JP5857392B2 - Near infrared absorbing ink and method for producing the same - Google Patents

Near infrared absorbing ink and method for producing the same Download PDF

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JP5857392B2
JP5857392B2 JP2009019484A JP2009019484A JP5857392B2 JP 5857392 B2 JP5857392 B2 JP 5857392B2 JP 2009019484 A JP2009019484 A JP 2009019484A JP 2009019484 A JP2009019484 A JP 2009019484A JP 5857392 B2 JP5857392 B2 JP 5857392B2
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resin
ink
infrared absorbing
infrared
oil
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JP2010174164A (en
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美穂 荒木
美穂 荒木
牛腸 智
智 牛腸
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Toppan Inc
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Description

本発明は、商品券、宝くじ、定期券等の証券類の偽造防止を目的とする、近赤外線吸収インキおよびその製法に係わり、さらに詳しくは、少なくとも樹脂にくるまれた赤外線吸収色素および油分、樹脂とから成り、耐溶剤性が高いことを特徴とする近赤外線吸収インキおよびその製造方法に関する。   The present invention relates to a near-infrared absorbing ink for the purpose of preventing counterfeiting of securities such as gift certificates, lottery tickets, commuter passes and the like, and more specifically, an infrared absorbing dye and oil contained in at least a resin, a resin It is related with the near-infrared absorptive ink characterized by having high solvent resistance, and its manufacturing method.

従来から株券、債券、小切手、商品券、宝くじ、定期券等の証券類に記載される情報を機械により読み取る手段として、バーコードやOCR文字等の機械読み取り可能なコードマークが設けられることが多く、通常、近赤外線領域の光を反射する基材面に、近赤外線領域の光を吸収するインキ、カーボンブラック等を含むインキを用いてコードマークを形成するものがある。   Traditionally, machine-readable code marks such as bar codes and OCR characters are often provided as means for reading information on securities such as stock certificates, bonds, checks, gift certificates, lottery tickets, and commuter passes. In some cases, a code mark is usually formed on a base material surface that reflects light in the near infrared region, using ink that absorbs light in the near infrared region, or ink containing carbon black or the like.

白色のインキ及び黒色のインキの赤外線反射および赤外線吸収等の特性を利用し、機械的に読み取り可能な情報を、前記インキを用いてバーコードのパターン状のマークで表し、これを媒体などに付与し、これに赤外線を照射して、マークを走査し、その反射赤外光の強度を測定することにより記録された情報を読み取っている。そして、情報が不正に読み取られないように可視光を遮断し、赤外線を透過する隠蔽層を形成し、可視光により容易に情報が読み取られることを防止する。   Utilizing characteristics such as infrared reflection and infrared absorption of white ink and black ink, mechanically readable information is represented by barcode pattern marks using the ink, and this is applied to media etc. The recorded information is read by irradiating this with infrared rays, scanning the mark, and measuring the intensity of the reflected infrared light. Then, visible light is blocked so that information is not read illegally, and a concealing layer that transmits infrared rays is formed to prevent information from being easily read by visible light.

しかし、上記インキに用いられるカーボンブラックやロイコ染料等の赤外線吸収物質は可視領域においても光吸収性を有しているため、上記情報パターンは赤外線読み取り装置にて機械読み取りされると共に肉眼でもその存在が判読され易く、依然として複写等の偽造や変造等を有効に防止する手段としては不充分であった。   However, since the infrared absorbing material such as carbon black and leuco dye used in the ink has a light absorbing property even in the visible region, the information pattern is mechanically read by an infrared reader and is also present with the naked eye. Is still unreadable as a means for effectively preventing counterfeiting and alteration such as copying.

目視できないようにする手段として、従来からそれ自体が可視光領域における吸収が少なく、しかも、それ以外の波長領域において吸収を有する、特に赤外線吸収材料として熱線吸収ガラスや赤外線吸収ガラスを粉砕し、これを顔料化したものをインキに含有させ、コードマークを形成し、可視光領域での吸収が少ないため、目視困難となることから偽造・変造・改竄などの防止に有効な手段として考えられてきた。   As means for preventing visual observation, heat absorption glass or infrared absorption glass is pulverized as an infrared absorption material, particularly, which itself has little absorption in the visible light region and has absorption in other wavelength regions. It has been considered as an effective means to prevent counterfeiting, tampering, tampering, etc., because it contains pigments in the ink, forms code marks, and has little absorption in the visible light region, making it difficult to see. .

