET繊維のみの成形では前記PET繊維融点以下で加工した際は殆ど繊維状のものとなってしまい、連続して引取る成形が出来ず、また前記PET繊維の融点以上で成形加工した際はほぼ全ての繊維が溶融してしまい、全く引取る事が出来ず、繊維製液体供給芯を得るには至らなかった。   In Comparative Example 2, a 260 ° C. melting point PET fiber [4d] (main fiber only) was molded by passing the designed sliver through a mold [nozzle shape] so that the fiber density was 4,000 d / mm 2 at 100%. The results are illustrated. In the molding of the PET fiber only, it becomes almost fibrous when processed below the melting point of the PET fiber, and cannot be continuously drawn, and when molded at the melting point of the PET fiber or higher Almost all the fibers were melted and could not be picked up at all, and the fiber liquid supply core could not be obtained.

比較例3では、主繊維としてのPET繊維(太さ3d、融点260℃)と、熱融着繊維としてのPET/LPET複合繊維(太さ4d、PETの融点260℃、LPETの融点120℃)と、の二種類の繊維を70:30の比率で混合し、繊維製液体供給芯を得た際の結果を例示しており、繊維製液体供給芯の棒状体を得る事は出来るものの、前記繊維製液体供給芯はLPETの融点が120℃と低温である為に研磨加工に耐えられないものとなり、ペン先加工等の後加工を必要とする目的においては不適となる。   In Comparative Example 3, PET fiber (thickness 3d, melting point 260 ° C) as the main fiber and PET / LPET composite fiber (thickness 4d, PET melting point 260 ° C, LPET melting point 120 ° C) as the heat-sealing fiber The two types of fibers are mixed at a ratio of 70:30 to illustrate the result when a fiber liquid supply core is obtained, and although a rod-like body of the fiber liquid supply core can be obtained, The fiber liquid supply core cannot withstand polishing because the melting point of LPET is as low as 120 ° C., and is unsuitable for purposes that require post-processing such as nib processing.

比較例4では、主繊維としてのPBT繊維(太さ3d、融点220℃)と、熱融着繊維としてのPET/LPET複合繊維(太さ2d、PETの融点260℃、LPETの融点200℃)と、の二種類の繊維を70:30の比率で混合し、繊維密度4,000d/mm2となる様、設計されたスライバーを金型[ノズル状]内に通過させ成形した結果を例示している。前記PBT繊維とLPETの融点の差が20℃しかない為、LPETの融点以上で成形加工した際はPBT繊維も溶融してしまい、また逆にLPETの融点以下の成形加工温度では殆ど繊維状の状態のままでうまく引取る事が出来ず、繊維製液体供給芯を得るには至らなかった。   In Comparative Example 4, PBT fiber as the main fiber (thickness 3d, melting point 220 ° C) and PET / LPET composite fiber as the heat-sealing fiber (thickness 2d, PET melting point 260 ° C, LPET melting point 200 ° C) These two types of fibers are mixed at a ratio of 70:30, and the sliver designed so as to have a fiber density of 4,000 d / mm 2 is passed through a mold [nozzle shape] and molded. . Because the difference in melting point between the PBT fiber and LPET is only 20 ° C, the PBT fiber also melts when molded above the melting point of LPET, and conversely at the molding processing temperature below the melting point of LPET it is almost fibrous. It was not possible to pull it out as it was, and a fiber liquid supply core could not be obtained.

また、表1中の実施例1では、主繊維としてのPET繊維(太さ3d、融点260℃)と、熱融着繊維としてのPET/LPET複合繊維(太さ4d、PETの融点260℃、LPETの融点180℃)と、の二種類の繊維を90:10の比率で混合し、繊維密度4,000d/mm2となる様、設計された混綿スライバーを金型[ノズル状]を通過させLPETバインダー分(低融点部)を溶融結着させ、繊維を長手方向に集束した繊維製液体供給芯1を得た。その後、その繊維製液体供給芯1では、原棒を指定の長さにカットし、研磨等の方法で先端、後端形状を形成し、略砲弾形状の熱硬化樹脂を使用しない研磨加工に耐え得るエステル繊維製筆記具用ペン先を得ることが出来た。   In Example 1 in Table 1, PET fiber (thickness 3d, melting point 260 ° C.) as the main fiber and PET / LPET composite fiber (thickness 4d, melting point 260 ° C. of PET, LPET binder, which is designed to mix two types of fibers with a melting point of 180 ° C and a ratio of 90:10, and pass through a mold [nozzle] so that the fiber density is 4,000d / mm2. Minutes (low melting point portion) were melted and bonded to obtain a fiber liquid supply core 1 in which the fibers were converged in the longitudinal direction. After that, in the fiber liquid supply core 1, the raw rod is cut to a specified length, and the tip and rear end shapes are formed by a method such as polishing, which can withstand polishing without using a substantially shell-shaped thermosetting resin. An ester fiber writing instrument nib was obtained.

