JP3893091B2 - Negative ion generator - Google Patents
Negative ion generator Download PDFInfo
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- JP3893091B2 JP3893091B2 JP2002249134A JP2002249134A JP3893091B2 JP 3893091 B2 JP3893091 B2 JP 3893091B2 JP 2002249134 A JP2002249134 A JP 2002249134A JP 2002249134 A JP2002249134 A JP 2002249134A JP 3893091 B2 JP3893091 B2 JP 3893091B2
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- ion generator
- negative ion
- polytetrafluoroethylene
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Description
【0001】
【発明の属する技術分野】
本発明は、自然分極を有する鉱石の粉体を使用してなるマイナスイオン発生体に関するものである。
【0002】
【従来の技術】
「電荷を持つ原子もしくは分子などの原子団」をイオンという。イオンは自然界や大気中に多く存在し、プラスの電荷をもったものをプラスイオンといい、新築の家、電化製品の多い部屋、車の排気の多い場所や喫煙場所にプラスイオンの環境、空気が多いとされ、これらプラスイオンは人体への影響、自律神経が不備となり、目まい、頭痛、イライラ、神経症の原因となるといわれている。
【0003】
一方、マイナスイオンの多い環境、空気は湿度の多い場所の森林草木、滝噴水近辺や温泉に多いとされ、これらの場所では身体や呼吸器機能向上、精神安定、疲労感軽減、免疫力向上の効果があるとされている。
【0004】
従って、マイナスイオンの多い環境が好まれ、人為的にマイナスイオンを発生、放出する方法、物体として電気利用によるコロナ放電式があるが、設備やオゾン発生の、滝や噴水、それにスチーム放出による水破砕方式、トルマリンなどの鉱石による方式、ボロニウムやラドンなどの放射性元素を利用した放射線方式等がある。
【0005】
これらの方式は、それぞれ利点と欠点があるが、安全性が高く、持ち運び、設置が便利で簡単にマイナスイオンを発生、放出させる方法・物体としてトルマリンなどの鉱石による方式が多く使用されている。
【0006】
天然鉱石による方式として、トルマリン、ゼオライト、ロッシュ塩、プロピオン酸カルシュウムストロンチュウム等が挙げられる。
【0007】
特にトルマリンは電気石として永久電気分極をしている物体であり、永久電気分極性を有する物体は動体下ではマイナスイオンを発生させるが、トルマリン単独では無いに等しい微弱なマイナスイオンしか発生しない物体であるため、多大に発生しうるように、微量の放射線を放出する粉体であるデービ鉱石、カルノー石、トール石、トリウム石等があり、これらを一部含む鉱石の粉末を天然鉱石と混合使用する方法が特開2001−20177号公報に記載されている。
【0008】
更に、特開2001−288679号公報には無機多孔質素材である多孔質泥、ケイソウ土、ゼオライト等と混合使用する方法が記載されているが、何れも無機物であり、微弱ながらも放射線を放出し、無機金属による人体障害がうかがいしれない。
【0009】
また、これらをトルマリンと混合使用しても、マイナスイオンの発生量は微弱な状態から若干増大しうるのみで、この程度のマイナスイオンの放出量では、生活環境や空気中のプラスイオンで簡単に中和され、生活環境や人体に好影響を与えるだけの効果は期待し難い状態である。
【0010】
それにもかかわらず、これらトルマリンや上記物質を超微粒子状にして樹脂や繊維に数パーセント付着させたり、練り混んだりして、マイナスイオンを発生するとする商品が市場に多々出回っている。しかし、これらのマイナスイオンは更に極めて弱く、生活環境や身回品等を常時マイナスイオン下に置くには程遠いものである。
【0011】
【発明が解決しようとする課題】
本発明は、従来の技術の欠点を解消し、身体に好影響を与えることを注目されているマイナスイオンを、自然分極を有する鉱石を使用するが、実質的に放射線を放出する鉱石を使用しなくても、効率よく発生する物質を提供することを課題とする。
【0012】
【課題を解決するための手段】