また、証券類への印刷においては、印刷物には偽造・変造・改竄などの防止のために、高い耐性が求められる。印刷上に耐薬品性を向上させる層を設けられる場合もあるが、用途によっては設けることができないことも多い。そのため、インキ自体に耐薬品性を持たせる必要がある。しかし、従来の赤外線吸収色素の多くは、経時的に色彩変化が現れたり、近赤外線遮蔽能が低下、又は消失するという問題がある。   In printing on securities, printed materials are required to have high resistance to prevent forgery, alteration, tampering, and the like. In some cases, a layer for improving chemical resistance may be provided on the print, but it may not be provided depending on the application. For this reason, the ink itself needs to have chemical resistance. However, many of the conventional infrared absorbing dyes have a problem that a color change appears with time, and near-infrared shielding ability is reduced or disappears.

特開平10−78509号広報JP 10-78509 A 特開平10−180947号広報JP 10-180947 A 特開昭61−154888号広報JP-A 61-154888 特開昭61−197281号広報JP-A 61-197281 特開昭61−246091号広報JP-A 61-246091 特開昭63−37991号広報JP-A-63-37991 特開昭63−39388号広報JP-A-63-39388 特開昭62−233288号広報Japanese Laid-Open Patent Publication No. 62-233288 特開昭63−312889号広報JP-A-63-312889 特開平2−43269号広報JP-A-2-43269 特開平2−138382号広報JP-A-2-138382 特開平2−296885号広報JP-A-2-29685 特開平3−43461号広報JP-A-3-43461 特開平3−77840号広報Japanese Laid-Open Patent Publication No. 3-77840 特開平3−100066号広報JP-A-3-100066 特開平3−62878号広報Japanese Laid-Open Patent Publication No. 3-62878 特願平3−338557号広報Japanese Patent Application No. 3-338557 特願平3−99730号広報Japanese Patent Application No. 3-99730 特願平3−252414号広報Japanese Patent Application No. 3-252414 特開昭61−291651号広報JP-A 61-291651 特開昭61−291652号広報Japanese Laid-Open Patent Publication No. 61-291651 特開昭62−15260号広報Japanese Laid-Open Patent Publication No. Sho 62-15260 特開昭62−132963号広報JP-A-62-132963 特開平1−129068号広報JP-A-1-129068 特開平1−172458号広報JP-A-1-172458

本発明は、上記のような問題点に着目してなされたものであり、耐溶剤性に優れ、特に偽造防止インキとして厳しい環境や故意による偽造・変造・改竄防止に有効な耐性を持つ近赤外線吸収インキ、および、その製造方法を提供する。   The present invention has been made paying attention to the above-mentioned problems, and is excellent in solvent resistance, and particularly has a resistance to effective anti-counterfeiting, falsification, and tampering as a forgery-preventing ink, especially in the near infrared An absorbent ink and a method for producing the same are provided.

発明は、赤外線吸収色素と溶剤または水に溶解もしくは分散した樹脂を混合し、基材上にコーティングし、これをかき落としや吸引、基材の延伸の手段によって剥離して、油分と混合し、湿式粉砕した前記樹脂にくるまれて成る前記赤外吸収色素の分散体をJIS K5701に記載の流動特性試験によるスプレッドメーター直径値が10mm〜20mmの油性ワニスに混合し、少なくとも、前記樹脂に包含された前記赤外線吸収色素と油性ワニスの樹脂と前記油分を含むことを特徴とする赤外線吸収インキである。
The present invention is a mixture of an infrared absorbing dye and a resin dissolved or dispersed in a solvent or water, coated on a substrate, peeled off by means of scraping or sucking, stretching the substrate, mixed with oil, The dispersion of the infrared absorbing dye wrapped in the wet-pulverized resin is mixed with an oil varnish having a spread meter diameter value of 10 mm to 20 mm according to a flow property test described in JIS K5701, and at least included in the resin. An infrared absorbing ink comprising the infrared absorbing dye, an oil varnish resin, and the oil.