実施例2では、主繊維としてのPET繊維(太さ3d、融点260℃)と、熱融着繊維としてのPET/LPET複合繊維(太さ4d、PETの融点260℃、LPETの融点180℃)と、の二種類の繊維を70:30の比率で混合し、繊維密度4,000d/mm2となる様、設計された混綿スライバーを金型[ノズル状]を通過させ、LPETバインダー分(低融点部)を溶融結着させ、繊維を長手方向に集束した繊維製液体供給芯1を得た。その後、前記繊維製液体供給芯1でも指定の長さにカットし、研磨等の方法で先端、後端形状を形成し、略砲弾形状の熱硬化樹脂を使用しないエステル繊維製の筆記具用ペン先またはインク誘導芯等の供給芯を得る事が出来た。実施例2では断面硬度が27と実施例1に例示するものより少し硬い繊維製液体供給芯を得ることが出来た。また、この実施例2の気孔率は、65%であり、実施例1の気孔率よりも小さくなった。   In Example 2, PET fiber as the main fiber (thickness 3d, melting point 260 ° C) and PET / LPET composite fiber as the heat-sealing fiber (thickness 4d, PET melting point 260 ° C, LPET melting point 180 ° C) These two types of fibers are mixed at a ratio of 70:30, and the blended cotton sliver designed so that the fiber density is 4,000 d / mm 2 is passed through the mold [nozzle shape] and the LPET binder content (low melting point part) ) Was melt-bonded to obtain a fiber liquid supply core 1 in which the fibers were converged in the longitudinal direction. Thereafter, the fiber liquid supply core 1 is cut to a specified length, and the tip and rear end shapes are formed by a method such as polishing, and the pen tip for a writing instrument made of ester fiber that does not use a substantially shell-shaped thermosetting resin. Alternatively, a supply core such as an ink induction core could be obtained. In Example 2, a fiber liquid supply core having a cross-sectional hardness of 27 and slightly harder than that illustrated in Example 1 could be obtained. Moreover, the porosity of this Example 2 was 65%, and became smaller than the porosity of Example 1.

実施例3では、主繊維としてのPET繊維(太さ3d、融点260℃)と、熱融着繊維としてのPET/LPET複合繊維(太さ4d、PETの融点260℃、LPETの融点180℃)と、の二種類の繊維を50:50の比率で混合し、繊維製液体供給芯1を得たものを例示している。この実施例3では断面硬度が42と実施例2に例示するものより更に硬い繊維製液体供給芯を得ることが出来た。また、この実施例3の気孔率は、61%であり、実施例2の気孔率よりも更に小さくなった。   In Example 3, PET fibers (thickness 3d, melting point 260 ° C.) as main fibers and PET / LPET composite fibers (thickness 4d, PET melting point 260 ° C., LPET melting point 180 ° C.) as heat-sealing fibers The two types of fibers are mixed at a ratio of 50:50 to obtain a fiber-made liquid supply core 1. In Example 3, a fiber liquid supply core having a cross-sectional hardness of 42 and a hardness higher than that illustrated in Example 2 could be obtained. In addition, the porosity of Example 3 was 61%, which was even smaller than the porosity of Example 2.

すなわち、実施例1〜3より、主繊維に対する熱融着繊維の比率が多いほど、硬度が高く、且つ気孔率が小さくなる傾向があるといえる。   That is, it can be said from Examples 1 to 3 that the higher the ratio of the heat-sealing fiber to the main fiber, the higher the hardness and the lower the porosity.

実施例4では、主繊維としてのPET繊維(太さ3d、融点260℃)と、熱融着繊維としてのPBT繊維(太さ3d、融点170℃)と、の二種類の繊維を70:30の比率で混合し、繊維密度4,000d/mm2となる様、設計された混綿スライバーを金型[ノズル状]を通過させ、PBTバインダー分(低融点部)を溶融結着させ、繊維を長手方向に集束した繊維製液体供給芯1となる原棒を得た結果を例示している。   In Example 4, two types of fibers, PET fibers (thickness 3d, melting point 260 ° C.) as main fibers and PBT fibers (thickness 3d, melting point 170 ° C.) as heat-fusible fibers, are 70:30. The blended cotton sliver designed to have a fiber density of 4,000 d / mm2 is passed through the mold [nozzle shape] to melt and bond the PBT binder (low melting point), and the fibers in the longitudinal direction. The result which obtained the raw | natural stick | rod used as the fiber liquid supply core 1 converged in FIG.