本発明者等は、自然分極を有する鉱石、例えばトルマリンのマイナスイオン発生体原理はその結晶体構造により起因しているといわれ、それはトルマリン結晶の先の尖ったプラス極の箇所と結晶の平坦なマイナス極に分極するとされており、このプラス極からマイナス極に向かって電界が発生し、マイナスイオンがマイナス極より発生すること、及び二種の異なった物質又は同種の物体を摩擦したり、分離した場合に、物質間で電子又はイオンの移動が起こり、静電気が発生することに着眼し、この現象を利用することにより、上記課題を解決した。
【0013】
即ち、自然分極を有する鉱石の粉末は、静止状態では分極差が生じずマイナスイオンを発生しないが、摩擦、剥離、移動等で静電気が生ずると微弱ながらマイナスイオンを発生すること、及びかかる自然分極を有する鉱石の粉末に、強制的に静電気を与えれば多量のマイナスイオンが発生することを見出し、その結果、自然分極を有する鉱石の粉末に、静電気に帯電している物体を接触させることにより、自然分極を有する鉱石の結晶の電界バランスが乱れ分極差を生じ、強力なマイナスイオンを発生可能としたのである。
【0014】
そこで、自然分極を有する鉱石の粉末と接触させる物質について、種々検討した結果、有機フッ素樹脂化合物が少々の摩擦や剥離等にて極めて強力に、長時間帯電することを見出し、それをマイナス帯電させたものを、自然分極を有する鉱石の粉末と接触させることにより、所望の結果を得たのである。
【0015】
物体が静電気を帯電する場合、プラスとマイナスのどちらかに帯電するが、プラス静電気に帯電しやすい有機化合物としては、ポリエステル樹脂、ナイロン樹脂、天然獣毛、ポリ塩化ビニル樹脂等があり、マイナス静電気に帯電し易い有機化合物質としては、フッ素樹脂、ポリエチレン樹脂、ビニロン樹脂、アクリル樹脂等があり、粉体、特に粒径が小さくなればなるほど表面積が大となり、静電気を帯電しやすくなる。
【0016】
これらの物体に簡単に静電気を帯電させ、更にプラス、マイナスを自由に帯電させることは、電気による自己放電式、電圧印圧式の中にパルス直流方式や定常直流方式等により可能であり、極めて高帯電性を与えることができる。特にパルス直流方式にて、より簡単に強力なプラス又はマイナスの高帯電性を得ることができる。
【0017】
しかし、通常の物質はいずれも静電気帯電した状態は極めて短時間で減少していくものであるが、有機フッ素樹脂化合物の中には、極めて強く、かつ長時間帯電し、しかも、電気によるパルス直流方式にて、簡単に強力な高帯電性を付与でき、その殆どの場合に、マイナスに帯電するという特異な性質があることが分かった。
【0018】
従って、本発明では、自然分極を有する鉱石粉末をマイナス帯電した有機フッ素樹脂化合物と接触させることにより、自然分極を有する鉱石粉末が多量のマイナスイオンを発生するようにしたのである。
【0019】
自然分極を有する鉱石粉末としては、トルマリン粉体又はそれを含むものを使用するのが好ましく、有機フッ素樹脂化合物は予め電気的に加電してマイナス帯電された状態で使用されても、また、トルマリン粉体と接触・混合後に電気的に加電してマイナス帯電されてもよいが、予めマイナス帯電された有機フッ素樹脂化合物を、自然分極を有する鉱石粉末と混合使用するのが、マイナスイオン放出量の点からより効果的である。
【0020】
一般に、自然分極を有する鉱石と有機フッ素樹脂化合物は共に、1mm以下の粒径の粉体で、その混合比率が1/99〜99/1となるようにするのが好ましい。これらの粉体の粒径が1mmを越すと、接触点と表面積が減少するため、マイナスイオンの放出が少なくなり、所望の効果を得難いものとなる。自然分極を有する鉱石粉体と有機フッ素樹脂化合物粉体の接触・混合比率が特に好ましいのは10:90〜50:50である。
【0021】
なお、自然分極を有する鉱石粉末と有機フッ素樹脂化合物の混合物を含む樹脂成形体、又は自然分極を有する鉱石粉末と有機フッ素樹脂化合物を含む塗料を製造し、これを布、紙、木材、プラスチック、金属等の機材に塗布したものをマイナスイオン発生体としてもよい。この場合、有機フッ素樹脂化合物へのマイナス帯電は、樹脂成形体製造後や塗料の塗布後になされてもよい。
【0022】
本発明で使用する有機フッ素樹脂化合物の代表的なものとしては、
ポリテトラフルオロエチレン・エチレンコポリマー樹脂、
ポリテトラフルオロエチレン・プロピレンコポリマー樹脂、
ポリテトラフルオロエチレン・パーフルオロアルキルビニルエーテルコポリマー樹脂、
ポリテトラフルオロエチレン・ヘキサフルオロプロピレンコポリマー樹脂、
ポリテトラフルオロエチレン・ヘキサフルオロプロピレン・パーフルオロアルキルビニルエーテルコポリマー樹脂、
ポリテトラフルオロエチレン樹脂、
ポリビニルフルオライド樹脂、
ポリビニリデンフルオライド樹脂、
ポリクロロトリフルオロエチレン樹脂、および