発明は、JIS K5701に基づいたグラインドメーターを用いて行った練和度測定による前記分散体の練和度が1μm以下であることを特徴とする請求項1に記載の赤外線吸収インキである。
The infrared absorbing ink according to claim 1, wherein the dispersion has a kneading degree of 1 μm or less as measured by a kneading degree measurement using a grindometer based on JIS K5701.

請求項に記載の発明は、硬化性樹脂と赤外線吸収色素とを混合し、前記硬化性樹脂を硬化する工程と、硬化した前記赤外線吸収色素を含む硬化性樹脂を油分と混合し粉砕し分散体とする工程と、粉砕した前記赤外線吸収色素を含む分散体と樹脂を混合する工程、を有することを特徴とする赤外線吸収インキの製造方法法である。
The invention according to claim 1 is a process of mixing a curable resin and an infrared absorbing dye, curing the curable resin, and mixing and pulverizing and dispersing the curable resin containing the cured infrared absorbing dye with an oil. A method for producing an infrared absorbing ink, comprising: a step of forming a body; and a step of mixing a dispersion containing a pulverized infrared absorbing pigment and a resin.

本発明は以上の構成と製造方法から、下記に示す如き効果がある。
本発明の赤外吸収インキは、耐性の低い赤外吸収色素を樹脂にくるむことにより、耐性の向上を図ることができる。また、その製造方法として、耐溶剤性の高い樹脂と赤外線吸収色素とを混合したコーティング剤を基材上に塗布して硬化させ、硬化した層を剥離して、油分と混合して粉砕することにより、耐性の向上した近赤外線吸収インキを得ることができる。
The present invention has the following effects from the above configuration and manufacturing method.
The infrared absorbing ink of the present invention can be improved in resistance by wrapping an infrared absorbing dye having low resistance in a resin. In addition, as a manufacturing method thereof, a coating agent in which a resin having high solvent resistance and an infrared absorbing dye are mixed is applied on a substrate and cured, and the cured layer is peeled off, mixed with an oil, and pulverized. Thus, a near-infrared absorbing ink with improved resistance can be obtained.

本発明の近赤外線吸収インキは、少なくとも樹脂にくるまれた赤外線吸収色素および油分、樹脂とから成る。   The near-infrared absorbing ink of the present invention comprises at least an infrared-absorbing dye wrapped in a resin, an oil component, and a resin.

本発明に使用される近赤外線吸収色素は、800nm〜1400nmに吸収のある赤外吸収材料で、フタロシアニン化合物、ナフタロシアニン化合物、アントラキノン化合物、ジイモニウム化合物、シアニン化合物の中から選ばれることが好ましいが、これらに限定されるものではない。具体例として、特許文献3、特許文献4、特許文献5、特許文献6、特許文献7、特許文献8、特許文献9、特許文献10、特許文献11、特許文献12、特許文献13、特許文献14、特許文献15、特許文献16、特許文献17、特許文献18、特許文献19等に開示されているフタロシアンニン類あるいはナフタロシアニン類、特許文献20、特許文献21、特許文献22、特許文献23、特許文献24、特許文献25等に開示されているようなアントラキノン類が挙げられる。   The near-infrared absorbing dye used in the present invention is an infrared absorbing material having absorption at 800 nm to 1400 nm, and is preferably selected from phthalocyanine compounds, naphthalocyanine compounds, anthraquinone compounds, diimonium compounds, and cyanine compounds, It is not limited to these. As specific examples, Patent Literature 3, Patent Literature 4, Patent Literature 5, Patent Literature 6, Patent Literature 7, Patent Literature 8, Patent Literature 9, Patent Literature 10, Patent Literature 11, Patent Literature 12, Patent Literature 13, Patent Literature. 14, Patent Literature 15, Patent Literature 16, Patent Literature 17, Patent Literature 18, Patent Literature 19, and the like, phthalocyanines or naphthalocyanines, Patent Literature 20, Patent Literature 21, Patent Literature 22, Patent Literature 23, Patent Document 24, Patent Document 25, and the like.