実施例5では、主繊維としてのPET繊維(太さ3d、融点260℃)と、熱融着繊維としての芯鞘型のPET/PBT複合繊維(太さ1.5d、PETの融点260℃、PBTの融点220℃)と、の二種類の繊維を70:30の比率で混合し、繊維密度4,000d/mm2となる様、設計された混綿スライバーを金型[ノズル状]を通過させ、PBTバインダー分(低融点部)を溶融結着させ、繊維を長手方向に集束した繊維製液体供給芯を得た結果を例示している。   In Example 5, PET fiber as the main fiber (thickness 3d, melting point 260 ° C) and core-sheath type PET / PBT composite fiber (thickness 1.5d, PET melting point 260 ° C, PBT as the heat-sealing fiber) 2 types of fibers are mixed at a ratio of 70:30, and a mixed cotton sliver designed to have a fiber density of 4,000 d / mm 2 is passed through a die [nozzle] to form a PBT binder. The result of obtaining a fiber-made liquid supply core in which the fibers (the low melting point portion) are melt-bound and the fibers are focused in the longitudinal direction is illustrated.

また、実施例6では、主繊維としてのPA66繊維(太さ6d、融点260℃)と、熱融着繊維としてのPA6繊維(太さ3d、融点220℃)と、の二種類の繊維を70:30の比率で混合し、繊維密度4,000d/mm2となる様、設計された混綿スライバーを金型[ノズル状]を通過させ、PA6バインダー分(低融点部)を溶融結着させ、繊維を長手方向に集束した繊維製液体供給芯1を得たものを例示している。   Further, in Example 6, two types of fibers, namely, a PA66 fiber (thickness 6d, melting point 260 ° C.) as a main fiber and a PA6 fiber (thickness 3d, melting point 220 ° C.) as a heat-sealing fiber, are used. : Mix at a ratio of 30 and pass the designed mixed cotton sliver through the mold [nozzle shape] so that the fiber density is 4,000 d / mm2, melt the PA6 binder (low melting point part), and bond the fibers. A fiber liquid supply core 1 concentrated in the longitudinal direction is illustrated.

また、実施例7では、主繊維としてのPET繊維(太さ3d、融点260℃)と、熱融着繊維としてのPET/LPET複合繊維(太さ2d、PETの融点260℃、LPETの融点200℃)と、の二種類の繊維を70:30の比率で混合し、繊維密度4,000d/mm2となる様、設計された混綿スライバーを金型[ノズル状]を通過させ、LPETバインダー分(低融点部)を溶融結着させ、繊維を長手方向に集束した繊維製液体供給芯1を得た。その後、前記繊維製液体供給芯1でも指定の長さにカットし、研磨等の方法で先端、後端形状を形成し、略砲弾形状の熱硬化樹脂を使用しないエステル繊維製の筆記具用ペン先またはインク誘導芯等の供給芯を得る事が出来た。   In Example 7, PET fibers (thickness 3d, melting point 260 ° C.) as main fibers, and PET / LPET composite fibers (thickness 2d, PET melting point 260 ° C., LPET melting point 200 ° C. as heat-sealing fibers. )), And the blended cotton sliver designed so that the fiber density is 4,000 d / mm 2 is passed through the mold [nozzle] and the LPET binder content (low) The fiber melting point) was melt-bound to obtain a fiber liquid supply core 1 in which the fibers were converged in the longitudinal direction. Thereafter, the fiber liquid supply core 1 is cut to a specified length, and the tip and rear end shapes are formed by a method such as polishing, and the pen tip for a writing instrument made of ester fiber that does not use a substantially shell-shaped thermosetting resin. Alternatively, a supply core such as an ink induction core could be obtained.

