JP5000800B2 - Inorganic film-forming coating agent, inorganic film-forming method, inorganic film-coated aluminum material and inorganic film-coated steel material obtained by using the same - Google Patents
Inorganic film-forming coating agent, inorganic film-forming method, inorganic film-coated aluminum material and inorganic film-coated steel material obtained by using the same Download PDFInfo
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Description
【0001】
【発明の属する技術分野】
本発明は、金属の防食性に優れた無機膜を形成する無機形成用塗布剤及びそれを塗布し乾燥して無機膜を形成する方法及びその無機膜被覆アルミニウム材、無機膜被覆鋼材に関する。
【0002】
【従来の技術及びその課題】
空調機の熱交換器用のフィン基材としては、軽量性、加工性、熱伝導性に優れたアルミニウム又はアルミニウム合金に化成処理を施したものが一般に使用されている。
【0003】
空調機の熱交換器は冷房時に発生する凝縮水が水滴となってフィン間に水のブリッジを形成し、空気の通風路を狭めるため通風抵抗が大きくなって電力の損失、騒音の発生、水滴の飛散などの不具合が発生するといった問題がある。かかる現象を防止する方策として、例えば、アルミニウム製フィン材(以下、「フィン材」という)の表面を親水化処理して水滴及び水滴によるブリッジの形成を防止することが行われている。
【0004】
しかしながら、これらの方法で得られる親水化処理皮膜を形成したフィン材は、皮膜が親水性を有することもあって、強い腐食環境下に置かれていると、数ケ月程度で腐食されてしまうといった問題があった。
【0005】
この問題を解決する方法として、耐食性、コストなどの面から基材であるアルミニウム又はアルミニウム合金材表面にクロメート処理を施す方法が多く行われている。しかしながら、クロメート処理はクロムイオンが有害金属イオンであるため環境保全の面から問題がある。
【0006】
また、上記したクロムイオンを使用しない下地処理剤や処理方法としても公知であり、例えば、チタン塩(ジルコニウム塩)、過酸化水素及び(縮合)リン酸(誘導体)を含有する酸性溶液で処理するアルミニウム表面処理法(特開昭54−24232号公報)、アルミニウムをチタンイオン(ジルコニウムイオン、鉄イオン)、錯化剤を含有するアルカリ性水溶液で処理し、水洗後、リン酸等の酸性水溶液で処理するアルミニウム表面処理法(特開昭54−160527号公報)、リン酸イオン、チタン化合物、フッ化物及び促進剤を含むアルミニウム表面処理組成物(特開平9−20984号公報)、(縮合)リン酸(塩)、チタニウム塩(ジルコニム塩)、フッ化物、(次)亜リン酸(塩)を含有するアルミニウム系金属表面処理用組成物(特開平9−143752号公報)などが挙げられる。
【0007】
しかしながら、上記したチタン化合物を使用した下地処理剤や処理方法は、下地処理剤の安定性が十分でないこと、クロメート処理と比較して耐食性が十分でないこと、親水性が十分でないこと及び耐久性が十分でないことなどの問題点があった。
また、近年、防錆被覆鋼板には優れた耐食性が要求され、従来の冷延鋼板にかわり亜鉛系めっき鋼板を基板とする表面処理鋼板が多く使用されている。
【0008】
従来、亜鉛系めっき鋼板の表面処理として、クロム酸塩処理及びリン酸亜鉛処理が一般に行われているが、クロムの毒性が問題になっている。クロム酸塩処理は、処理工程でのクロム酸塩ヒュームの揮散の問題、排水処理設備に多大の費用を要すること、さらには化成処理被膜からのクロム酸の溶出による問題などがある。また6価クロム化合物は、IARC(International Agency for Researchon Cancer Review)を初めとして多くの公的機関が人体に対する発癌性物質に指定しており極めて有害な物質である。
【0009】
またリン酸亜鉛処理では、リン酸亜鉛処理後、通常、クロム酸によるリンス処理を行うためクロム処理の問題があるとともに、リン酸亜鉛処理剤中の反応促進剤、金属イオンなどの排水処理、被処理金属からの金属イオンの溶出によるスラッジ処理の問題がある。
【0010】
クロム酸塩処理やリン酸亜鉛処理以外の処理方法としては、(1)重燐酸アルミニウムを含有する水溶液で処理した後、150〜550℃の温度で加熱する表面処理方法(特公昭53-28857号公報参照)、(2)タンニン酸を含有する水溶液で処理する方法(特開昭51-71233号公報参照)などが提案され、また、(3)亜硝酸ナトリウム、硼酸ナトリウム、イミダゾール、芳香族カルボン酸、界面活性剤等による処理方法もしくはこれらを組合せた処理方法が行われている。
【0011】
しかしながら、(1)の方法は、この上に塗料を塗装する場合、塗料の密着性が十分でなく、また、(2)の方法は、耐食性が劣り、(3)の方法は、いずれも高温多湿の雰囲気に暴露された場合の耐食性が劣るという問題がある。
【0012】
また、膜厚数μm以下の薄膜の被膜を有する亜鉛系鋼板として、特開昭58-224174 号公報、特開昭60-50179号公報、特開昭60-50180号公報などには、亜鉛系めっき鋼板を基材とし、これにクロメート被膜を形成し、さらにこの上に最上層として有機複合シリケート被膜を形成した防錆鋼板が知られており、このものは、加工性及び耐食性に優れた性能を有する。しかしながら、この防錆鋼板はクロメート被膜を有するため、前記したと同様にクロメートイオンによる安全衛生面の問題があった。また、この防錆鋼板からクロメート被膜を除いた鋼板では、いまだ耐食性が十分ではない。