近赤外線吸収色素をくるむ樹脂は、硬化性樹脂であれば良く、熱硬化性樹脂、紫外線硬化性樹脂、荷電粒子線硬化性樹脂、電子線硬化性樹脂、などが挙げられる。求められる性能として、耐溶剤性を持つものであれば良く、例えば、ポリプロピレン、ポリエチレン、ポリアミドイミド等が上げられるが、フェノール樹脂やメラミン樹脂等の熱硬化性樹脂でも良く、これに限定されるものではない。   The resin enclosing the near-infrared absorbing dye may be a curable resin, and examples thereof include a thermosetting resin, an ultraviolet curable resin, a charged particle beam curable resin, and an electron beam curable resin. What is required is that it has solvent resistance, for example, polypropylene, polyethylene, polyamideimide and the like can be raised, but thermosetting resins such as phenol resin and melamine resin may be used, and are limited thereto. is not.

溶媒の分散体として用いられる油分としては、油性ワニスに含まれるものが好ましく、乾性油としては大豆油、桐油、アマニ油等であり、その他変性した乾性油でも、半乾性油でも使用することができる。さらに、ワニスに使用される溶剤でも良く、ノルマルパラフィン、イソパラフィン、ナフテン、α−オレフィン、その他の脂肪族炭化水素等の有機溶剤である。溶剤としては沸点200℃以上の高沸点溶剤が好ましい。例えば、0号ソルベント、5号ソルベント、7号ソルベント、AFソルベント(いずれも新日本石油株式会社製)等がある。   As the oil used as the solvent dispersion, those contained in the oil varnish are preferable, and the drying oil is soybean oil, tung oil, linseed oil, etc., and other modified drying oils or semi-drying oils may be used. it can. Furthermore, the solvent used for a varnish may be sufficient and it is organic solvents, such as normal paraffin, isoparaffin, naphthene, alpha-olefin, and other aliphatic hydrocarbons. As the solvent, a high boiling point solvent having a boiling point of 200 ° C. or higher is preferable. For example, there are 0 solvent, 5 solvent, 7 solvent, AF solvent (all manufactured by Nippon Oil Corporation) and the like.

上記記載の赤外線吸収色素と適宜溶剤または水に溶解もしくは分散した樹脂を混合し、基材上にコーティングし、これを剥離して、粉砕する。基材からの剥離は、かき落としや吸引、基材の延伸等の手段によって行われ、その後、油分と混合し、湿式粉砕を行う。粉砕は、ボールミル、コロイドミル、ハンマーミルなどの通常の手段によって行うことができ、適宜分級しても良く、樹脂にくるまれて成る赤外吸収色素の分散体の粒子は、1μm以下の粒径にする。   The infrared absorbing dye described above and a resin dissolved or dispersed in a solvent or water as appropriate are mixed, coated on a substrate, peeled off and pulverized. Peeling from the base material is performed by means such as scraping or suction, stretching of the base material, etc., and then mixed with oil and wet pulverized. The pulverization can be carried out by ordinary means such as a ball mill, a colloid mill, a hammer mill, etc., and may be classified as appropriate. The particles of the infrared absorbing dye dispersed in a resin have a particle size of 1 μm or less. To.

樹脂にくるまれて成る赤外吸収色素の分散体の粒子の粒径の測定は、JIS K5701に基づいてグラインドメーター(粒度測定器)を用い、深さ方向の連続的に変化している溝を有するゲージ盤にインキを入れて、溝の深い位置から浅い方向へ、スクレーパーを押し付けたまま均等の速さで引き動かし、密集した粒が現れ始めた目盛りを読み取り、読み取れない時は1μm以下とみなし、粒度測定を行った。この測定方法による測定値が1μmより大きい場合は、分散状態が悪く、また、薄い印刷をする場合に粒子が目立ち、面があれる他、特にオフセット印刷の場合にはブラン残りが起こり、ベタ刷り部にムラが出
たり、網刷り部の網点にがさつきが生じる為、1μm以下の粒径にする必要がある。
Measurement of the particle diameter of the dispersion of the infrared absorbing dye wrapped in the resin is based on JIS K5701, using a grindometer (particle size measuring instrument) to measure the continuously changing grooves in the depth direction. Put the ink in the gauge board and pull it from the deep position of the groove to the shallow direction with the scraper pressed at an even speed, read the graduation where dense grains began to appear, and if it can not be read, it will be regarded as 1μm or less The particle size was measured. If the value measured by this measurement method is larger than 1 μm, the dispersion state is poor, and when thin printing is performed, particles are conspicuous and have a surface. Since unevenness appears in the portion and the halftone dot of the halftone printing portion becomes rough, the particle size must be 1 μm or less.