ポリクロロトリフルオロエチレン・エチレンコポリマー樹脂などが例示できる。いずれも市販の製品が使用可能である。
【0023】
なお、本発明では、周囲に複数の開孔を設けた筒状の回転装置に、自然分極を有する鉱石の粉体と、マイナス帯電させた有機フッ素樹脂化合物の粉体を入れ、回転させることによって、マイナスイオンを非常に多く生じさせうる製品とすることもできる。この場合、前記回転装置には、粉体混合物が漏れないように、外周(又は内周)にフィルターを取り付けるのが好ましいが、このフィルターにも、自然分極を有する鉱石の粉体とマイナス帯電させた有機フッ素樹脂化合物を併含する塗料を塗布した布帛を使用するなどして、自然分極を有する鉱石の粉体とマイナス帯電させた有機フッ素樹脂化合物を併含させるのが好ましい。特に、前記回転装置を、アルミニューム製とすることにより、驚異的なマイナスイオンの生成を可能とする。
【0024】
【発明の実施の形態】
次に、実施例と比較例に基づき、本発明をさらに詳しく説明するが、実施例等で使用した器具装置等は次の通りである。
〔静電気負荷発生装置〕
パルス直流電気方式のパルスイオナイザーA−20J(鈴木商会製・京都)。出力直流電圧5kv、タングステン電極針2本、エアーアウトレット1/2インチNTP、使用空気圧5kgf/cm3 、電極針と試料間の距離10cm、放射時間5秒の条件下で使用した。
〔マイナスイオン及びプラスイオン発生性能評価〕
イオン測定器としてダイナミックシステムエアーイオンカウンターFIC−2000(東京フィーサー製・東京)を搭載したイオナリー測定器SSI−1500(鈴木商会製・京都)で測定した。測定条件は次の通りである。
測定雰囲気として気温20℃湿度40%の恒湿恒温室エアーイオンカウンターFIC−2000の吸気口より測定試料までの距離15cm、測定試料の上下振幅距離15cm、振幅回数100回/分(速度30m/分)、測定時間1分で測定結果は最大マイナスイオン、最大プラスイオンの量を示す。マイナスイオンとプラスイオンの1分間の平均値を1cc当たりのイオン個数を測定した。
【0025】
実施例1
有機フッ素樹脂化合物粉体としてポリテトラフルオロエチレン樹脂(テックケム研究所製のカオシリカTEE−100:平均粒径0.02mm粉末)−以下、TFE粉末と略す−10gに静電気負荷装置によりマイナス静電気を付与した物と黒トルマリン粉末(エネックス社製の粒径5〜20μm粉末)90gを混合し、精錬漂白された微細高密度100%綿ツイル織物5×10cm角の二重袋内部に密封し、イオン量を測定した。
【0026】
実施例2〜4
TFE粉末と黒トルマリン粉末の量を下記の通り変更した以外は実施例1と同様の方法で、イオン量を測定した。
〔実施例2〕 TFE粉末50gと黒トルマリン粉末50g
〔実施例3〕 TFE粉末75gと黒トルマリン粉末25g
〔実施例4〕 TFE粉末90gと黒トルマリン粉末10g
【0027】
実施例5
実施例1のTFE粉末を、ポリテトラフルオロエチレン−ヘキサフルオロプロピレン−パーフルオロアルキルビニルエーテル共重合体(テックケム研究所製のカオシリカPPF−2300:平均粒径0.2mm粉末)に変えた以外は実施例1と同様の方法で、イオン量を測定した。
【0028】
比較例1
実施例1に使用した黒トルマリン粉末のみを精錬漂白された微細高密度100%綿ツイル織物5×10cm角の二重袋内部に密封し、イオン量を測定した。
【0029】
比較例2
マイナス静電気を付与した黒トルマリン粉末を使用して、比較例1と同様の方法で、イオン量を測定した。
【0030】
比較例3
実施例1に使用したTFE粉末のみを精錬漂白された微細高密度100%綿ツイル織物5×10cm角の二重袋内部に密封し、イオン量を測定した。
【0031】
比較例4
マイナス静電気を付与したTFE粉末を使用して、比較例3と同様の方法で、イオン量を測定した。
【0032】
実施例1〜5及び比較例1〜4で得た結果を表1に示す。
【0033】
【表1】
実施例6−綿織物にマイナスイオン発生体を付着せしめた例−
ポリアクリル樹脂系粘性沈下防止剤(英国、アライド社製のアルコプリントPTF)の0.2%水溶液100重量部に、ポリウレタン系エマルジョンバインダー(有限会社古川技研製のテックコートWH960)5重量部、マイグレーション防止剤として10%アルギン酸ソーダ水溶液3重量部、ブロックイソシアネート系架橋剤(有限会社古川技研製のスーパーフレシュJB−7300)1重量部、ジフェニルエーテル系アニオン界面活性浸透剤(花王株式会社製のペレックスSSH)0.2重量部を混合均一に攪拌したストック溶液に黒トルマリン粉末(粒径0.5μm以下の粉末)4重量部とノニルフェノール系界面活性剤4%を含むポリテトラフルオロエチレン・エチレンコポリマー樹脂濃度45%の水分散体(テックケム研究所製のカオシリカTEEC−45)11重量部を混合し、ホモデスパー−1000rpmで5分間攪拌し、処理液を調製した。