本発明の目的は、特に金属の防食性に優れた無機の膜を形成する無機形成用塗布剤及びそれを塗布し乾燥して無機膜を形成する方法を提供することである。
【0013】
また、本発明の目的は、耐食性に優れ、クロムを含有しない下地処理被膜の特に熱交換器アルミニウムフィン材に適したの無機膜被覆アルミニウム材を提供することである。
【0014】
さらに、本発明の目的は、亜鉛系めっき鋼板にクロメート被膜がなくても、優れた耐食性を発揮する無機膜被覆鋼材を提供することである。
【0015】
【課題を解決するための手段】
本発明者らは、鋭意研究の結果、特定の弗化物と特定の加水分解性モノマー及び/又はその低縮合物とを反応させてなる無機膜形成用塗布剤が、従来からの問題点を解消することを見出し、本発明を完成するに至った。
【0016】
かくして本発明によれば、下記成分
(A)チタン弗化水素酸及びジルコニウム弗化水素酸から選ばれる少なくとも1種の弗化物、及び(B)一般式 M(OR) 4 (式中、Mはチタン原子であり、Rは同一もしくは異なって炭素数1〜4のアルキル基を示す)である加水分解性モノマー及び/又はその低縮合物を反応させてなることを特徴とする無機膜形成用塗布剤が提供される。
【0017】
また、本発明は、上記無機膜形成用塗布剤を、基材に塗布し、必要に応じて加熱処理して形成させることを特徴とする無機膜形成方法が提供される。
また、本発明は、アルミニウム材又はアルミニウム合金材表面に、上記無機膜形成用塗布剤から形成されてなる無機膜が形成されてなることを特徴とする無機膜被覆アルミニウム材が提供される。
【0018】
更に、本発明は、鋼材表面に、上記無機膜形成用塗布剤から形成されてなる無機膜が被覆されてなることを特徴とする無機膜被覆鋼材が提供される。
【0019】
【発明の実施の形態】
まず、本発明の無機膜形成用塗布剤について説明する。
【0020】
本発明の無機膜形成用塗布剤は、(A)ケイ弗化水素酸、チタン弗化水素酸、及びジルコニウム弗化水素酸から選ばれる少なくとも1種の弗化物(以下、このものを単に「弗化物(A)」と略すことがある。)、及び(B)全てが加水分解性基により置換されたシリコンモノマ−、チタンモノマー、ジルコニウムモノマーから選ばれる少なくとも1種の加水分解性モノマー及び/又はその低縮合物(以下、これらのものをまとめて単に「加水分解性化合物(B)」と略すことがある。)を反応させてなるものである。
【0021】
上記弗化物(A)は、ケイ弗化水素酸、チタン弗化水素酸、及びジルコニウム弗化水素酸であり、H2MF6 (Mは上記と同じ意味を表す。)で表されるものである。
【0022】
上記弗化物(A)と反応させるために使用される加水分解性モノマーは、シリコン、チタン及びジルコニウムの原子に直接加水分解性基が全て結合したものである。該加水分解性基は加水分解反応により水酸基を生じる官能基である。該加水分解性基としては、従来から公知のものであれば制限はないが、特に加水分解性に優れること、無着色の点から低級アルコキシル基が好ましい。
【0023】
加水分解性モノマーとしては、特に、一般式 M(OR)4 (式中、Mはシリコン原子、チタン原子又はジルコニウム原子であり、Rは同一もしくは異なって炭素数1〜4のアルキル基を示す)のテトラアルコキシ化合物が好ましい。炭素数1〜4のアルキル基としては、例えば、メチル基、エチル基、n-プロピル基、iso-プロピル基、n-ブチル基、iso-ブチル基、sec-ブチル基、tert-ブチル基等が挙げられる。
【0024】
該加水分解性モノマーとして、具体的には、例えば、テトラメトキシシラン、テトラエトキシシラン、テトラプロポキシシラン、テトラブトキシシシラン、トリメトキエトキシシラン、ジメトキシジエトキシシラン、トリエトキシメトキシシラン、テトラメトキシチタン、テトラエトキシチタン、テトラプロポキシチタン、テトラブトキシシチタン、トリメトキエトキシチタン、ジメトキシジエトキシチタン、トリエトキシメトキシチタン、テトラメトキシジルコニウム、テトラエトキシジルコニウム、テトラプロポキシジルコニウム、テトラブトキシシジルコニウム、トリメトキエトキシジルコニウム、ジメトキシジエトキシジルコニウム、トリエトキシメトキシジルコニウム等が好適なものとして挙げられる。
【0025】
加水分解性モノマーの低縮合物としては、上記した加水分解性モノマーをお互いに加水分解して縮合反応させた低縮合物を使用することができる。低縮合物の縮合度は2〜30、特に縮合度2〜10の範囲内のものを使用することが好ましい。該加水分解縮合反応は、従来から公知の方法、例えば、加水分解性モノマーを水及び触媒(例えば、塩基性触媒、酸性触媒等)の存在下で常温もしくは加熱により反応を行うことができる。上記反応は、必要に応じて、例えば、メタノ−ル、エタノ−ル、イソプロピルアルコ−ル、エチレングリコ−ル系、プロピレングリコ-ル系等の親水性溶剤中で行うことができる。
【0026】
上記弗化物(A)と加水分解性化合物(B)との反応割合は、弗化物(A)1に対して、加水分解性化合物(B)を0.1〜10重量比、好ましくは0.5〜10重量比の範囲で反応させることが望ましい。加水分解性化合物(B)が0.1未満になると造膜性が低下し、耐食性が劣り、一方、加水分解性化合物(B)が10を超えると弗化物の比率が低下し、耐食性が劣るので好ましくない。
また、上記弗化物(A)と加水分解性化合物(B)との反応は、反応温度1〜 70℃、好ましくは、5〜70℃の範囲内で5分〜20時間、好ましくは、5分〜10時間反応させることにより製造できる。
【0027】
弗化物(A)と加水分解性化合物(B)との反応により製造された本発明の無機膜形成用塗布剤は、弗化物(A)と加水分解性化合物(B)との反応物、及び弗化物(A)、加水分解性化合物(B)の混合物も含むことができる。弗化物(A)と加水分解性化合物(B)との反応物の構成は明白ではないが、弗化物(A)と加水分解性化合物(B)とが直鎖状、分岐状、又はこれらの構造が組合わさったものと考えられる。また、分子末端は弗化物(A)反応構成成分であっても加水分解性化合物(B)反応構成成分であっても構わない。