次に、樹脂にくるまれた赤外線吸収色素の分散体と混合する、油性ワニスの樹脂としては、アルキド樹脂を含むポリエステル樹脂、石油樹脂、フェノール樹脂、ロジン変性フェノール樹脂、エポキシ樹脂、ケトン樹脂、ロジン、ロジン誘導体、ロジン変性マレイン酸樹脂等が好ましい。特に、ロジン変性フェノール樹脂としては、次のようなものがあげられる。p−オクチルフェノール、p−ノニルフェノールのようなp−アルキルフェノールとパラホルムアルデヒド、及びロジンをトルエンに溶解させ、酸、あるいは、アルカリ触媒下で反応後、グリセリン、ペンタエリスリトール、あるいは、ロジンを200℃で溶融し、レゾール樹脂を加えて反応後、グリセリンでエステル化したロジン変性フェノール樹脂、あるいは、ロジンのグリセリンエステルにレゾール樹脂を加えて反応させたロジン変性フェノール樹脂、あるいはロジン変性アルキド樹脂とフェノール樹脂を反応させたロジン変性フェノール樹脂等がある。   Next, the resin of the oil-based varnish mixed with the dispersion of the infrared absorbing pigment wrapped in the resin includes polyester resin including alkyd resin, petroleum resin, phenol resin, rosin-modified phenol resin, epoxy resin, ketone resin, rosin A rosin derivative, a rosin-modified maleic resin, and the like are preferable. Particularly, examples of the rosin-modified phenol resin include the following. p-Alkylphenol such as p-octylphenol, p-nonylphenol, paraformaldehyde, and rosin are dissolved in toluene, reacted in an acid or alkaline catalyst, and glycerin, pentaerythritol, or rosin is melted at 200 ° C. After the reaction by adding a resole resin, rosin-modified phenol resin esterified with glycerin, or rosin-modified phenol resin obtained by adding resole resin to glycerin ester of rosin, or rosin-modified alkyd resin and phenol resin are reacted. And rosin-modified phenolic resin.

油性ワニスの組成としては、重量比で樹脂/油/溶剤として10〜50/10〜60/10〜70で、トータル100となるような比率が適している。1例を挙げると、ロジン変性フェノール樹脂/アマニ油/石油系高沸点溶剤であり、40/10/50(重量比)である。なお本発明の濃縮インキ組成物としては、樹脂および溶剤を含まず、乾性油によって得られる組成物であってもよい。また、乾性油を含まず、樹脂および溶剤によって得られる組成物、樹脂および乾性油、樹脂および高沸点溶剤によって得られるものでもよい。例えばロジン変性フェノール樹脂/アマニ油(重量比40/60)やロジン変性フェノール樹脂/石油系高沸点溶剤(重量比50/50)である。また、乾性油を含まず、樹脂および溶剤によって得られる組成物、樹脂および乾性油、樹脂および高沸点溶剤によって得られるものでもよい。例えば分散体/ロジン変性フェノール樹脂/アマニ油(重量比10/40/50)や分散体/ロジン変性フェノール樹脂/石油系高沸点溶剤(重量比10/50/40)である。上記物質の他に、すくなくとも、ドライヤーとして鉛、マンガンのホウ酸塩を、添加剤として加える必要があるが、その重量比3%以下で良い。その他、印刷適性向上のために、ワックス、ワセリンポリエステル、エポキシ、トリアジン樹脂などの非反応性樹脂や表面改質剤を添加しても良いが、添加剤としては重量比5%程度である。   As the composition of the oily varnish, a ratio of 10 to 50/10 to 60/10 to 70 in terms of weight ratio of resin / oil / solvent and a total of 100 is suitable. One example is rosin-modified phenolic resin / linseed oil / petroleum high boiling point solvent, which is 40/10/50 (weight ratio). The concentrated ink composition of the present invention may be a composition that does not contain a resin and a solvent and is obtained from a drying oil. In addition, a composition obtained by using a resin and a solvent without containing a drying oil, or a composition obtained by using a resin and a drying oil, a resin and a high boiling point solvent may be used. For example, rosin modified phenolic resin / linseed oil (weight ratio 40/60) and rosin modified phenolic resin / petroleum high boiling point solvent (weight ratio 50/50). In addition, a composition obtained by using a resin and a solvent without containing a drying oil, or a composition obtained by using a resin and a drying oil, a resin and a high boiling point solvent may be used. For example, dispersion / rosin modified phenolic resin / linseed oil (weight ratio 10/40/50) and dispersion / rosin modified phenolic resin / petroleum high boiling point solvent (weight ratio 10/50/40). In addition to the above substances, at least lead and manganese borates need to be added as additives as a dryer, but the weight ratio may be 3% or less. In addition, in order to improve printability, non-reactive resins such as wax, petrolatum polyester, epoxy, and triazine resin and surface modifiers may be added, but the additive is about 5% by weight.