また、実施例8では、主繊維としてのPET繊維(太さ3d、融点260℃)と、熱融着繊維としてのPET/LPET複合繊維(太さ2d、PETの融点260℃、LPETの融点180℃)と、の二種類の繊維を70:30の比率で混合し、繊維密度4,000d/mm2となる様、設計された混綿スライバーを金型[ノズル状]を通過させ、LPETバインダー分(低融点部)を溶融結着させ、繊維を長手方向に集束した繊維製液体供給芯1を得た。その後、前記繊維製液体供給芯1でも指定の長さにカットし、研磨等の方法で先端、後端形状を形成し、略砲弾形状の熱硬化樹脂を使用しないエステル繊維製の筆記具用ペン先またはインク誘導芯等の供給芯を得る事が出来た。
なお、実施例7と実施例8の違いを説明すれば、実施例8では、PET/LPET複合繊維における低融点部として、実施例7のものよりも融点が低いLPETを用いている。
In Example 8, PET fiber as the main fiber (thickness 3d, melting point 260 ° C.) and PET / LPET composite fiber (thickness 2d, PET melting point 260 ° C., LPET melting point 180 ° as the heat fusion fiber) )), And the blended cotton sliver designed so that the fiber density is 4,000 d / mm 2 is passed through the mold [nozzle] and the LPET binder content (low) The fiber melting point) was melt-bound to obtain a fiber liquid supply core 1 in which the fibers were converged in the longitudinal direction. Thereafter, the fiber liquid supply core 1 is cut to a specified length, and the tip and rear end shapes are formed by a method such as polishing, and the pen tip for a writing instrument made of ester fiber that does not use a substantially shell-shaped thermosetting resin. Alternatively, a supply core such as an ink induction core could be obtained.
The difference between Example 7 and Example 8 will be described. In Example 8, LPET having a lower melting point than that of Example 7 is used as the low melting point part in the PET / LPET composite fiber.

表1における実施例8と実施例2の比較より、主繊維の太さよりも熱融着繊維の太さを細くすれば(実施例8)、その関係が逆の場合(実施例2)に比較して、硬度が高い繊維製液体供給芯1を得られるといえる。   From the comparison between Example 8 and Example 2 in Table 1, if the thickness of the heat-fusible fiber is made thinner than the thickness of the main fiber (Example 8), it is compared with the case where the relationship is reversed (Example 2). Thus, it can be said that a fiber liquid supply core 1 having high hardness can be obtained.

図1は本発明の繊維製液体供給芯1の一例であり、この繊維製液体供給芯1は軸方向に方向性を持つ繊維束で、成形加工温度では熱溶融しない、融点の高い主繊維と、熱融着する融点の低い部分(低融点部)を持つ熱融着繊維との溶融結着により径断面積比20〜85%の気孔率を形成し、相互に自着している。   FIG. 1 shows an example of a fiber liquid supply core 1 according to the present invention. This fiber liquid supply core 1 is a fiber bundle having a directionality in the axial direction. A porosity with a diameter cross-sectional area ratio of 20 to 85% is formed by melt-bonding with a heat-sealing fiber having a low melting point portion (low melting point portion) to be heat-sealed, and is self-attached to each other.

図2は、熱融着繊維に複合繊維を使用して成形した繊維製液体供給芯1の拡大横断面を、模式的に示している。
図中、符号2で示す部分は、主繊維としてのPET繊維である。また、符号3で示す部分は、熱融着繊維としてのPET/LPET複合繊維であり、特に外表面側の黒塗り部分が成形加工温度で溶融する低融点部(LPET)、内部側の白塗り部分が成形加工温度では溶融しない高融点部(PET)である。
なお、実際の繊維製液体供給芯1の拡大横断面については、図示を省略するが、詳述すれば、図2中の黒塗り部分(低融点部)が熱溶融して形が崩れ、その熱溶融した際の低融点部によって繊維間が結着されるとともに、繊維間に気孔が形成された状態となる。
FIG. 2 schematically shows an enlarged cross section of a fiber liquid supply core 1 formed by using a composite fiber as a heat-sealing fiber.
In the figure, a portion indicated by reference numeral 2 is a PET fiber as a main fiber. The portion indicated by reference numeral 3 is a PET / LPET composite fiber as a heat-sealing fiber, and in particular, the low melting point portion (LPET) in which the black-coated portion on the outer surface side melts at the molding processing temperature, and white coating on the inner side The part is a high melting point part (PET) that does not melt at the molding temperature.
In addition, although illustration is abbreviate | omitted about the expanded cross section of the actual fiber liquid supply core 1, if it explains in full detail, the black coating part (low melting | fusing point part) in FIG. The fibers are bound by the low melting point when melted by heat, and pores are formed between the fibers.

