JP3724137B2 - Photocationic polymerizable silica fine particles, production method thereof, and photocationic curable resin composition - Google Patents

Description

【００１４】
そして、本発明の光カチオン硬化性樹脂組成物は、本発明の光カチオン重合性シリカ微粒子（ａ）と、
上記（ａ）以外の光カチオン重合性化合物（ｂ）と、
カチオン性光重合開始剤（ｃ）と、
を含むことを特徴とする。
【００１５】
本発明の組成物は、光カチオン重合により硬化するので空気中において高速硬化させることができ、また、高温加熱を必要とすることなく硬化させることができるため熱に弱い基材にも適用できる。更に、光カチオン重合性シリカ微粒子（ａ）を含むことから高硬度の硬化膜を形成可能であるので、この組成物はハードコート剤組成物として好適である。
【００１６】
【発明の実施の形態】
以下、本発明を詳細に説明する。
尚、本明細書においては、オキセタニル基を有する化合物を「オキセタン化合物」と表す。
【００１７】
（１）光カチオン重合性シリカ微粒子及びその製造方法について
本発明の光カチオン重合性シリカ微粒子における「オキセタニル基をもつ有機官能基」とは、上記式（ＩＩ）に示す構造式で表されるオキセタニル基をもつ有機官能基である。また、この有機官能基をシリカ微粒子の表面に「化学結合させる」方法としては、下記式（ＩＩＩ）に示す構造式で表されるシラン化合物を、シリカ微粒子表面の水酸基とカップリングさせる等の方法を用いることができる。
Ｒ^０ _ｙＳｉＸ_４−ｙ （ＩＩＩ）
（但し、Ｒ^０はオキセタニル基をもつ有機官能基であり、Ｘは加水分解性基であり、ｙは１、２または３である。）
【００１８】
このシラン化合物をカップリングさせる「シリカ微粒子」としては、一般的なコロイダルシリカが好適に用いられる。その粒子径は、０．００５μｍ〜１０μｍであることが好ましく、０．０１μｍ〜１μｍであることがより好ましい。シリカ微粒子の粒子径が上記範囲を超えると樹脂組成物中に均一に分散しない場合があり、一方上記範囲に満たない場合にはハードコーティング剤としての表面硬度が不足しやすいためである。
【００１９】
上記シラン化合物としては、上記式（Ｉ）に示す構造式で表される化合物を用いることが好ましい。また、上記式（Ｉ）におけるＲ^０は、上記式（ＩＩ）に示す構造式で表される基である。この式（ＩＩ）において、Ｒ^１は水素原子又は炭素数１〜６のアルキル基であり、Ｒ^１がエチル基であることが特に好ましい。また、Ｒ^２は炭素数２〜６のアルキレン基であり、Ｒ^２がプロピレン基であることが特に好ましい。これは、このようなオキセタン化合物の入手或いは合成が容易なためである。また、本発明の光カチオン重合性シリカ微粒子をハードコーティング剤組成物として用いる場合には、Ｒ^１又はＲ^２の炭素数が７以上であると、この組成物から形成された皮膜の表面硬度が不足しやすいので好ましくない。
【００２０】
上記式（Ｉ）におけるＲ³は、アルキル基、シクロアルキル基又はアリール基である。また、この化合物一分子中には三つのＲ³が含まれるが、これらは全て同じ基であってもよいし二種以上の異なる基であってもよい。
【００２１】
上記「アルキル基」としては、例えばメチル基、エチル基、ｎ−及びｉ−プロピル基、ｎ−、ｉ−及びｔ−ブチル基等が挙げられる。また、「シクロアルキル基」の例としてはシクロヘキシル基等が、「アリール基」の例としてはフェニル基等が挙げられる。このうち、加水分解性が良好であることから、Ｒ³が炭素数１〜３のアルキル基であることが好ましい。
【００２２】
上記シラン化合物と上記シリカ微粒子とを反応させる方法としては、例えばこれらの化合物を有機溶媒中で攪拌・混合すればよい。ここで、反応系を加熱してもよい。使用する有機溶媒は特に限定されないが、シリカゾルの安定性等の点から、メチルアルコール、エチルアルコール、イソプロピルアルコール等のアルコール類を用いることが好ましい。
【００２３】
また、本発明のシリカ微粒子は、粒子表面に化学結合された「オキセタニル基をもつ有機官能基」に加えて、粒子に吸着されたオキセタニル化合物、粒子を被覆するオキセタニル化合物等を有してもよい。
【００２４】
（２）光カチオン重合性化合物（ｂ）について
本発明の光カチオン硬化性樹脂組成物における光カチオン重合性化合物（ｂ）は特に限定されず、ビニルオキシ基、エポキシ基又はオキセタニル基等の光カチオン重合性基を有する化合物から選択された一種又は二種以上を用いることができる。
この化合物一分子の有する光カチオン重合性基の数は特に限定されないが、硬化性を向上させるためには二官能以上の光カチオン重合性化合物（ｂ）を用いることが好ましい。
【００２５】
光カチオン重合性化合物（ｂ）の具体例としては、ビニルオキシ基をもつものとしてエチルビニルエーテル等を、エポキシ基をもつものとしてビスフェノールＦジグリシジルエーテル等を、オキセタニル基をもつものとして１，４−ビス［（３−エチル−３−オキセタニルメトキシ）メチル］ベンゼン等を挙げることができる。
【００２６】
このうち、前述のように耐熱性が良く、接着力に優れ、且つ耐薬品性の良好な硬化物を形成可能であるため、エポキシド又はオキセタン化合物を用いることが好ましい。また、エポキシドに比べて一般に光重合速度がより速く、しかもより高い重合度が得られやすいことから、光カチオン重合性化合物（ｂ）としてはオキセタン化合物を用いることが特に好ましい。
尚、光カチオン重合性化合物（ｂ）は、この「オキセタン化合物」として上記式（Ｉ）で示される化合物を含んでもよく、また上記式（Ｉ）に示す化合物とシリカ微粒子とを反応させる際に生成された上記（ａ）以外の化合物であって光カチオン重合性を有するものを含んでもよい。
【００２７】
（３）カチオン性光重合開始剤（ｃ）について
本発明の光カチオン硬化性樹脂組成物におけるカチオン性光重合開始剤（ｃ）としては、一般的に使用されているカチオン性光重合開始剤のいずれもが使用可能である。このうち好ましい開始剤としては、ジアリルヨードニウム塩及びトリアリルスルホニウム塩等が挙げられる。
【００２８】
（４）各成分の混合割合について
本発明の光カチオン硬化性樹脂組成物における、光カチオン重合性シリカ微粒子（ａ）と光カチオン重合性化合物（ｂ）との好ましい混合割合は、各成分の組成及び本発明の組成物の用途によって異なるが、（ａ）成分／（ｂ）成分が重量比で０．５／９９．５〜５０／５０の範囲であることが好ましく、２／９８〜３０／７０の範囲であることがより好ましい。
光カチオン重合性シリカ微粒子（ａ）の割合が増すとともに硬化物の表面硬度は向上する傾向にある。しかし、このシリカ微粒子（ａ）の割合が５０重量％を超えると、シリカ微粒子が安定に存在できなくなる場合があり、樹脂がゲル化する恐れがある。更に、この組成物をコーティング剤として用いる場合には、シリカ微粒子（ａ）の割合が多すぎると、組成物の塗工性が低下したり、硬化膜の弾性や密着性等が不足したりする。一方、シリカ微粒子（ａ）の割合が０．５重量％未満であると、このシリカ微粒子（ａ）の添加効果が十分に発揮されない場合がある。
【００２９】
また、上記（ｃ）成分の添加量は、（ａ）成分と（ｂ）成分との合計重量に対して通常１〜１０重量％の範囲とすることが好ましく、３〜５重量％とすることがより好ましい。
【００３０】
本発明の光カチオン硬化性樹脂組成物は、上記（ａ）〜（ｃ）成分の他に、粘度調節剤、レベリング剤、安定剤、シランカップリング剤等の一般的な添加剤を含むことができる。また、この組成物は有機溶媒を含んでもよいが、その含有量は組成物全体に対して３０重量％以下であることが好ましく、２０重量％以下であることが更に好ましい。
【００３１】
【実施例】
以下、実施例により本発明を更に具体的に説明する。
【００３２】
（１）光カチオン重合性シリカ微粒子の合成
下記式(IV)に示すケイ素化合物とコロイダルシリカ表面の水酸基とをカップリングさせて、光カチオン重合性シリカ微粒子Ａを得た。以下において、この式(IV)に示すケイ素化合物を「Ｏｘｅ−ＴＲＩＥＳ」という。
【００３３】
【化３】