油性ワニスは、粘度としては、常温(25℃)で、100〜700(Pa・s、パスカル秒)の範囲が良い。また、流動性がJIS K5701に記載の流動特性試験によるスプレッドメーター直径値が10mm〜20mmであることが必要である。これは、セキュリティ用途での印刷として、スピードや速さ、多色刷りの観点から最も望まれている印刷方式の一つであるオフセット方式に求められる物性である。インキとして、一般的に柔らかくするのは簡単であるが、固くするのは難しい。固いインキであれば、希釈等により柔らかくすることもでき、調整しやすいため、上記のような粘度と流動性が求められる。   The oily varnish has a viscosity in the range of 100 to 700 (Pa · s, Pascal second) at normal temperature (25 ° C.). Moreover, it is necessary for the flow meter to have a spread meter diameter value of 10 mm to 20 mm according to a flow characteristic test described in JIS K5701. This is a physical property required for the offset method, which is one of the most desired printing methods from the viewpoint of speed, speed, and multicolor printing for security applications. As an ink, it is generally easy to make it soft, but it is difficult to make it hard. If it is a hard ink, it can be softened by dilution or the like, and it is easy to adjust, so that the above viscosity and fluidity are required.

本発明の赤外吸収インキの一例をあげると、樹脂に包まれた赤外線吸収色素の分散体/ロジン変性フェノール樹脂/アマニ油/石油系高沸点溶剤の組成は、10/40/10/40(重量比)を挙げることができる。   As an example of the infrared absorbing ink of the present invention, the composition of a dispersion of infrared absorbing pigment wrapped in resin / rosin modified phenolic resin / linseed oil / petroleum high boiling point solvent is 10/40/10/40 ( Weight ratio).

樹脂にくるまれた赤外線吸収色素の分散体と平版インキ用ワニスとの混合は、顔料粒子の練肉を必要とせず、単にミキサーにより平版インキ用ワニスを均一に混合し、最終インキにできる。
以下、実施例と比較例により本発明を詳細に説明する。
Mixing the dispersion of the infrared-absorbing dye wrapped in the resin with the lithographic ink varnish does not require the kneading of the pigment particles, and the lithographic ink varnish can be uniformly mixed by a mixer to obtain the final ink.
Hereinafter, the present invention will be described in detail by way of examples and comparative examples.

フタロシアニン色素イーエクスカラーIR−14(日本触媒株式会社製)20重量部をトルエン60重量部で溶解したポリエチレン樹脂20重量部の溶液に分散させ、厚さ25μmの無延伸のポリプロピレンフィルム上に紫外線硬化型インキを約70m/minの速さで塗工し、紫外線を照射して硬化させ、延伸することによって、剥離し、これをあまに油と混合し、ロールミルで粉砕し、分散体を得た。この分散体20重量部とロジン変性フェノール樹脂/大豆油/石油系高沸点溶剤の重量比が、40/10/50の油性ワニス0号ソルベントH(新日本石油製)80重量部とを常温でディスパーにて混合し、赤外線を吸収する酸化重合型のオフセットインキを得た。このインキの練和度をJIS K5701に基づいたグラインドメーターを用いた測定により、練和度は、1μm以下であった。スプレッドメーター直径値は、16.0mmだった。このインキをRIテスターにより、試験片を作製した。
Phthalocyanine dyes EXCOLOR IR-14 (manufactured by Nippon Shokubai Co., Ltd.) 20 parts by weight were dispersed in a solution of 20 parts by weight of a polyethylene resin dissolved in 60 parts by weight of toluene, on a polypropylene film unstretched thickness 25 [mu] m, UV A curable ink is applied at a speed of about 70 m / min, cured by irradiating with ultraviolet rays, and stretched to peel off, mixed with oil, and pulverized with a roll mill to obtain a dispersion. It was. 20 parts by weight of this dispersion and 80 parts by weight of oily varnish No. 0 Solvent H (manufactured by Nippon Oil) having a weight ratio of rosin-modified phenolic resin / soybean oil / petroleum high boiling solvent of 40/10/50 at room temperature Mixing with a disper, an oxidation polymerization type offset ink absorbing infrared rays was obtained. The kneading degree of this ink was 1 μm or less as measured by using a grindometer based on JIS K5701. The spread meter diameter value was 16.0 mm. A test piece was prepared from this ink using an RI tester.