図3では熱融着繊維に単一重合体素材からなる成型加工温度で容易に溶融する低融点の繊維を使用して成形した繊維製液体供給芯1の拡大横断面を、模式的に示している。
図中、符号4で示す黒塗り部分は、熱融着繊維(低融点部)としてのPA6(ポリアミド6)繊維である。また、符号5で示す白塗り部分は、成形加工温度では溶融しない主繊維としてのPA66(ポリアミド66)繊維である。すなわち、この態様では、熱融着繊維を低融点部のみによって構成している(高融点部を有さない構成としている)。
なお、実際の繊維製液体供給芯1の拡大横断面については、図示を省略するが、詳述すれば、図3中の黒塗り部分(熱融着繊維(低融点部))が熱溶融して形が崩れ、その熱溶融した際の低融点部によって繊維間が結着されるとともに、繊維間に気孔が形成された状態となる。
FIG. 3 schematically shows an enlarged cross section of a fiber liquid supply core 1 formed by using a low-melting fiber that is easily melted at a molding processing temperature made of a single polymer material for a heat-sealing fiber. .
In the figure, the black coating portion indicated by reference numeral 4 is PA6 (polyamide 6) fiber as a heat-sealing fiber (low melting point portion). Further, the white coating portion indicated by reference numeral 5 is PA66 (polyamide 66) fiber as a main fiber that does not melt at the molding processing temperature. That is, in this aspect, the heat-sealing fiber is configured only by the low melting point portion (the configuration does not have the high melting point portion).
In addition, although illustration is abbreviate | omitted about the expanded cross section of the actual fiber liquid supply core 1, if it explains in full detail, the black coating part (heat-fusion fiber (low melting | fusing point part)) in FIG. 3 will heat-melt. The shape is deformed, and the fibers are bound by the low melting point when melted by heat, and pores are formed between the fibers.

図4には熱硬化樹脂を使用した方法で繊維製液体供給芯を得る従来の製造方法を例示している。
図中、符号6は混合繊維束、符号8は樹脂液槽、符号9は乾燥炉、符号10は引取機、符号11はカッターである。
FIG. 4 illustrates a conventional manufacturing method for obtaining a fiber liquid supply core by a method using a thermosetting resin.
In the figure, reference numeral 6 is a mixed fiber bundle, reference numeral 8 is a resin liquid tank, reference numeral 9 is a drying furnace, reference numeral 10 is a take-up machine, and reference numeral 11 is a cutter.

図5には熱硬化樹脂を使用しない今回発明の繊維製液体供給芯1を得る製法を例示している。
この製造方法では、主繊維と熱融着繊維を含む二種類以上の繊維を多数混合し、その繊維方向を揃えて束ねて混合繊維束6を構成し、この混合繊維束6を、加熱ブロック7に通過させ引取機10により引き取ることで、束ね合わせ方向(繊維方向に直交する方向)に圧縮しながら、熱融着繊維の低融点部の融点よりも高く且つ主繊維の融点よりも低い温度で加熱し、熱融着繊維の低融点部のみを溶融し、その溶融した低融点部の樹脂によって繊維間を結着するとともに、繊維間に繊維方向へわたる連続気孔を形成して、繊維方向を長手方向へ向けた中実棒状の繊維製液体供給芯1(図1参照)が得られる。
その後、この繊維製液体供給芯1は、指定の長さにカットされ、例えば、長さ方向の一端部側又は両端部側が砲弾形状等の所望の形状に研磨加工されることで、筆記具のペン先(図6参照)等になる。
FIG. 5 illustrates a production method for obtaining the fiber liquid supply core 1 of the present invention without using a thermosetting resin.
In this manufacturing method, a large number of two or more types of fibers including main fibers and heat-sealing fibers are mixed, and the fiber directions are aligned and bundled to form a mixed fiber bundle 6. The mixed fiber bundle 6 is heated with a heating block 7. At a temperature higher than the melting point of the low melting point portion of the heat-fusible fiber and lower than the melting point of the main fiber while being compressed in the bundling direction (direction perpendicular to the fiber direction). Heat, melt only the low-melting point portion of the heat-fusible fiber, bind the fibers with the melted resin of the low-melting point, and form continuous pores extending between the fibers in the fiber direction. A solid rod-like fiber liquid supply core 1 (see FIG. 1) oriented in the longitudinal direction is obtained.
Thereafter, the fiber liquid supply core 1 is cut to a specified length, and for example, one end side or both end sides in the length direction is polished into a desired shape such as a shell shape, so that the pen of the writing instrument First (see FIG. 6).

本発明に係る繊維製液体供給芯の製造方法によれば、熱硬化樹脂を繊維束に含浸させ、乾燥炉内で熱硬化樹脂が溶融していた有機溶剤を飛ばす必要が無く、有機溶剤を大気放出すると言った製造上発生する環境悪化懸念が払拭された。また前記有機溶剤の揮発・乾燥、及び熱硬化樹脂の硬化の為の熱エネルギーも不要となり低コストで、かつ地球環境に優しい形で製品作りが可能となった。また、図5からも分るよう樹脂液槽や乾燥炉も不要となり製造スペースも大幅に削減可能となった。   According to the method for producing a fiber liquid supply core according to the present invention, it is not necessary to impregnate a fiber bundle with a thermosetting resin, and to blow off the organic solvent in which the thermosetting resin has been melted in a drying furnace. The concerns about environmental degradation that occurred during manufacturing were released. Further, the heat energy for volatilization / drying of the organic solvent and curing of the thermosetting resin is not required, and the product can be manufactured at a low cost and in a form friendly to the global environment. Further, as can be seen from FIG. 5, the resin liquid tank and the drying furnace are not required, and the manufacturing space can be greatly reduced.