【００３４】
また、使用したコロイダルシリカの性状を下記に示す。
［コロイダルシリカ］
日産化学株式会社製、メタノールシリカゾル
商品名「スノーテックスＳＴ−ＭｅＯＨ」
粒子径；１０〜２０ｎｍ
ＳｉＯ₂含有量；３０．６ｗｔ％
Ｈ₂Ｏ含有量；１．５ｗｔ％
【００３５】
(1)攪拌機及び温度計を備えた反応器に、上記コロイダルシリカ（以下、「ＳＴ−ＭｅＯＨ」という。）２０．０４ｇ（ＳｉＯ₂として６．２４ｇ）を仕込み、攪拌しながら、Ｏｘｅ−ＴＲＩＥＳ１０．５７ｇ（３３．０ｍｍｏｌ）とトルエン４．０３ｇ（内標として）との混合溶液を徐々に滴下した。
(2)反応の進行をガスクロマトグラフィーにより追跡し、ガスクロマトグラムにおける面積比をトルエンと比較することにより、Ｏｘｅ−ＴＲＩＥＳの消費量及びエタノールの生成量を求めた。Ｏｘｅ−ＴＲＩＥＳの消費が観測されなくなり、新たにエタノールが生成されなくなった時点で反応を終了し、光カチオン重合性シリカ微粒子Ａを含む反応液Ａ(MeOH溶液)を得た。
【００３６】
上記方法により求めた、反応中におけるＯｘｅ−ＴＲＩＥＳの消費量及びエチルアルコールの生成量の推移を下記表１に示す。Ｏｘｅ−ＴＲＩＥＳの消費に従って、ほぼ理論量（即ち、消費されたＯｘｅ−ＴＲＩＥＳのモル数に対して３倍モル量）のエタノールが生成していることから、脱エタノール反応が良好に進行していることが判る。
【００３７】
【表１】