【0028】
また、該反応物中には、MOR(H)基及びMF基を含有するものであるが、該反応物を有する本発明の無機膜形成用塗布剤を塗装した後、乾燥又は焼付けによりMOR(H)基及びMF基は、実質的には残存しない、完全な無機膜が形成されると考えられる。
【0029】
本発明の無機膜形成用塗布剤は、必要に応じて、例えば、メタノ−ル、エタノ−ル、イソプロピルアルコ−ル、エチレングリコ−ル系、プロピレングリコ-ル系等の親水性溶剤で希釈して使用することができる。
【0030】
本発明の無機膜形成用塗布剤には、必要に応じて、例えば、上記した成分以外に、必要に応じて界面活性剤、防菌剤、防錆剤(タンニン酸、フィチン酸、ベンゾトリアゾールなど)、着色顔料、体質顔料、防錆顔料などの顔料類などを含有することができる。
【0031】
本発明の無機膜形成用塗布剤は、塗装固形分として、通常0.01〜10重量%、特に0.1〜5重量%が好ましい。固形分が0.01重量%未満になると、造膜性が不十分となり、耐食性が劣り、一方10重量%を超えると、膜にワレを生じ、耐食性が劣るので好ましくない。
【0032】
本発明の無機膜形成用塗布剤は、酸性領域で安定な液体となり、特にPH0.5〜5、特に0.5〜3の範囲が好ましい。
本発明の無機膜形成用塗布剤は、基材に塗布し、必要に応じて加熱処理して形成させることにより無機膜を形成させることができる。
【0033】
該基材としては、特に制限なしに、例えば、ポリ塩化ビニル樹脂、ポリエチレンテレフタレート、アクリル系樹脂、シリコン系樹脂、ポリエステル系樹脂、弗素系樹脂、エポキシ系樹脂、ポリエチレン樹脂、ナイロン樹脂、ブチラール樹脂、繊維素樹脂、フェノール樹脂、及びこれら2種以上の樹脂のものが組合わさった樹脂や表面処理やプライマーが施されたプラスチック基材、ガラス、セメント等の無機基材、紙、繊維等のパルプ基材、鉄鋼、アルミニウム、銅、ステンレス、亜鉛、錫、これら2種以上の金属が組合わさったものや表面処理やプライマーが施された金属基材などが挙げられる。
【0034】
本発明の無機膜形成用塗布剤において、該塗布剤をアルミニウム材又はアルミニウム合金材に適用して得られる無機膜被覆アルミニウム材、及び鋼材、金属表面のリン酸塩処理皮膜表面に適用して得られる無機膜被覆鋼材について、以下に説明する。
【0035】
無機膜被覆アルミニウム材:
アルミニウム材上に本発明の無機膜形成用塗布剤を塗装し乾燥させることによって無機膜を形成することができる。無機膜形成用塗布剤は、基材であるアルミニウム材(例えば、アルミニウムフィン材などの如き熱交換器に組み立てられたものであってもよい)上に、それ自体既知の塗装方法、例えば、浸漬塗装、シャワー塗装、スプレー塗装、ロール塗装、電着塗装などによって塗装することができる。無機膜形成用塗布剤の乾燥条件は、通常、素材到達最高温度が約60〜250℃となる条件で約2秒から約30分間乾燥させることが好適である。
【0036】
また、無機膜形成用塗布剤の乾燥膜厚としては通常、0.001〜10μm、特に0.1〜3μmの範囲が好ましい。0.001μm未満になると、耐食性、耐水性などの性能が劣り、一方10μmを超えると、無機膜が割れたり親水性などが劣るので好ましくない。
【0037】
無機膜被覆鋼材:
下記鋼材表面に本発明の無機膜形成用塗布剤を塗装し乾燥させることによって無機膜形成用塗布剤を形成することができる。無機膜形成用塗布剤は、下記鋼材(例えば、組み立てられたものであってもよい)上に、それ自体既知の塗装方法、例えば、浸漬塗装、シャワー塗装、スプレー塗装、ロール塗装、電着塗装などによって塗装することができる。無機膜形成用塗布剤の乾燥条件は、通常、素材到達最高温度が約60〜250℃となる条件で約2秒から約30分間乾燥させることが好適である。
【0038】
また、無機膜形成用塗布剤の乾燥膜厚としては通常、0.001〜10μm、特に0.1〜3μmの範囲が好ましい。0.001μm未満になると、耐食性、耐水性などの性能が劣り、一方10μmを超えると、無機膜が割れたり親水性などが劣るので好ましくない。
【0039】
鋼材としては、好ましくは溶融亜鉛めっき鋼板、電気亜鉛めっき鋼板、鉄−亜鉛合金めっき鋼板、ニッケル−亜鉛合金めっき鋼板、アルミニウム−亜鉛合金めっき鋼板(例えば、「ガルバリウム」、「ガルファン」という商品名で販売されている合金めっき鋼板)などを挙げることができる。また、亜鉛系めっき鋼板として、クロム酸塩処理、リン酸亜鉛処理、複合酸化膜処理などの化成処理を施した亜鉛系めっき鋼板も使用することもできる。
【0040】
該無機膜被覆鋼材は、耐食性、耐指紋性などに優れ、そのまま防錆鋼板、潤滑防錆鋼板として使用することもできるが、この上に、さらに上層被膜を形成することもできる。この上層被膜を形成する組成物は、目的に応じて適宜選定すればよく種々の塗料組成物を使用することができる。この塗料組成物としては、例えば、プライマー塗料、着色上塗塗料などを挙げることができる。プライマー塗料を塗装し、さらにその上に着色上塗塗料を塗装してもよい。
【0041】
【発明の効果】
本発明において、上記した構成を有する無機膜形成用塗布剤を、例えば、アルミニウム、電気亜鉛メッキ鋼板等の金属基材に塗装、加熱して無機膜を形成することにより、無機膜形成用塗布剤を構成する弗化物(A)構成成分は金属腐食の抑制剤として作用し、一方、加水分解性化合物(B)構成成分は酸化珪素、酸化チタン、酸化ジルコニウムなどの如き酸化金属膜又は酸化珪素膜を形成するので酸素透過性の少ない無機膜が形成されるので防食性に優れた無機膜が形成され、そして(A)構成成分と(B)構成成分とが化学結合しているので、金属腐食の抑制剤として働き金属素材に配位した弗化物(A)構成成分を(B)構成成分の酸化金属膜又は酸化珪素膜で保護するために高防食性、高耐久性の無機膜が形成されたものと推察される。
【0042】
【実施例】