なお、本発明に係る繊維製液体供給芯の製造方法の好ましい態様では、主繊維の太さと熱融着繊維の太さとの比率を調整することで、硬さ調整及び/又は気孔率の調整をするようにしてもよい。
すなわち、主繊維の太さと熱融着繊維の太さとの比率を調整すれば、各繊維外周における結着箇所の数を調整することができ、この結着箇所の増減により硬度や気孔率を調整することができる。
特に好ましい態様として、主繊維の太さよりも熱融着繊維の太さを細くすれば、主繊維外周における結着箇所が増えるので、繊維間の接着強度を向上することができる。
In the preferred embodiment of the method for producing a fiber liquid supply core according to the present invention, the hardness and / or the porosity can be adjusted by adjusting the ratio between the thickness of the main fiber and the thickness of the heat fusion fiber. You may make it do.
In other words, by adjusting the ratio between the thickness of the main fiber and the thickness of the heat-sealing fiber, the number of binding sites on the outer periphery of each fiber can be adjusted, and the hardness and porosity can be adjusted by increasing or decreasing the number of binding sites. can do.
As a particularly preferred embodiment, if the thickness of the heat-sealing fiber is made thinner than the thickness of the main fiber, the number of binding sites on the outer periphery of the main fiber increases, so that the adhesive strength between the fibers can be improved.

更に本発明に係る繊維製液体供給芯の製造方法の好ましい態様としては、主繊維の量と熱融着繊維の量との比率を調整することで、硬さ調整及び/又は気孔率の調整をするようにしてもよい。
すなわち、例えば、主繊維の量に対し熱融着繊維の量の比率を大きくすれば、各繊維外周における結着箇所の数が増えるため、成形後の繊維製液体供給芯の硬度を上げるとともに、気孔率を小さくすることができる。
Furthermore, as a preferable aspect of the method for producing a fiber liquid supply core according to the present invention, the ratio of the amount of the main fiber and the amount of the heat fusion fiber is adjusted to adjust the hardness and / or the porosity. You may make it do.
That is, for example, if the ratio of the amount of heat-bonded fibers to the amount of main fibers is increased, the number of binding locations on the outer periphery of each fiber increases, so the hardness of the fiber liquid supply core after molding is increased, The porosity can be reduced.

以上、本発明の実施例について説明したが、本発明はこれらの実施形態に何等限定されるものではない。   As mentioned above, although the Example of this invention was described, this invention is not limited to these embodiment at all.

例えば、本発明における繊維製液体供給芯は熱硬化樹脂を使用する事無く、融点の異なる繊維を組み合わせ作られ、連通した気孔を有し、液体を供給可能な多孔質体であり、その熱硬化樹脂を使用しない本発明の繊維製液体供給芯の成形に使用される繊維は短繊維からなるスライバー形態のものに限定されること無く、融点の異なる長繊維であるフィラメント繊維形態のものを組み合わせて作られたものであっても良い。またその繊維製液体供給芯に使用される繊維は実施例記載の繊維等に限定されるものではなく、市場に流通している全ての繊維を含めて選択自由であり、何等限定されるものではない。   For example, the fiber liquid supply core in the present invention is a porous body that is made of a combination of fibers having different melting points without using a thermosetting resin, has pores that communicate with each other, and can supply liquid. The fiber used for forming the fiber liquid supply core of the present invention that does not use a resin is not limited to a sliver form composed of short fibers, but a combination of filament fiber forms that are long fibers having different melting points. It may be made. In addition, the fibers used in the fiber liquid supply core are not limited to the fibers described in the examples, but can be freely selected including all fibers distributed in the market. Absent.

また、本発明における繊維製液体供給芯1は、例えば、丸棒状、角棒状、その他適宜断面形状の中実棒状としてもよい。   Moreover, the fiber liquid supply core 1 in the present invention may be, for example, a round bar shape, a square bar shape, or a solid bar shape as appropriate in cross section.

また、上記実施の形態では、前記主繊維と前記熱融着繊維の二種類の繊維により繊維製液体供給芯1を構成したが、本発明はこれに限定されず、例えば、前記主繊維と前記熱融着繊維とを含む三種類以上の繊維によって繊維製液体供給芯1を構成するようにしてもよい。   Moreover, in the said embodiment, although the fiber-made liquid supply core 1 was comprised by two types of fibers, the said main fiber and the said heat-fusion fiber, this invention is not limited to this, For example, the said main fiber and the said The fiber liquid supply core 1 may be constituted by three or more kinds of fibers including the heat-sealing fibers.