【００３８】
上記反応液Ａ(MeOH溶液)の一部から、下記の方法によりシリカ成分を単離精製し、その表面を分析した。
即ち、この反応液Ａ(MeOH溶液)から溶剤を留去し、残留固体を粉砕したのちトルエン中で６０分間の超音波洗浄を行った。次いで、０．２μｍのミリポアフィルタにより濾過し、更にトルエンで洗浄し、加熱真空引により乾燥させて白色粉末状固体を得た。
【００３９】
拡散反射赤外線スペクトル分析により、この物質の表面を分析した。得られたＩＲチャートを図１に示す。図１から判るように、シリカ微粒子Ａの表面において、２，８００〜３，０００ｃｍ^-1のＣＨ伸縮運動に起因する吸収をはじめとして、Ｏｘｅ−ＴＲＩＥＳに由来する特性吸収が観察された。従って、この白色粉末状固体はオキセタニル基の導入されたシリカであると推察される。また、上記の単離精製工程においてもオキセタニル基が除かれなかったことから、このオキセタニル基はシリカ表面に化学結合されているものと考えられる。
【００４０】
（２）光カチオン硬化性樹脂組成物の評価
下記表２に示す割合で、上記反応液Ａ(MeOH溶液)（光カチオン重合性シリカ微粒子Ａの含有量；３０重量％）、下記(Ｖ)に示す構造式で表される光カチオン重合性化合物（下記表２中では、「ＸＤ−Ｏｘｅｔａｎｅ」と表す。）を混合し、減圧下でメタノールを完全に留去したものに、カチオン性光重合開始剤（ｃ）としてのトリアリルスルフォニウムヘキサフルオロフォスフィン塩（（ａ）と（ｂ）との合計重量に対して２．５重量％）を混合して、光カチオン硬化性樹脂組成物ａ−１を調整した。この組成物ａ−１全体における光カチオン重合性シリカ微粒子Ａの含有量は５．０ｗｔ％である。
【００４１】
【化４】

【００４２】
また、比較例として、上記反応液Ａを添加しない樹脂組成物ｂ−１、及び、上記反応液Ａに代えてオキセタニル基が導入されていないコロイダルシリカ（スノーテックスＳＴ−ＭｅＯＨを使用）を用いた樹脂組成物ｂ−２を同様に調整した。
【００４３】
これらの組成物につき、下記の方法により硬化性及び鉛筆硬度を評価した。その結果を下記表２に併せて示す。
【００４４】
(1)硬化性
各組成物を、バーコーターを用いてガラス基板上に約２０μｍの厚さに塗布し、下記の条件により５回の紫外線照射を行った。照射後に表面のタックがなくなった場合を〇、表面にタックが残っている場合を×として評価した。
［ＵＶ照射条件］
ランプ：８０Ｗ／ｃｍ高圧水銀ランプ
ランプ高さ：１０ｃｍ
コンベアスピード：１０ｍ／ｍｉｎ
照射雰囲気：大気中
【００４５】
(2)鉛筆硬度
各組成物を、バーコーターを用いて鋼板上及びガラス基板上に約２０μｍの厚さに塗布し、上記照射条件で５回の紫外線照射を行って硬化膜を得た。この硬化膜につき、ＪＩＳ Ｋ ５４００に準じて表面の鉛筆硬度を測定した。
【００４６】
【表２】