<比較例>
フタロシアニン色素イーエクスカラーIR−14(日本触媒株式会社製)10重量部をロジン変性フェノール樹脂/大豆油/石油系高沸点溶剤の重量比が、40/10/50の油性ワニス 0号ソルベントH(新日本石油製)90重量部とを常温でディスパーにて混合し、赤外線を吸収する酸化重合型のオフセットインキを得た。このインキの練和度をJIS K5701に基づいた目盛り1.0μm間隔のグラインドメーター(粒度測定器)を用いた測定は、縦筋が出なかったため、測定限界下の1.0μm以下であった。このインキをRIテスターにより、上質紙に展色し、試験片を作製した。
<Comparative example>
10 parts by weight of phthalocyanine dye EEX Color IR-14 (manufactured by Nippon Shokubai Co., Ltd.) is an oily varnish No. 0 Solvent H having a weight ratio of rosin modified phenolic resin / soybean oil / petroleum high boiling solvent of 40/10/50 ( 90 parts by weight of Nippon Oil Co., Ltd. was mixed with a disper at room temperature to obtain an oxidation polymerization type offset ink that absorbs infrared rays. Measurement of the kneading degree of the ink using a grindometer (particle size measuring instrument) with a scale of 1.0 μm based on JIS K5701 was 1.0 μm or less below the measurement limit because no vertical streak appeared. This ink was developed on high-quality paper by an RI tester to prepare a test piece.

実施例と比較例で作製した試験片を分光光度計UV−3100(島津製作所製)で赤外線840nmの反射率を測定した後、以下の薬品についての耐性試験を行った。表1の薬品にそれぞれ、10分間浸漬した後、同じ分光光度計で840nmの反射率を測定した結果を表1に示した。比較例は溶剤に対し、反射率が高くなり、吸収が落ちていたが、本発明の実施例は、反射率に変化が見られず、耐薬品性に優れていることが分かる。また本発明の製造方法によれば、耐薬品性に優れた赤外吸収インキ組成物を効率よく得ることができる。

Figure 0005857392
The test pieces prepared in Examples and Comparative Examples were measured for the reflectance of infrared ray 840 nm with a spectrophotometer UV-3100 (manufactured by Shimadzu Corporation), and then subjected to a resistance test for the following chemicals. Table 1 shows the results of measuring the reflectivity at 840 nm with the same spectrophotometer after being immersed in the chemicals in Table 1 for 10 minutes. In the comparative example, the reflectance was higher and the absorption was lower than that of the solvent, but it was found that the examples of the present invention were excellent in chemical resistance with no change in the reflectance. Moreover, according to the manufacturing method of this invention, the infrared rays absorption ink composition excellent in chemical resistance can be obtained efficiently.
Figure 0005857392

Claims (1)

硬化性樹脂と赤外線吸収色素とを混合し、前記硬化性樹脂を硬化する工程と、硬化した前記赤外線吸収色素を含む硬化性樹脂を油分と混合し粉砕し分散体とする工程と、粉砕した前記赤外線吸収色素を含む分散体と樹脂を混合する工程、を有することを特徴とする赤外線吸収インキの製造方法。   Mixing the curable resin and the infrared absorbing dye, curing the curable resin, mixing the cured curable resin containing the infrared absorbing dye with oil, and pulverizing it into a dispersion; A method for producing an infrared-absorbing ink, comprising: mixing a dispersion containing an infrared-absorbing dye and a resin.
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