また、図2に示す一例では、熱融着繊維の特に好ましい態様として芯鞘構造の複合繊維を用いたが、この熱融着繊維は、少なくとも外表面の一部又は全部に前記主繊維よりも融点の低い低融点部を有するものであればよく、例えば、一半部が高融点の重合体で他半部が低融点の重合体である接合型複合繊維や、高融点の重合体と低融点の重合体の層を交互に配置した多層型複合繊維等であってもよいし、図3に例示したように、内外の全てが低融点部である繊維であってもよい。   In the example shown in FIG. 2, the core-sheath composite fiber is used as a particularly preferable embodiment of the heat-sealing fiber, but the heat-sealing fiber is at least partially or entirely on the outer surface than the main fiber. What is necessary is just to have a low melting point part with a low melting point, for example, a joint type composite fiber in which one half is a high melting point polymer and the other half is a low melting point polymer, or a high melting point polymer and a low melting point. A multilayer type composite fiber or the like in which the polymer layers are alternately arranged may be used, or, as illustrated in FIG. 3, all of the inside and outside may be a fiber having a low melting point.

また、図6に示す一例では、長手方向の両端部側に研磨面を有する態様としたが、他例としては、長手方向の一端部側のみに研磨面を有する態様や、外周面に研磨面を有する態様等、外面の少なくとも一部に研磨面を有する構成とすることができる。また、更に他例としては、外面に研磨面を有さない態様とすることも可能である。   Moreover, in the example shown in FIG. 6, although it was set as the aspect which has a grinding | polishing surface in the both ends part of a longitudinal direction, as another example, the aspect which has a grinding | polishing surface only in the one end part side of a longitudinal direction, or a grinding | polishing surface on an outer peripheral surface It can be set as the structure which has a grinding | polishing surface in at least one part of outer surfaces. As still another example, it is possible to adopt an aspect in which the outer surface does not have a polished surface.

本発明の繊維製液体供給芯は、例えば油性マーカー、ボードマーカー、ラインマーカー、ペイントマーカー、水性マーカー、医療用マーカー、プラモデル用マーカー等のマーキングペンに用いる筆記具用ペン先またはインク誘導芯用液体供給芯に適している。   The fiber liquid supply core of the present invention is, for example, an oil-based marker, a board marker, a line marker, a paint marker, an aqueous marker, a medical marker, a plastic marker, a pen tip for a writing instrument used for a marking pen, or a liquid supply for an ink guide core. Suitable for wicks.

また、本発明の繊維製液体供給芯は、例えば化粧用として有用であり、特にアイライナー、アイシャドウ、アイブロー、毛染めマーカー、チーク、リップライナー、リップグロス、コンシーラー、マニキュアリムーバー、ネイルケア、スキンケア、ホワイトニング、メイク落とし、歯の清掃、まつ毛ケア、香水ペンの液体塗布用供給芯に適している。   Further, the fiber liquid supply core of the present invention is useful, for example, for cosmetic purposes. Suitable for whitening, makeup remover, tooth cleaning, eyelash care, and liquid supply core for perfume pen.

さらには、例えば薬剤塗布用としても有用であり、特に芳香剤、消臭剤、防虫剤、液状シップ剤、日焼け止め、サンオイル、にきび治療薬などの液体塗布または液体吸い上げ、揮散用液体供給芯に適している。   Furthermore, it is also useful for, for example, drug application, and in particular, liquid application or liquid uptake and volatilization liquid supply cores such as fragrances, deodorants, insect repellents, liquid shipping agents, sunscreens, sun oils, acne remedies Suitable for

1 繊維製液体供給芯
2 PET繊維(主繊維)
3 PET/LPET芯鞘複合繊維(熱融着繊維)
4 PA6繊維(熱融着繊維)
5 PA66繊維(主繊維)
6 混合繊維束
7 加熱ブロック
8 樹脂液槽
9 乾燥炉
10 引取機
11 カッター
1 Fiber supply core 2 PET fiber (main fiber)
3 PET / LPET core-sheath composite fiber (heat-bonded fiber)
4 PA6 fiber (heat fusion fiber)
5 PA66 fiber (main fiber)
6 Mixed fiber bundle 7 Heating block 8 Resin liquid tank 9 Drying furnace 10 Take-up machine 11 Cutter

Claims (6)