以下、実施例及び比較例を挙げて本発明をさらに具体的に説明する。以下、「部」および「%」はそれぞれ「重量部」および「重量%」を意味する。本発明は以下の実施例に制限されるものではない。
【0043】
無機膜形成用塗布剤(1)の製造例
テトラiso-プロポキシチタン2.0部とエタノール48部の混合物を40%チタン弗化水素酸1.5部と脱イオン水48.5部の混合物中に20℃で1時間かけて撹拌しながら滴下した。白濁の無機膜形成用塗布剤(1)を得た。
【0044】
無機膜形成用塗布剤(2)の製造例
製造例1のテトラiso-プロポキシチタンの代わりにテトラn−ブトキシチタンを使用して同様の製造条件で白濁の無機膜形成用塗布剤(2)を得た。
【0045】
無機膜形成用塗布剤(3)の製造例
製造例1のチタン弗化水素酸の代わりに40%ジルコニウム弗化水素酸を使用して同様の製造条件で白濁の無機膜形成用塗布剤(3)を得た。
【0046】
無機膜形成用塗布剤(4)の製造例
チタン処理剤(1)の製造例において、40%チタン弗化水素酸6部を使用して同様の製造条件で透明の無機膜形成用塗布剤(4)を得た。
【0047】
無機膜形成用塗布剤(5)の製造例
テトラiso−プロポキシチタン2.0部とエタノール48部の混合物を脱イオン水50部の混合物中に20℃で1時間かけて攪拌しながら滴下した。白濁の無機膜形成用塗布剤(5)を得た。
【0048】
無機膜形成用塗布剤(6)の製造例
40%チタン弗化水素酸6部と脱イオン水94部を混合し、透明の無機膜形成用塗布剤(6)を得た。
【0049】
無機膜形成用塗布剤(7)の製造例
40%ジルコニア弗化水素酸6部と脱イオン水94部を混合し、透明の無機膜形成用塗布剤(7)を得た。
【0050】
無機膜形成用塗布剤(1)〜(4)(実施例)、無機膜形成用塗布剤(5)〜(7)(比較例)を得た。
【0051】
試験板の作成A: 板厚0.1mmのアルミニウム板(A1050)を、アルカリ脱脂剤(日本シービーケミカル(株)製、商品名「ケミクリーナー561B」)を溶解した濃度2%の水溶液を使用して脱脂、水洗した後、上記実施例及び比較例で得た下地処理剤を乾燥皮膜重量が0.2g/m2となるように塗布し、素材到達温度が100℃になるようにして20秒間焼付けて下地処理皮膜を形成した。
【0052】
得られた各試験塗板に耐食性の試験を行った。その試験結果を後記表1に示す。試験は下記の試験方法に従って行った。
【0053】
耐食性:JIS−Z−2371塩水噴霧試験法に準ずる。試験時間は120時間、240時間及び360時間の3段階とし、下記基準により評価した。
○…塗面に白サビ、フクレの発生が認められない
△…白サビ又はフクレが少し発生
×…白サビ又はフクレが著しく発生。
【0054】
試験板の作成B: 板厚0.6mm、片面のめっき付着量20g/m2 の電気亜鉛めっき鋼板を、アルカリ脱脂剤(日本シービーケミカル(株)製、商品名「ケミクリーナー561B」)を溶解した濃度2%の水溶液を使用して脱脂、水洗した後、上記実施例及び比較例で得た下地処理剤を乾燥皮膜重量が1.0g/m2となるように塗布し、素材到達温度が100℃になるようにして20秒間焼付けて下地処理皮膜を形成した。
得られた各試験塗板に耐食性の試験を行った。その試験結果を後記表2に示す。試験は下記の試験方法に従って行った。
【0055】
耐食性:試験塗板の端面部及び裏面部をシールした試験塗板に、JIS Z2371に規定する塩水噴霧試験を72時間まで行い、24時間経過時及び48時間経過時における塗膜面の錆の程度を下記基準により評価した。
a:白錆の発生が認められない、
b:白錆の発生程度が塗膜面積の5%未満、
c:白錆の発生程度が塗膜面積の5%以上で10%未満、
d:白錆の発生程度が塗膜面積の10%以上で50%未満、
e:白錆の発生程度が塗膜面積の50%以上。
【0056】
試験板の作成C
板厚0.6mm、片面のめっき付着量20g/m2 の電気亜鉛めっき鋼板を、基材として用いた。
上記めっき鋼板の表面をアルカリ脱脂した後、表面調整(日本パーカライジング(株)製の「プレパレンZ」を用いたスプレー処理)を行い、さらにリン酸亜鉛処理(日本パーカライジング(株)製の「パルボンド3308」を用いたスプレー処理)を行った後、水洗、乾燥してリン酸亜鉛処理を施した各種めっき鋼板を得た。リン酸亜鉛処理皮膜の付着量は1.5g/m2とした。
【0057】
上記リン酸亜鉛処理を施した各種めっき鋼板表面に上記実施例及び比較例で得た下地処理剤を乾燥皮膜重量が1.0g/m2となるように塗布し、素材到達温度が100℃になるようにして20秒間焼付けて下地処理皮膜を形成した。
得られた各試験塗板に耐食性の試験を行った。その試験結果を後記表3に示す。試験は下記の試験方法に従って行った。
【0058】
耐食性:試験塗板の端面部及び裏面部をシールした試験塗板に、JIS Z2371に規定する塩水噴霧試験を72時間まで行い、24時間経過時及び48時間経過時における塗膜面の錆の程度を下記基準により評価した。
a:白錆の発生が認められない、
b:白錆の発生程度が塗膜面積の5%未満、
c:白錆の発生程度が塗膜面積の5%以上で10%未満、
d:白錆の発生程度が塗膜面積の10%以上で50%未満、
e:白錆の発生程度が塗膜面積の50%以上。
試験結果を以下に示す。
表1
【0059】
【表1】
【0060】
【表2】
【0061】
【表3】
[0001]
BACKGROUND OF THE INVENTION
TECHNICAL FIELD The present invention relates to an inorganic forming coating agent that forms an inorganic film excellent in metal anticorrosion, a method for forming the inorganic film by applying it and drying, an inorganic film-coated aluminum material, and an inorganic film-coated steel material.