【００４７】
表２から判るように、本発明の組成物ａ−１は、高温加熱を要することなく高速に光硬化させることができた。また、上記反応液Ａを添加しない樹脂組成物ｂ−１の鉛筆硬度がＨＢであるのに対して、この組成物から形成された硬化膜は鉛筆硬度が２Ｈであり、光カチオン重合性シリカ微粒子Ａの添加により表面硬度が向上した。そして、オキセタニル基が導入されていないコロイダルシリカを用いた組成物ｂ−２に比べて、組成物ａ−１によると表面硬度及び破壊強度の向上という利点があった。
【００４８】
尚、本発明においては、前記具体的実施例に示すものに限られず、目的、用途に応じて本発明の範囲内で種々変更した実施例とすることができる。例えば、上記実施例では、光カチオン重合性シリカ微粒子を合成した反応液を用いて光カチオン硬化性樹脂組成物を調整したが、この反応液から単離された光カチオン重合性シリカ微粒子を用いてもよい。
【００４９】
【発明の効果】
本発明の光カチオン重合性シリカ微粒子は、表面にオキセタニル基を有することにより、空気中においても良好な光重合性を示す。また、本発明の光カチオン硬化性組成物は、この光カチオン重合性シリカ微粒子を含むことから、高温加熱を要することなく且つ空気中で速やかに硬化して高硬度の膜を形成可能であるため、例えばハードコート剤組成物として有用である。
【図面の簡単な説明】
【図１】光カチオン重合性シリカ微粒子Ａの拡散反射ＩＲスペクトルを示すチャートである。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to silica fine particles having photocationic polymerizability and a method for producing the same, and further to a photocationic curable resin composition containing the silica fine particles. The photocationically polymerizable silica fine particles or the photocationic curable resin composition of the present invention is rapidly cured by photocationic polymerization without requiring high-temperature heating and forms a hardened cured film, for example, as a hard coating agent. Is preferred.
[0002]
[Prior art]
In the field of ultraviolet (UV) -initiated polymerization or ultraviolet-ray-initiated curing, photoinitiated radical polymerization using polyfunctional acrylates and unsaturated polyesters is widely studied and industrially used.
However, there is a problem that this radical polymerization is inhibited by oxygen in the air. In particular, when the coating composition is cured by radical polymerization, the influence of polymerization inhibition due to oxygen becomes more pronounced as the film thickness of the composition becomes thinner. Under an inert atmosphere, the composition can be cured quickly and completely. There is a restriction that it must be cured.
[0003]
In contrast, photoinitiated cationic polymerization, unlike the above-described photoinitiated radical polymerization, is not subject to polymerization inhibition by oxygen, and can be completely polymerized even in air. In particular, according to a composition using an epoxide or oxetane compound as a monomer, it is possible to obtain a cured product having good heat resistance, excellent adhesion, and good chemical resistance.
However, a cured product formed from a photocationic curable composition using the above epoxide or oxetane compound as a monomer generally has a relatively low surface hardness because the basic skeleton structure is a polyether. It was difficult to utilize as a hard coating agent composition.
[0004]
On the other hand, thermosetting silicone compositions are known in the field of hard coating agents. Although this composition is excellent in the hard coat performance of the cured film, it requires a large-scale coating facility, takes a long time for the heat curing process, and cannot be used for a heat-sensitive substrate because the curing conditions are high. There are problems such as.
[0005]
Also known is a material obtained by coupling acrylic silane to the surface of colloidal silica used for a thermosetting silicone hard coating agent (hereinafter referred to as “acrylic-modified colloidal silica”). This hard coating composition composed of acrylic-modified colloidal silica is superior in hard coat performance compared to conventional acrylic systems because it contains colloidal silica, and utilizes an ultraviolet curing mechanism of an acrylic group introduced on the surface of colloidal silica. And has the advantage of being curable at low temperatures.
[0006]
[Problems to be solved by the invention]
However, since the hard coating agent composition comprising the acrylic-modified colloidal silica is cured by radical polymerization of an acrylic group, the polymerization is inhibited by oxygen in the air as described above. In addition, in the use of forming a thin film like a hard coating agent composition, the influence of this polymerization inhibition by oxygen is particularly remarkable. For this reason, there has been a problem that the composition must be cured in an inert atmosphere.
[0007]
An object of the present invention is to provide a photocationically polymerizable silica fine particle that can be polymerized in air without requiring high-temperature heating, and a method for producing the same.
Another object of the present invention is to provide a photocationically curable resin composition containing the above-mentioned photocationically polymerizable silica fine particles, which can be cured in air without requiring high-temperature heating, and forms a cured product having a high surface hardness. Is to provide.
[0008]
[Means for Solving the Problems]
The present inventors have found that silica fine particles having an oxetanyl group chemically bonded to the surface have good photocationic polymerizability, and that a composition comprising the silica fine particles forms a cured film having high hardness. . Furthermore, the present invention was completed by finding a suitable method for producing the photocationically polymerizable silica fine particles.
[0009]
That is, the photocationically polymerizable silica fine particles of the present invention are obtained by reacting a silane compound represented by the structural formula represented by the following formula (III) with silica fine particles, and represented by the structural formula represented by the following formula (II). The organic functional group having an oxetanyl group is chemically bonded to the particle surface.
R ⁰ _y SiX _4-y (III)
(However, R ⁰ is an organic functional group having an oxetanyl group represented by the structural formula shown in the following formula (II), X is a hydrolyzable group, and y is 1, 2 or 3.)
[0010]
Since the silica fine particles of the present invention have an oxetanyl group on the surface, they exhibit good photopolymerization properties even in the air.
[0011]
The method for producing the photocationically polymerizable silica fine particles of the present invention is a method for producing the photocationically polymerizable silica fine particles of the present invention, wherein the silane compound and silica represented by the structural formula represented by the following formula ( III ) It is characterized by reacting with fine particles.
R ⁰ _y SiX _4-y (III)
(However, R ⁰ is an organic functional group having an oxetanyl group represented by the structural formula shown in the following formula (II) , X is a hydrolyzable group, and y is 1, 2 or 3. )
[0012]
R ⁰ is an organic functional group represented by the structural formula shown in the following formula (II). Further, as the silane compound represented by the structural formula shown in the above formula (III), a silane compound represented by the structural formula shown in the following formula (I) can be used.
R ⁰ Si (OR ³ ) ₃ (I)
(However, R ⁰ is an organic functional group having an oxetanyl group represented by the structural formula shown in the above formula (II), and R ³ is an alkyl group, a cycloalkyl group, or an aryl group.)
[0013]
[Chemical formula 2]