主繊維と熱融着繊維とを含む二種類以上の繊維を、多数混合し長手方向にそろえて束ね圧縮し、繊維間に連続気孔を有する状態で繊維間を熱溶融した際の前記熱融着繊維の外周部により結着し、繊維方向を長手方向へ向けた中実棒状に形成してなる繊維製液体供給芯であって、
前記主繊維は、ポリエチレンテレフタレート繊維であり、
前記熱融着繊維は、ポリエチレンテレフタレート繊維の外周を、該ポリエチレンテレフタレート繊維よりも融点が低く且つ前記主繊維よりも融点が低い低融点ポリエチレンテレフタレートにより覆った鞘芯構造の複合繊維であり、この熱融着繊維の太さは、前記主繊維の太さよりも細いことを特徴とする繊維製液体供給芯。
Two or more fibers containing a main fiber and a heat fusible fibers, and compressed bundle aligned on a number mixed longitudinal direction, and the heat at the time of the inter-fiber was heat melted in a state having continuous pores fiber維間A fiber liquid supply core that is bound by the outer periphery of the attached fibers and formed into a solid rod shape in which the fiber direction is directed in the longitudinal direction ,
The main fiber is a polyethylene terephthalate fiber,
The heat-fusible fiber is a composite fiber having a sheath-core structure in which the outer periphery of a polyethylene terephthalate fiber is covered with a low-melting point polyethylene terephthalate having a melting point lower than that of the polyethylene terephthalate fiber and lower than that of the main fiber. A fiber liquid supply core characterized in that the thickness of the fused fiber is thinner than the thickness of the main fiber .
前記主繊維は、太さ3d、融点260℃のポリエチレンテレフタレート繊維であり、
前記熱融着繊維は、融点260℃のポリエチレンテレフタレート繊維の外周を、融点200℃の低融点ポリエチレンテレフタレートにより覆った太さ2dの複合繊維であり、
これら主繊維と熱融着繊維とは、気孔率20〜85%となるように構成されることを特徴とする請求項1記載の繊維製液体供給芯。
The main fiber is a polyethylene terephthalate fiber having a thickness of 3d and a melting point of 260 ° C,
The heat-sealing fiber is a 2d-thick composite fiber in which the outer periphery of a polyethylene terephthalate fiber having a melting point of 260 ° C. is covered with a low melting point polyethylene terephthalate having a melting point of 200 ° C.,
2. The fiber-made liquid supply core according to claim 1, wherein the main fiber and the heat-sealing fiber are configured to have a porosity of 20 to 85% .
前記主繊維と前記低融点部の融点の差が20℃よりも大きいことを特徴とする請求項1又は2記載の繊維製液体供給芯。   The fiber liquid supply core according to claim 1 or 2, wherein a difference in melting point between the main fiber and the low melting point portion is greater than 20 ° C. 前記主繊維と前記熱融着繊維を含む二種類以上の繊維を多数混合し長手方向にそろえて束ね混合繊維束を構成し、この混合繊維束を、束ね合わせ方向へ圧縮するとともに、前記熱融着繊維の低融点部の融点よりも高く且つ前記主繊維の融点よりも低い温度で加熱することで、前記低融点部を熱溶融し、その熱溶融した低融点部により繊維間を結着するようにしたことを特徴とする請求項1乃至3何れか1項記載の繊維製液体供給芯の製造方法。 A large number of two or more types of fibers including the main fiber and the heat fusion fiber are mixed and aligned in the longitudinal direction to form a bundle of mixed fibers. The mixed fiber bundle is compressed in the bundle direction, and the heat fusion is performed. By heating at a temperature higher than the melting point of the low melting point portion of the adhering fiber and lower than the melting point of the main fiber, the low melting point portion is thermally melted, and the fibers are bound by the heat melting low melting point portion. The method for producing a fiber liquid supply core according to any one of claims 1 to 3, wherein the fiber liquid supply core is formed. 前記主繊維の太さと前記熱融着繊維の太さとの比率を調整することで、硬さ調整及び/又は気孔率の調整をするようにしたことを特徴とする請求項4記載の繊維製液体供給芯の製造方法 5. The fiber liquid according to claim 4, wherein the ratio of the thickness of the main fiber and the thickness of the heat-sealing fiber is adjusted to adjust the hardness and / or the porosity. Manufacturing method of supply core . 前記主繊維の量と前記熱融着繊維の量との比率を調整することで、硬さ調整及び/又は気孔率の調整をするようにしたことを特徴とする請求項4又は5記載の繊維製液体供給芯の製造方法。 The fiber according to claim 4 or 5, wherein the ratio of the amount of the main fiber and the amount of the heat-fusible fiber is adjusted to adjust the hardness and / or the porosity. A method for producing a liquid supply core.
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