[0002]
[Prior art and problems]
As a fin base material for a heat exchanger of an air conditioner, a material obtained by subjecting aluminum or an aluminum alloy excellent in lightness, workability, and heat conductivity to chemical conversion is generally used.
[0003]
In the air conditioner heat exchanger, the condensed water generated during cooling becomes water droplets to form a water bridge between the fins, narrowing the air ventilation path, increasing the resistance to ventilation, resulting in power loss, noise generation, water droplets There is a problem that problems such as splashing occur. As a measure for preventing such a phenomenon, for example, the surface of an aluminum fin material (hereinafter referred to as “fin material”) is subjected to a hydrophilic treatment to prevent water droplets and bridge formation due to water droplets.
[0004]
However, the fin material on which the hydrophilized film obtained by these methods is formed may be corroded in several months if it is placed in a strong corrosive environment because the film has hydrophilicity. There was a problem.
[0005]
As a method for solving this problem, a method of performing chromate treatment on the surface of aluminum or aluminum alloy material, which is a base material, is frequently performed from the viewpoint of corrosion resistance and cost. However, the chromate treatment has a problem in terms of environmental conservation because chromium ions are harmful metal ions.
[0006]
Moreover, it is also known as a base treatment agent and a treatment method that do not use the above-described chromium ions, and for example, it is treated with an acidic solution containing titanium salt (zirconium salt), hydrogen peroxide, and (condensed) phosphoric acid (derivative). Aluminum surface treatment method (Japanese Patent Laid-Open No. 54-24232), aluminum is treated with an alkaline aqueous solution containing titanium ions (zirconium ions, iron ions) and a complexing agent, washed with water, and then treated with an acidic aqueous solution such as phosphoric acid. Aluminum surface treatment method (JP-A-54-160527), aluminum surface treatment composition containing phosphate ion, titanium compound, fluoride and accelerator (JP-A-9-20984), (condensation) phosphoric acid (Salt), Titanium salt (Zirconium salt), Fluoride, (Hydrogen) Phosphorous acid (Salt) Aluminum-based metal surface treatment set Like object (JP-A-9-143752).
[0007]
However, the surface treatment agent and the treatment method using the above-described titanium compound have insufficient stability of the surface treatment agent, insufficient corrosion resistance compared to chromate treatment, insufficient hydrophilicity, and durability. There were problems such as not enough.
In recent years, anticorrosion-coated steel sheets are required to have excellent corrosion resistance, and many surface-treated steel sheets using zinc-based plated steel sheets as substrates instead of conventional cold-rolled steel sheets have been used.
[0008]
Conventionally, chromate treatment and zinc phosphate treatment are generally performed as the surface treatment of zinc-based plated steel sheets, but the toxicity of chromium has become a problem. The chromate treatment has a problem of volatilization of chromate fume in the treatment process, a large amount of cost for the wastewater treatment facility, and a problem due to elution of chromic acid from the chemical conversion coating. Hexavalent chromium compounds are extremely harmful because many public institutions, including IARC (International Agency for Research on Cancer Review), have designated them as carcinogenic substances for the human body.
[0009]
In addition, in zinc phosphate treatment, after zinc phosphate treatment, rinsing treatment with chromic acid is usually performed, so there is a problem of chromium treatment, as well as treatment accelerators in zinc phosphate treatment agents, wastewater treatment of metal ions, etc. There is a problem of sludge treatment due to elution of metal ions from the treated metal.
[0010]
As treatment methods other than chromate treatment and zinc phosphate treatment, (1) surface treatment method (Japanese Patent Publication No. 53-28857) which is treated with an aqueous solution containing aluminum biphosphate and then heated at a temperature of 150 to 550 ° C. And (2) a method of treating with an aqueous solution containing tannic acid (see Japanese Patent Application Laid-Open No. 51-71233), and (3) sodium nitrite, sodium borate, imidazole, aromatic carvone A treatment method using an acid, a surfactant, or the like, or a treatment method combining these, is performed.
[0011]
However, in the method (1), when a paint is applied thereon, the adhesion of the paint is not sufficient, the method (2) is inferior in corrosion resistance, and the methods (3) are both high temperature. There is a problem that the corrosion resistance is inferior when exposed to a humid atmosphere.
[0012]
Further, as zinc-based steel sheets having a thin film having a film thickness of several μm or less, JP-A-58-224174, JP-A-60-50179, JP-A-60-50180, etc. A rust-proof steel sheet is known that has a plated steel plate as a base material, a chromate film is formed on this, and an organic composite silicate film is formed on top of this as a top layer, and this has excellent workability and corrosion resistance. Have However, since this rust-proof steel sheet has a chromate film, there was a problem of health and safety due to chromate ions as described above. Further, the steel plate obtained by removing the chromate film from the rust-proof steel plate still has insufficient corrosion resistance.
An object of the present invention is to provide a coating agent for forming an inorganic film that forms an inorganic film particularly excellent in corrosion resistance of a metal, and a method for forming an inorganic film by applying the coating agent and drying it.
[0013]
Another object of the present invention is to provide an inorganic film-coated aluminum material that is excellent in corrosion resistance and is suitable for a heat-exchanger aluminum fin material particularly for a base treatment film that does not contain chromium.
[0014]
Furthermore, an object of the present invention is to provide an inorganic film-coated steel material that exhibits excellent corrosion resistance even if the zinc-based plated steel sheet does not have a chromate film.
[0015]
[Means for Solving the Problems]
As a result of diligent research, the present inventors have solved a conventional problem with a coating agent for forming an inorganic film obtained by reacting a specific fluoride with a specific hydrolyzable monomer and / or a low condensate thereof. As a result, the present invention has been completed.
[0016]
Thus, according to the present invention, the following component (A) at least one fluoride selected from titanium hydrofluoric acid and zirconium hydrofluoric acid, and (B) the general formula M (OR) 4 (wherein M is An inorganic film-forming coating characterized by reacting a hydrolyzable monomer and / or a low condensate thereof which are titanium atoms and R is the same or different and represents an alkyl group having 1 to 4 carbon atoms) An agent is provided.
[0017]
The present invention also provides an inorganic film forming method characterized in that the above-mentioned coating agent for forming an inorganic film is applied to a substrate and heat-treated as necessary.
The present invention also provides an inorganic film-coated aluminum material, wherein an inorganic film formed from the above-mentioned inorganic film forming coating agent is formed on the surface of an aluminum material or an aluminum alloy material.