[0014]
And the photocationic curable resin composition of the present invention comprises the photocationically polymerizable silica fine particles (a) of the present invention,
A photocationically polymerizable compound (b) other than the above (a);
A cationic photopolymerization initiator (c);
It is characterized by including.
[0015]
Since the composition of the present invention is cured by cationic photopolymerization, it can be cured at a high speed in the air, and can be cured without requiring high-temperature heating, so that it can be applied to a heat-sensitive substrate. Furthermore, since the photocationic polymerizable silica fine particles (a) are contained, a cured film having a high hardness can be formed. Therefore, this composition is suitable as a hard coat agent composition.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail.
In the present specification, a compound having an oxetanyl group is referred to as an “oxetane compound”.
[0017]
(1) About Photocationic Polymerizable Silica Fine Particles and Method for Producing the Same “The organic functional group having an oxetanyl group” in the photocationic polymerizable silica fine particles of the present invention means oxetanyl represented by the structural formula shown in the above formula (II). Ru organic functional groups der with group. In addition, as a method of “chemically bonding” this organic functional group to the surface of the silica fine particles, a method of coupling a silane compound represented by the structural formula shown by the following formula (III) with a hydroxyl group on the surface of the silica fine particles, etc. Can be used.
R ⁰ _y SiX _4-y (III)
(However, R ⁰ is an organic functional group having an oxetanyl group, X is a hydrolyzable group, and y is 1, 2 or 3.)
[0018]
As the “silica fine particles” for coupling the silane compound, general colloidal silica is preferably used. The particle diameter is preferably 0.005 μm to 10 μm, and more preferably 0.01 μm to 1 μm. If the particle diameter of the silica fine particles exceeds the above range, it may not be uniformly dispersed in the resin composition. On the other hand, if it is less than the above range, the surface hardness as the hard coating agent tends to be insufficient.
[0019]
As the silane compound, it is preferable to use a compound represented by the structural formula shown in the formula (I). R ⁰ in the above formula (I) is a group represented by the structural formula shown in the above formula (II). In the formula (II), R ¹ is a hydrogen atom or an alkyl group having 1 to 6 carbon atoms, and R ¹ is particularly preferably an ethyl group. R ² is an alkylene group having 2 to 6 carbon atoms, and R ² is particularly preferably a propylene group. This is because it is easy to obtain or synthesize such oxetane compounds. In addition, when the photocationically polymerizable silica fine particles of the present invention are used as a hard coating agent composition, the surface hardness of a film formed from this composition when the carbon number of R ¹ or R ² is 7 or more. It is not preferable because it tends to be insufficient.
[0020]
R ³ in the above formula (I) is an alkyl group, a cycloalkyl group or an aryl group. Further, three R ³ are contained in one molecule of the compound, and these may all be the same group or two or more different groups.
[0021]
Examples of the “alkyl group” include a methyl group, an ethyl group, an n- and i-propyl group, an n-, i-, and a t-butyl group. Examples of the “cycloalkyl group” include a cyclohexyl group, and examples of the “aryl group” include a phenyl group. Among these, since the hydrolysis resistance is excellent, it is preferable R ³ is an alkyl group having 1 to 3 carbon atoms.
[0022]
As a method for reacting the silane compound and the silica fine particles, for example, these compounds may be stirred and mixed in an organic solvent. Here, the reaction system may be heated. The organic solvent to be used is not particularly limited, but alcohols such as methyl alcohol, ethyl alcohol, and isopropyl alcohol are preferably used from the viewpoint of the stability of silica sol.
[0023]
In addition to the “organic functional group having an oxetanyl group” chemically bonded to the particle surface, the silica fine particle of the present invention may have an oxetanyl compound adsorbed on the particle, an oxetanyl compound covering the particle, and the like. .
[0024]
(2) Photocationic polymerizable compound (b) The photocationic polymerizable compound (b) in the photocationic curable resin composition of the present invention is not particularly limited, and is a photocationic polymerization such as a vinyloxy group, an epoxy group, or an oxetanyl group. 1 type, or 2 or more types selected from the compound which has a sex group can be used.
The number of photocationically polymerizable groups contained in one molecule of the compound is not particularly limited, but it is preferable to use a bifunctional or higher functional photocationically polymerizable compound (b) in order to improve curability.
[0025]
Specific examples of the cationic photopolymerizable compound (b) include ethyl vinyl ether having a vinyloxy group, bisphenol F diglycidyl ether having an epoxy group, and 1,4-bis having an oxetanyl group. And [(3-ethyl-3-oxetanylmethoxy) methyl] benzene.
[0026]
Among them, as described above, it is preferable to use an epoxide or an oxetane compound because it can form a cured product having good heat resistance, excellent adhesion, and good chemical resistance. In addition, it is particularly preferable to use an oxetane compound as the photocationically polymerizable compound (b) because the photopolymerization rate is generally higher than that of the epoxide and a higher degree of polymerization is easily obtained.
The photocationically polymerizable compound (b) may contain a compound represented by the above formula (I) as this “oxetane compound”, and when reacting the compound represented by the above formula (I) with silica fine particles. A compound other than the produced (a) and having a cationic photopolymerization property may be included.
[0027]
(3) Cationic Photopolymerization Initiator (c) As the cationic photopolymerization initiator (c) in the photocationic curable resin composition of the present invention, a cationic photopolymerization initiator generally used is used. Either can be used. Among these, preferable initiators include diallyl iodonium salt and triallyl sulfonium salt.
[0028]
(4) Mixing ratio of each component The preferable mixing ratio of the photocationically polymerizable silica fine particles (a) and the photocationically polymerizable compound (b) in the photocationic curable resin composition of the present invention is the composition of each component. The component (a) / component (b) is preferably in the range of 0.5 / 99.5 to 50/50 by weight, although it varies depending on the use of the composition of the present invention. A range of 70 is more preferable.
The surface hardness of the cured product tends to improve as the proportion of the photocationically polymerizable silica fine particles (a) increases. However, if the proportion of the silica fine particles (a) exceeds 50% by weight, the silica fine particles may not be present stably, and the resin may be gelled. Furthermore, when this composition is used as a coating agent, if the ratio of the silica fine particles (a) is too large, the coating property of the composition is lowered, or the elasticity or adhesion of the cured film is insufficient. . On the other hand, when the proportion of the silica fine particles (a) is less than 0.5% by weight, the effect of adding the silica fine particles (a) may not be sufficiently exhibited.
[0029]
The amount of component (c) added is preferably in the range of usually 1 to 10% by weight, preferably 3 to 5% by weight, based on the total weight of component (a) and component (b). Is more preferable.
[0030]
The photocationic curable resin composition of the present invention may contain general additives such as a viscosity modifier, a leveling agent, a stabilizer, and a silane coupling agent in addition to the components (a) to (c). it can. Moreover, although this composition may contain an organic solvent, it is preferable that the content is 30 weight% or less with respect to the whole composition, and it is still more preferable that it is 20 weight% or less.
[0031]
【Example】
Hereinafter, the present invention will be described more specifically with reference to examples.
[0032]
(1) Synthesis of photocationically polymerizable silica fine particles Photocationic polymerizable silica fine particles A were obtained by coupling a silicon compound represented by the following formula (IV) and a hydroxyl group on the surface of colloidal silica. Hereinafter, the silicon compound represented by the formula (IV) is referred to as “Oxe-TRIES”.
[0033]
[Chemical 3]