この処理液に精錬漂白された局方ガーゼを5秒間浸し、2本マングルで絞り率80%で均一に絞り、100℃で5分間乾燥し、160℃で2分間熱処理した後、50℃の温水で1分間湯洗し、絞って100℃で3分間乾燥した。
このようにして得た処理ガーゼに、静電負荷発生装置でマイナス静電気を付与し、試験片とした。
試験片を10cm×2cmの短冊状に裁断し、これを20g±0.2gとなるように重ね、長辺の一方を束ねて結束し、他方は結束しないで、イオナー測定器に結束した方を上にして、箱内部に設置し、前述の測定器と測定条件でイオン量を測定した。
【0035】
実施例7
実施例6のポリテトラフルオロエチレン・エチレンコポリマー樹脂の代わりにポリテトラフルオロエチレン樹脂濃度45%の水分散体(テックケム研究所製のカオシリカTEEC−45L)を使用した以外は実施例6と同様の方法を実施して、試験片のイオン量を測定した。
【0036】
比較例5
処理ガーゼに静電負荷発生装置でマイナス静電気を付与する処理をしない以外は、実施例6と同様の方法を実施した。
【0037】
比較例6
実施例6の方法で、ポリテトラフルオロエチレン・エチレンコポリマー樹脂を使用しないで試験片を作成し、また、処理ガーゼに静電負荷発生装置でマイナス静電気を付与する処理をしない以外は実施例6と同様の方法を実施した。
【0038】
比較例7
実施例6の方法で、黒トルマリン粉末とポリテトラフルオロエチレン・エチレンコポリマー樹脂とを混合しないで、また処理ガーゼに静電負荷発生装置でマイナス静電気を付与する処理をしない以外は実施例6と同様の方法を実施した。
【0039】
実施例8
長油性フタル酸系溶剤塗料(株式会社カンペパビリオ製のハウスペイントPRO白色)100重量部にトルエン50重量部、アセトン50重量部、ポリテトラフルオロエチレン・パーフルオロアルキルビニルエーテルコポリマー樹脂(テックケン研究所製のカオシリカTEFAB−1501)の平均粒径20μm粉体10重量部、ピンクトルマリン粉末(エネックス製の平均粒径10μm以下の粉体)3重量部を混合攪拌し、均一にして市販紙質の壁紙に塗布し、48時間乾燥し、実施例6と同様に静電負荷発生装置でマイナス静電気を付与し、短冊状の試験片としてイオン量を測定した。
【0040】
比較例8
実施例8に使用した市販紙質の壁紙のみ、マイナス静電気を付与しないで短冊状としてイオン量を測定した。
【0041】
比較例9
実施例8に使用したポリテトラフルオロエチレン・パーフルオロアルキルビニルエーテルコポリマー樹脂の粉末を混合しないで、更にマイナス静電気も付与しないで、実施例8と同様の方法を実施した。
実施例6〜8と比較例5〜9の試験結果を表2に示す。
【0042】
【表2】
実施例9
室内の空気にマイナスイオンを供給せしめるべくトルマリン0.5μm(エネックス製)0.5重量部、ポリテトラフルオロエチレン・エチレンコポリマー樹脂濃度45%の水分散体(テックケン研究所製のカオシリカTEEC−45)1.2重量部、純水80重量部、ジメチルエーテル18.3重量部の混合物をスプレー缶に充填し、イオン測定器と連結したアルミ製の箱に1メートルの距離より1秒間吹き掛けイオン量を測定した。
【0044】
実施例10
スプレー間と箱の距離を2メートルとした以外は実施例9と同様の方法を実施した。
実施例9と10の試験結果を表3に示す。
【0045】
【表3】
実施例11
前記方法にてマイナス荷電したポリテトラフルオロエチレン樹脂(テックケン研究所製のカオシリカTFE−1010:平均粒径0.02mm)100重量部とトルマリン粒径5〜20μm(エネックス社製)100重量部を混合した混合粉体と下記のフィルターを準備した。
フィルターは、木綿の布の表面に、アクリル樹脂バインダー含有ミネラルターペン系の繊維顔料プリント用ペースト(ユニ化成社製のユニバインダーMCO:粘度21000cpsの白色ペースト)100重量部に前記方法にてマイナス荷電した平均粒径10μmのポリテトラフルオロエチレン粉体(テックケン研究所製のカオシリカTFE−2200)7重量部と平均粒径3μm黒トルマリン粉体(エネックス社製)4重量部を添加して、ホモデスパー2000rpmで10分攪拌混合して得た粘度48000cpsのねずみ色のペーストを、シルクスクリーンにて、全面塗布し、6時間乾燥した後、再度同様のペーストを塗布し、12時間乾燥時間後に、裏面にも表面と同じ処理を施したものである。