[0018]
Furthermore, the present invention provides an inorganic film-coated steel material characterized in that the surface of the steel material is coated with an inorganic film formed from the inorganic film-forming coating agent.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
First, the inorganic film-forming coating agent of the present invention will be described.
[0020]
The coating agent for forming an inorganic film of the present invention comprises (A) at least one fluoride selected from silicohydrofluoric acid, titanium hydrofluoric acid, and zirconium hydrofluoric acid (hereinafter referred to as “fluoride”). And (B) at least one hydrolyzable monomer selected from silicon monomers, titanium monomers, zirconium monomers all substituted with hydrolyzable groups, and / or The low condensate (hereinafter these may be collectively referred to simply as “hydrolyzable compound (B)”) is reacted.
[0021]
The fluoride (A) is silicic hydrofluoric acid, titanium hydrofluoric acid, and zirconium hydrofluoric acid, and is represented by H 2 MF 6 (M represents the same meaning as described above). is there.
[0022]
The hydrolyzable monomer used for reacting with the fluoride (A) is one in which all hydrolyzable groups are directly bonded to silicon, titanium and zirconium atoms. The hydrolyzable group is a functional group that generates a hydroxyl group by a hydrolysis reaction. The hydrolyzable group is not particularly limited as long as it is conventionally known, but a lower alkoxyl group is particularly preferred from the viewpoint of excellent hydrolyzability and no coloring.
[0023]
As the hydrolyzable monomer, in particular, the general formula M (OR) 4 (wherein M is a silicon atom, a titanium atom or a zirconium atom, and R is the same or different and represents an alkyl group having 1 to 4 carbon atoms) These tetraalkoxy compounds are preferred. Examples of the alkyl group having 1 to 4 carbon atoms include methyl group, ethyl group, n-propyl group, iso-propyl group, n-butyl group, iso-butyl group, sec-butyl group, and tert-butyl group. Can be mentioned.
[0024]
Specific examples of the hydrolyzable monomer include tetramethoxysilane, tetraethoxysilane, tetrapropoxysilane, tetrabutoxysilane, trimethoxyethoxysilane, dimethoxydiethoxysilane, triethoxymethoxysilane, tetramethoxytitanium, Tetraethoxytitanium, tetrapropoxytitanium, tetrabutoxytitanium, trimethoxyethoxytitanium, dimethoxydiethoxytitanium, triethoxymethoxytitanium, tetramethoxyzirconium, tetraethoxyzirconium, tetrapropoxyzirconium, tetrabutoxyzirconium, trimethoxyethoxyzirconium, Suitable examples include dimethoxydiethoxyzirconium, triethoxymethoxyzirconium and the like.
[0025]
As the low condensate of the hydrolyzable monomer, a low condensate obtained by hydrolyzing the above hydrolyzable monomers with each other to undergo a condensation reaction can be used. The condensation degree of the low condensate is preferably 2 to 30, particularly preferably within the range of the condensation degree 2 to 10. The hydrolysis-condensation reaction can be performed by a conventionally known method, for example, by reacting a hydrolyzable monomer in the presence of water and a catalyst (for example, a basic catalyst, an acidic catalyst, etc.) at room temperature or by heating. The above reaction can be carried out in a hydrophilic solvent such as methanol, ethanol, isopropyl alcohol, ethylene glycol or propylene glycol as required.
[0026]
The reaction ratio between the fluoride (A) and the hydrolyzable compound (B) is such that the hydrolyzable compound (B) is 0.1 to 10 wt. It is desirable to make it react in 5-10 weight ratio. When the hydrolyzable compound (B) is less than 0.1, the film-forming property is lowered and the corrosion resistance is inferior. On the other hand, when the hydrolyzable compound (B) exceeds 10, the ratio of fluoride is lowered and the corrosion resistance is inferior. Therefore, it is not preferable.
The reaction between the fluoride (A) and the hydrolyzable compound (B) is performed at a reaction temperature of 1 to 70 ° C., preferably 5 to 70 ° C. for 5 minutes to 20 hours, preferably 5 minutes. It can manufacture by making it react for 10 hours.
[0027]
The coating agent for forming an inorganic film of the present invention produced by the reaction of a fluoride (A) and a hydrolyzable compound (B) comprises a reaction product of a fluoride (A) and a hydrolyzable compound (B), and A mixture of fluoride (A) and hydrolyzable compound (B) can also be included. The composition of the reaction product of fluoride (A) and hydrolyzable compound (B) is not clear, but fluoride (A) and hydrolyzable compound (B) are linear, branched, or It is thought that the structure was combined. Further, the molecular terminal may be a fluoride (A) reaction component or a hydrolyzable compound (B) reaction component.
[0028]
The reaction product contains MOR (H) group and MF group. After coating the coating agent for forming an inorganic film of the present invention having the reaction product, the MOR ( It is considered that a complete inorganic film is formed in which the H) group and the MF group do not substantially remain.
[0029]
The coating agent for forming an inorganic film of the present invention is diluted with a hydrophilic solvent such as methanol, ethanol, isopropyl alcohol, ethylene glycol or propylene glycol as necessary. Can be used.
[0030]
In the coating agent for forming an inorganic film of the present invention, for example, in addition to the above-described components, a surfactant, a fungicide, a rust preventive agent (tannic acid, phytic acid, benzotriazole, etc., as necessary) ), Pigments such as colored pigments, extender pigments, rust preventive pigments, and the like.
[0031]
The coating agent for forming an inorganic film of the present invention is usually 0.01 to 10% by weight, particularly preferably 0.1 to 5% by weight, as a coating solid content. When the solid content is less than 0.01% by weight, the film forming property is insufficient and the corrosion resistance is inferior. On the other hand, when it exceeds 10% by weight, the film is cracked and the corrosion resistance is inferior.
[0032]
The coating agent for forming an inorganic film of the present invention becomes a stable liquid in an acidic region, and a pH of 0.5 to 5, particularly 0.5 to 3 is particularly preferable.
The coating agent for forming an inorganic film of the present invention can be formed on an inorganic film by applying it to a substrate and heat-treating it as necessary.