[0034]
The properties of the colloidal silica used are shown below.
[Colloidal silica]
Product name "Snowtex ST-MeOH", manufactured by Nissan Chemical Co., Ltd.
Particle size: 10-20nm
SiO ₂ content: 30.6 wt%
H ₂ O content: 1.5 wt%
[0035]
(1) A reactor equipped with a stirrer and a thermometer was charged with 20.04 g (6.24 g as SiO ₂ ) of the colloidal silica (hereinafter referred to as “ST-MeOH”), and while stirring, Oxe-TRIES10. A mixed solution of 57 g (33.0 mmol) and 4.03 g of toluene (as an internal standard) was gradually added dropwise.
(2) The progress of the reaction was followed by gas chromatography, and the amount of Oxe-TRIES consumed and the amount of ethanol produced were determined by comparing the area ratio in the gas chromatogram with toluene. The reaction was terminated when consumption of Oxe-TRIES was not observed and ethanol was no longer generated, and a reaction liquid A (MeOH solution) containing photocationically polymerizable silica fine particles A was obtained.
[0036]
Table 1 below shows changes in the amount of Oxe-TRIES consumed during the reaction and the amount of ethyl alcohol produced during the reaction. According to the consumption of Oxe-TRIES, almost the theoretical amount (that is, 3 times the amount of moles of Oxe-TRIES consumed) of ethanol is generated, and the deethanol reaction proceeds well. I understand that.
[0037]
[Table 1]