このフィルターを、アルミニューム製の筒体(長さ20cm、直径6.5cmの筒で、周囲に直径2cmの孔を72個設けており、中心軸を回転軸として回転可能となっている)の外周に内容物が漏れないように固定し、前記混合粉体を入れ、該筒体を蓋で密閉し、前記軸を中心として3回転/秒にて回転させ、イオナリー測定器から30cm離れた位置でのイオン量を測定した。
【0047】
実施例12
実施例11のアルミニウム製の筒体を、木製の筒体とした以外は実施例12と同様の方法を実施した。
実施例11と12の試験結果を表4に示す。
【0048】
【表4】
【発明の効果】
本発明の製品は、実質的に放射線を放出する危険性がなく、しかも長期間、安定して効率よくマイナスイオンを放出するものであるので、非常に取り扱い易く、多様な商品展開が可能となる。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a negative ion generator using ore powder having natural polarization.
[0002]
[Prior art]
“Atom or group of atoms with charge” is called ion. There are many ions in nature and in the atmosphere, and those with a positive charge are called positive ions. In a newly built house, a room with a lot of electrical appliances, a place where there is a lot of exhaust in a car or a smoking place, the environment of positive ions, air These positive ions are said to cause effects on the human body and lack of autonomic nerves, leading to dizziness, headache, irritation, and neurosis.
[0003]
On the other hand, an environment with a lot of negative ions, air is often found in humid forests, near waterfall fountains and hot springs. In these places, body and respiratory function improvement, mental stability, fatigue reduction, immunity improvement It is said to be effective.
[0004]
Therefore, an environment with a lot of negative ions is preferred, and there is a method of artificially generating and releasing negative ions, and there is a corona discharge method using electricity as an object, but there are waterfalls and fountains that generate equipment and ozone, and water generated by steam discharge. There are a crushing method, a method using ore such as tourmaline, and a radiation method using radioactive elements such as boronium and radon.
[0005]
Each of these methods has advantages and disadvantages, but they are highly safe, easy to carry and install, and methods of generating and releasing negative ions are easy. Methods of ore such as tourmaline are often used as objects.
[0006]
Examples of the method using natural ore include tourmaline, zeolite, Roche salt, calcium strontium propionate, and the like.