[0033]
The base material is not particularly limited, for example, polyvinyl chloride resin, polyethylene terephthalate, acrylic resin, silicon resin, polyester resin, fluorine resin, epoxy resin, polyethylene resin, nylon resin, butyral resin, Fiber base resin, phenol resin, and a combination of two or more of these resins, plastic base materials with surface treatment and primer, inorganic base materials such as glass and cement, pulp base such as paper and fiber Examples thereof include materials, steel, aluminum, copper, stainless steel, zinc, tin, a combination of two or more of these metals, and a metal substrate with a surface treatment or a primer.
[0034]
In the coating agent for forming an inorganic film of the present invention, the coating agent is applied to an inorganic film-coated aluminum material obtained by applying the coating agent to an aluminum material or an aluminum alloy material, and to a surface of a phosphating film on a steel material or metal surface. The inorganic film-coated steel material to be used will be described below.
[0035]
Inorganic film coated aluminum material:
An inorganic film can be formed by coating and drying the inorganic film-forming coating agent of the present invention on an aluminum material. The coating agent for forming an inorganic film is a coating method known per se, for example, dipping on an aluminum material (which may be assembled in a heat exchanger such as an aluminum fin material). It can be painted by painting, shower painting, spray painting, roll painting, electrodeposition painting, etc. As for the drying conditions of the coating agent for forming an inorganic film, it is usually preferable to dry the coating material for about 2 seconds to about 30 minutes under the condition that the maximum material reaching temperature is about 60 to 250 ° C.
[0036]
Moreover, as a dry film thickness of the coating agent for inorganic film formation, the range of 0.001-10 micrometers normally, especially 0.1-3 micrometers is preferable. When the thickness is less than 0.001 μm, the performance such as corrosion resistance and water resistance is inferior. On the other hand, when the thickness exceeds 10 μm, the inorganic film is cracked or the hydrophilicity is inferior.
[0037]
Inorganic film coated steel:
The coating agent for forming an inorganic film can be formed by coating and drying the coating material for forming an inorganic film of the present invention on the surface of the following steel material. The coating agent for forming an inorganic film is a coating method known per se, such as immersion coating, shower coating, spray coating, roll coating, electrodeposition coating, on the following steel materials (for example, it may be assembled). It can be painted by. As for the drying conditions of the coating agent for forming an inorganic film, it is usually preferable to dry the coating material for about 2 seconds to about 30 minutes under the condition that the maximum material reaching temperature is about 60 to 250 ° C.
[0038]
Moreover, as a dry film thickness of the coating agent for inorganic film formation, the range of 0.001-10 micrometers normally, especially 0.1-3 micrometers is preferable. When the thickness is less than 0.001 μm, the performance such as corrosion resistance and water resistance is inferior. On the other hand, when the thickness exceeds 10 μm, the inorganic film is cracked or the hydrophilicity is inferior.
[0039]
Preferably, the steel material is a hot dip galvanized steel sheet, an electrogalvanized steel sheet, an iron-zinc alloy plated steel sheet, a nickel-zinc alloy plated steel sheet, an aluminum-zinc alloy plated steel sheet (for example, “Galbarium”, “Galfan”). Alloy-plated steel sheet on the market). Moreover, as the zinc-based plated steel sheet, a zinc-based plated steel sheet subjected to chemical conversion treatment such as chromate treatment, zinc phosphate treatment, and composite oxide film treatment can also be used.
[0040]
The inorganic film-coated steel material is excellent in corrosion resistance, fingerprint resistance, and the like, and can be used as it is as a rust-proof steel plate or a lubricated rust-proof steel plate, but an upper film can be further formed thereon. The composition for forming the upper layer film may be appropriately selected according to the purpose, and various coating compositions can be used. Examples of the coating composition include a primer coating and a colored top coating. A primer paint may be applied, and a colored top coat may be further applied thereon.
[0041]
【Effect of the invention】
In the present invention, the inorganic film-forming coating agent having the above-described configuration is applied to a metal substrate such as aluminum or an electrogalvanized steel sheet and heated to form the inorganic film, thereby forming the inorganic film-forming coating agent. The component constituting the fluoride (A) acts as a metal corrosion inhibitor, while the component comprising the hydrolyzable compound (B) is a metal oxide film or silicon oxide film such as silicon oxide, titanium oxide or zirconium oxide. Since an inorganic film having low oxygen permeability is formed, an inorganic film having excellent anticorrosion properties is formed, and (A) component and (B) component are chemically bonded, so that metal corrosion occurs. In order to protect the fluoride (A) component coordinated to the metal material with the metal oxide film or silicon oxide film (B) as a suppressor of the metal, a highly corrosion-resistant and highly durable inorganic film is formed. It is guessed that .
[0042]
【Example】
Hereinafter, the present invention will be described more specifically with reference to examples and comparative examples. Hereinafter, “parts” and “%” mean “parts by weight” and “% by weight”, respectively. The present invention is not limited to the following examples.
[0043]
Production Example of Inorganic Film Forming Coating Agent (1) A mixture of 2.0 parts of tetraiso-propoxytitanium and 48 parts of ethanol in a mixture of 1.5 parts of 40% titanium hydrofluoric acid and 48.5 parts of deionized water Was added dropwise at 20 ° C. over 1 hour with stirring. A cloudy inorganic film-forming coating agent (1) was obtained.
[0044]
Production Example of Inorganic Film Forming Coating Agent (2) A white cloudy inorganic film forming coating agent (2) was prepared under the same production conditions using tetra n-butoxy titanium instead of tetraiso-propoxy titanium in Production Example 1. Obtained.
[0045]
Production Example of Inorganic Film Forming Coating Agent (3) Using 40% zirconium hydrofluoric acid in place of titanium hydrofluoric acid in Production Example 1, a cloudy inorganic film forming coating agent (3 )
[0046]
Production Example of Inorganic Film-Forming Coating Agent (4) In the production example of the titanium treating agent (1), a transparent inorganic film-forming coating agent under the same production conditions using 6 parts of 40% titanium hydrofluoric acid ( 4) was obtained.
[0047]
Production Example of Inorganic Film Forming Coating Agent (5) A mixture of 2.0 parts of tetraiso-propoxytitanium and 48 parts of ethanol was dropped into a mixture of 50 parts of deionized water at 20 ° C. with stirring for 1 hour. A cloudy inorganic film-forming coating agent (5) was obtained.