[0038]
A silica component was isolated and purified from a part of the reaction solution A (MeOH solution) by the following method, and the surface was analyzed.
That is, the solvent was distilled off from the reaction solution A (MeOH solution), and the residual solid was pulverized, followed by ultrasonic cleaning in toluene for 60 minutes. Next, the mixture was filtered through a 0.2 μm Millipore filter, further washed with toluene, and dried by heating under vacuum to obtain a white powdery solid.
[0039]
The surface of this material was analyzed by diffuse reflectance infrared spectral analysis. The obtained IR chart is shown in FIG. As can be seen from FIG. 1, on the surface of silica fine particles A, characteristic absorption derived from Oxe-TRIES was observed, including absorption due to CH stretching motion of 2,800 to 3,000 cm ⁻¹ . Therefore, this white powdery solid is presumed to be silica with an oxetanyl group introduced. Further, since the oxetanyl group was not removed in the above-described isolation and purification step, it is considered that this oxetanyl group was chemically bonded to the silica surface.
[0040]
(2) Evaluation of Photocationic Curable Resin Composition In the proportion shown in Table 2 below, the above reaction solution A (MeOH solution) (content of photocationic polymerizable silica fine particles A; 30% by weight), The cationic photopolymerizable compound (in the following Table 2, represented as “XD-Oxetane”) represented by the structural formula shown was mixed, and methanol was completely distilled off under reduced pressure. A triallylsulfonium hexafluorophosphine salt (2.5% by weight based on the total weight of (a) and (b)) as the agent (c) is mixed, and the photocation curable resin composition a -1 was adjusted. The content of the photocationically polymerizable silica fine particles A in the entire composition a-1 is 5.0 wt%.
[0041]
[Formula 4]