[0007]
In particular, tourmaline is an object that has permanent electric polarization as an electric stone, and an object having permanent electric polarizability generates negative ions under a moving object, but it is an object that generates only weak negative ions that are not equal to tourmaline alone. Therefore, there are Davi ore, carnotite, thorite, thorium, etc., which are powders that emit a very small amount of radiation so that they can be generated in large quantities. A method for doing this is described in Japanese Patent Laid-Open No. 2001-20177.
[0008]
Furthermore, Japanese Patent Application Laid-Open No. 2001-288679 describes a method of mixing and using inorganic porous materials such as porous mud, diatomaceous earth, zeolite, etc., all of which are inorganic substances and emit radiation even though they are weak. However, human body damage due to inorganic metals cannot be heard.
[0009]
In addition, even if these are mixed with tourmaline, the amount of negative ions generated can only slightly increase from a weak state. With this amount of negative ions released, it can be easily done in the living environment or in the air. It is in a state where it is difficult to expect effects that are neutralized and have a positive effect on the living environment and human body.
[0010]
Nevertheless, there are many products on the market that generate these negative ions when these tourmalines and the above substances are made into ultrafine particles and adhered to resin or fiber by several percent or mixed. However, these negative ions are much weaker, and it is far from always putting the living environment and personal items under negative ions.
[0011]
[Problems to be solved by the invention]
The present invention eliminates the drawbacks of the prior art and uses negative ions, ores with natural polarization, which are attracting attention to have a positive effect on the body, but uses ores that emit substantially radiation. It is an object of the present invention to provide a substance that is efficiently generated even if it is not.
[0012]
[Means for Solving the Problems]
The present inventors have said that the negative ion generator principle of ores having spontaneous polarization, such as tourmaline, is due to its crystal structure, which is the point of the positive pole of the tourmaline crystal and the flatness of the crystal. It is said that it is polarized to the negative pole, an electric field is generated from the positive pole to the negative pole, negative ions are generated from the negative pole, and two different substances or similar objects are rubbed or separated. In this case, the above problem was solved by utilizing this phenomenon, focusing on the fact that electrons or ions move between substances and static electricity is generated.
[0013]
That is, ore powder having natural polarization does not generate a polarization difference and does not generate negative ions in a stationary state, but generates weak negative ions when static electricity is generated due to friction, separation, movement, and the like. It is found that a large amount of negative ions is generated if static electricity is forcibly applied to ore powder having polarization, and as a result, an electrostatically charged object is brought into contact with ore powder having natural polarization. The electric field balance of the ore crystal having natural polarization is disturbed, resulting in a polarization difference, which makes it possible to generate strong negative ions.
[0014]
Therefore, as a result of various investigations on substances that come into contact with ore powder having natural polarization, it was found that the organic fluororesin compound is extremely strongly charged for a long time due to a little friction or peeling, and it is negatively charged. The desired result was obtained by contacting the powder with ore powder having natural polarization.
[0015]
When an object is charged with static electricity, it is charged either positively or negatively, but organic compounds that are easily charged with positive static electricity include polyester resin, nylon resin, natural animal hair, polyvinyl chloride resin, etc. Examples of organic compounds that are easily charged include fluororesin, polyethylene resin, vinylon resin, and acrylic resin. The smaller the powder, especially the smaller the particle size, the larger the surface area and the easier it is to charge static electricity.
[0016]
These objects can be easily charged with static electricity, and positive and negative charges can be freely charged using the self-discharge type by electricity and the voltage printing pressure type by pulse DC method or steady DC method. Chargeability can be imparted. In particular, a strong positive or negative high charging property can be obtained more easily by the pulse direct current method.
[0017]
However, the state of electrostatic charge in all ordinary substances decreases in a very short time, but some of the organic fluororesin compounds are extremely strong and charged for a long time, and furthermore, pulse direct current due to electricity. It was found that the method can easily give a strong high chargeability, and in most cases, has a unique property of being negatively charged.
[0018]
Therefore, in the present invention, the ore powder having natural polarization is brought into contact with the negatively charged organic fluororesin compound so that the ore powder having natural polarization generates a large amount of negative ions.
[0019]
As the ore powder having natural polarization, it is preferable to use a tourmaline powder or a powder containing the same, and the organic fluororesin compound may be used in a negatively charged state by being electrically charged in advance. Although it may be negatively charged by electrical charging after contact and mixing with tourmaline powder, it is negative ion release to use a pre-negatively charged organic fluororesin compound with ore powder having natural polarization. it is more effective in terms of quantity.