[0048]
Production Example of Inorganic Film Forming Coating Agent (6) 6 parts of 40% titanium hydrofluoric acid and 94 parts of deionized water were mixed to obtain a transparent inorganic film forming coating composition (6) .
[0049]
Production Example of Inorganic Film Forming Coating Agent (7) 6 parts of 40% zirconia hydrofluoric acid and 94 parts of deionized water were mixed to obtain a transparent inorganic film forming coating agent (7) .
[0050]
Inorganic film-forming coating agents (1) to (4) (Examples) and inorganic film-forming coating agents (5) to (7) (Comparative Examples) were obtained.
[0051]
Preparation of test plate A: An aluminum plate (A1050) having a thickness of 0.1 mm was used with an aqueous solution having a concentration of 2% in which an alkaline degreasing agent (trade name “Chem Cleaner 561B” manufactured by Nippon CB Chemical Co., Ltd.) was dissolved. After degreasing and washing with water, the surface treatment agents obtained in the above Examples and Comparative Examples were applied so that the dry film weight was 0.2 g / m 2, and the material reaching temperature was 100 ° C. for 20 seconds. Baking was performed to form a base treatment film.
[0052]
Each of the obtained test coated plates was subjected to a corrosion resistance test. The test results are shown in Table 1 below. The test was conducted according to the following test method.
[0053]
Corrosion resistance: According to JIS-Z-2371 salt spray test method. The test time was made into three stages of 120 hours, 240 hours and 360 hours, and evaluated according to the following criteria.
○: White rust and swelling are not observed on the coating surface. Δ: White rust or swelling is slightly generated. ×: White rust or swelling is remarkably generated.
[0054]
Preparation of test plate B: An electrolytic galvanized steel sheet having a thickness of 0.6 mm and a coating amount of 20 g / m 2 on one side was dissolved in an alkaline degreasing agent (trade name “Chem Cleaner 561B” manufactured by Nippon CB Chemical Co., Ltd.). After degreasing and washing with an aqueous solution having a concentration of 2%, the surface treatment agent obtained in the above Examples and Comparative Examples was applied so that the dry film weight was 1.0 g / m 2, and the material reaching temperature was The substrate was baked for 20 seconds at 100 ° C. to form a base treatment film.
Each of the obtained test coated plates was subjected to a corrosion resistance test. The test results are shown in Table 2 below. The test was conducted according to the following test method.
[0055]
Corrosion resistance: A salt spray test as defined in JIS Z2371 is performed on the test coated plate with the end and back surfaces of the test coated plate sealed up to 72 hours, and the degree of rust on the coated surface after 24 hours and 48 hours is shown below. Evaluation was made according to the criteria.
a: generation of white rust is not observed,
b: The degree of occurrence of white rust is less than 5% of the coating area,
c: The degree of occurrence of white rust is 5% or more and less than 10% of the coating area,
d: The degree of occurrence of white rust is 10% or more and less than 50% of the coating area,
e: The degree of occurrence of white rust is 50% or more of the coating film area.
[0056]
Preparation of test plate C
An electrogalvanized steel sheet having a plate thickness of 0.6 mm and a single-side plating coating amount of 20 g / m 2 was used as a substrate.
After the surface of the plated steel sheet is degreased with alkali, surface adjustment (spray treatment using “preparene Z” manufactured by Nihon Parkerizing Co., Ltd.) is performed, and zinc phosphate treatment (“Palbond 3308” manufactured by Nihon Parkerizing Co., Ltd.) is performed. After spraying using “,” various galvanized steel sheets subjected to zinc phosphate treatment by washing with water and drying were obtained. The adhesion amount of the zinc phosphate-treated film was 1.5 g / m 2 .
[0057]
The surface treatment agents obtained in the above examples and comparative examples were applied on the surfaces of various plated steel sheets subjected to the zinc phosphate treatment so that the dry film weight was 1.0 g / m 2, and the material arrival temperature was 100 ° C. In this manner, the substrate was baked for 20 seconds to form a base treatment film.
Each of the obtained test coated plates was subjected to a corrosion resistance test. The test results are shown in Table 3 below. The test was conducted according to the following test method.
[0058]
Corrosion resistance: A salt spray test specified in JIS Z2371 is performed on the test coated plate with the end face and back surface of the test coated plate sealed up to 72 hours. Evaluation was made according to the criteria.
a: generation of white rust is not observed,
b: The degree of occurrence of white rust is less than 5% of the coating area,
c: The degree of occurrence of white rust is 5% or more and less than 10% of the coating area,
d: The degree of occurrence of white rust is 10% or more and less than 50% of the coating area,
e: The degree of white rust generation is 50% or more of the coating area.
The test results are shown below.
Table 1
[0059]
[Table 1]
[0060]
[Table 2]
[0061]
[Table 3]
Claims (6)
(A)チタン弗化水素酸及びジルコニウム弗化水素酸から選ばれる少なくとも1種の弗化物、及び(B)一般式 M(OR) 4 (式中、Mはチタン原子であり、Rは同一もしくは異なって炭素数1〜4のアルキル基を示す)である加水分解性モノマー及び/又はその低縮合物を反応させてなることを特徴とする無機膜形成用塗布剤。The following component (A) at least one fluoride selected from titanium hydrofluoric acid and zirconium hydrofluoric acid, and (B) general formula M (OR) 4 (wherein M is a titanium atom, R is A coating agent for forming an inorganic film, which is obtained by reacting a hydrolyzable monomer having the same or different alkyl group having 1 to 4 carbon atoms and / or a low condensate thereof.
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JP2008184690A (en) * | 2002-12-24 | 2008-08-14 | Nippon Paint Co Ltd | Pretreatment method for coating |
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JP2005336334A (en) * | 2004-05-27 | 2005-12-08 | Ube Nitto Kasei Co Ltd | Coating composition for forming amorphous titanium oxide composite coating film, coating film produced by using the same and use thereof |
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JPS6022067B2 (en) * | 1982-09-30 | 1985-05-30 | 日本パ−カライジング株式会社 | Method for forming film on metal surface |
JPS63149387A (en) * | 1986-12-12 | 1988-06-22 | Furukawa Alum Co Ltd | Aluminum material for cap having base film for painting with satisfactory adhesion to ink |
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