[0042]
In addition, as a comparative example, the resin composition b-1 to which the reaction solution A was not added, and colloidal silica in which an oxetanyl group was not introduced in place of the reaction solution A (using Snowtex ST-MeOH) were used. Resin composition b-2 was similarly prepared.
[0043]
About these compositions, sclerosis | hardenability and pencil hardness were evaluated by the following method. The results are also shown in Table 2 below.
[0044]
(1) Curable Each composition was applied on a glass substrate to a thickness of about 20 μm using a bar coater, and irradiated with ultraviolet rays 5 times under the following conditions. The case where the surface tack disappeared after irradiation was evaluated as ◯, and the case where the surface tack remained was evaluated as x.
[UV irradiation conditions]
Lamp: 80 W / cm high-pressure mercury lamp Lamp height: 10 cm
Conveyor speed: 10m / min
Irradiation atmosphere: In air [0045]
(2) Pencil hardness Each composition was applied to a thickness of about 20 μm on a steel plate and a glass substrate using a bar coater, and irradiated with ultraviolet rays five times under the above irradiation conditions to obtain a cured film. About this cured film, the pencil hardness of the surface was measured according to JISK5400.
[0046]
[Table 2]

[0047]
As can be seen from Table 2, the composition a-1 of the present invention could be photocured at high speed without requiring high temperature heating. The resin composition b-1 to which the reaction solution A is not added has a pencil hardness of HB, whereas the cured film formed from this composition has a pencil hardness of 2H, and the photocationically polymerizable silica fine particles The addition of A improved the surface hardness. And compared with the composition b-2 using the colloidal silica in which the oxetanyl group was not introduce | transduced, according to the composition a-1, there existed an advantage of an improvement in surface hardness and a fracture strength.
[0048]
The present invention is not limited to the specific examples described above, and various modifications can be made within the scope of the present invention depending on the purpose and application. For example, in the above example, the photocation curable resin composition was prepared using the reaction liquid obtained by synthesizing the photo cation polymerizable silica fine particles, but the photo cation polymerizable silica fine particles isolated from the reaction liquid were used. Also good.
[0049]
【The invention's effect】
The photocationically polymerizable silica fine particles of the present invention have an oxetanyl group on the surface, and thus exhibit good photopolymerization properties even in the air. In addition, since the photocationic curable composition of the present invention contains the photocationically polymerizable silica fine particles, it can be rapidly cured in the air without forming at high temperature and can form a high hardness film. For example, it is useful as a hard coat agent composition.
[Brief description of the drawings]
FIG. 1 is a chart showing a diffuse reflection IR spectrum of photocationically polymerizable silica fine particles A.

Claims (4)

An organic functional group having an oxetanyl group represented by the structural formula represented by the following formula (II) is obtained on the particle surface by reacting a silane compound represented by the structural formula represented by the following formula (III) with silica fine particles. Photocationically polymerizable silica fine particles characterized by being chemically bonded.
R ⁰ _y SiX _4-y (III)
(However, R ⁰ is an organic functional group having an oxetanyl group represented by the structural formula shown in the following formula (II), X is a hydrolyzable group, and y is 1, 2 or 3.)

(However, R ¹ is a hydrogen atom or an alkyl group having 1 to 6 carbon atoms, and R ² is an alkylene group having 2 to 6 carbon atoms.) The method for producing photocationically polymerizable silica fine particles according to claim 1, wherein a silane compound represented by the structural formula represented by the following formula ( III ) is reacted with silica fine particles.
R ⁰ _y SiX _4-y (III)
(However, R ⁰ is an organic functional group having an oxetanyl group represented by the structural formula shown in the following formula (II) , X is a hydrolyzable group, and y is 1, 2 or 3. )

(However, R ¹ is a hydrogen atom or an alkyl group having 1 to 6 carbon atoms, and R ² is an alkylene group having 2 to 6 carbon atoms.) The method for producing photocationically polymerizable silica fine particles according to claim 2, wherein the silane compound represented by the structural formula represented by the formula (III) is a silane compound represented by the structural formula represented by the following formula (I) .
R ⁰ Si (OR ³ ) ₃ (I)
(However, R ⁰ is an organic functional group having an oxetanyl group represented by the structural formula shown in the above formula (II), and R ³ is an alkyl group, a cycloalkyl group, or an aryl group.) The photocationically polymerizable silica fine particles (a) according to claim 1,
A photocationically polymerizable compound (b) other than the above (a);
A cationic photopolymerization initiator (c);
A photocationically curable resin composition comprising:

Images