[0020]
In general, it is preferable that both the ore having natural polarization and the organic fluororesin compound are powders having a particle diameter of 1 mm or less and the mixing ratio thereof is 1/99 to 99/1. When the particle diameter of these powders exceeds 1 mm, the contact point and the surface area are reduced, so that the release of negative ions is reduced, making it difficult to obtain a desired effect. The contact / mixing ratio of the ore powder having natural polarization and the organic fluororesin compound powder is particularly preferably 10:90 to 50:50.
[0021]
In addition, a resin molded body containing a mixture of ore powder having a natural polarization and an organic fluororesin compound, or a paint containing an ore powder having a natural polarization and an organic fluororesin compound is manufactured, and this is made of cloth, paper, wood, plastic, A negative ion generator may be applied to metal or other equipment. In this case, negative charging to the organic fluororesin compound may be performed after the resin molded body is manufactured or after the coating is applied.
[0022]
As typical examples of the organic fluororesin compound used in the present invention,
Polytetrafluoroethylene / ethylene copolymer resin,
Polytetrafluoroethylene / propylene copolymer resin,
Polytetrafluoroethylene / perfluoroalkyl vinyl ether copolymer resin,
Polytetrafluoroethylene / hexafluoropropylene copolymer resin,
Polytetrafluoroethylene / hexafluoropropylene / perfluoroalkyl vinyl ether copolymer resin,
Polytetrafluoroethylene resin,
Polyvinyl fluoride resin,
Polyvinylidene fluoride resin,
Examples thereof include polychlorotrifluoroethylene resin and polychlorotrifluoroethylene / ethylene copolymer resin. In either case, commercially available products can be used.
[0023]
In the present invention, a cylindrical rotary device having a plurality of apertures around, putting the powder of an ore having spontaneous polarization, a powder of organic fluororesin Aburaka compound obtained by negatively charged, rotating By making it, it can also be set as the product which can produce | generate a lot of negative ions. In this case, it is preferable to attach a filter to the outer periphery (or inner periphery) of the rotating device so that the powder mixture does not leak, but this filter is also negatively charged with ore powder having natural polarization. and by the paint併含organic fluororesin Aburaka compound such as using the coated fabric, the causes are併含organic fluororesin Aburaka compound of powder and is negatively charged ore having spontaneous polarization preferable. In particular, when the rotating device is made of aluminum, it is possible to generate amazing negative ions.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Next, based on an Example and a comparative example, this invention is demonstrated in more detail, The instrument apparatus etc. which were used in the Example etc. are as follows.
[Electrostatic load generator]
Pulse direct current type pulse ionizer A-20J (manufactured by Suzuki Shokai, Kyoto). It was used under the conditions of an output DC voltage of 5 kv, two tungsten electrode needles, an air outlet 1/2 inch NTP, an operating air pressure of 5 kgf / cm 3 , a distance between the electrode needle and the sample of 10 cm, and a radiation time of 5 seconds.
[Negative ion and positive ion generation performance evaluation]
Measurement was performed with an ionary measuring instrument SSI-1500 (manufactured by Suzuki Shokai, Kyoto) equipped with a dynamic system air ion counter FIC-2000 (manufactured by Tokyo Fecer, Tokyo) as an ion measuring instrument. The measurement conditions are as follows.
As the measurement atmosphere, the distance from the inlet of the constant temperature and constant temperature air ion counter FIC-2000 at a temperature of 20 ° C. and humidity of 40% to the measurement sample is 15 cm, the vertical amplitude distance of the measurement sample is 15 cm, and the number of amplitudes is 100 times / minute (speed 30 m / minute) ), And the measurement result shows the amount of maximum negative ions and maximum positive ions in one minute. The average number of negative ions and positive ions per minute was measured for the number of ions per cc.
[0025]
Example 1
Polytetrafluoroethylene resin (Chacosilica TEE-100 manufactured by Techchem Laboratories: average particle size 0.02 mm powder) as an organic fluororesin compound powder-hereinafter, abbreviated as TFE powder -10 g was subjected to negative static electricity by an electrostatic load device. And 90 g of black tourmaline powder (powdered particle size of 5 to 20 μm, manufactured by Enex Co., Ltd.), sealed inside a double bag of 5 × 10 cm square fine fine 100% cotton twill fabric that has been refined and bleached. It was measured.
[0026]
Examples 2-4
The amount of ions was measured in the same manner as in Example 1 except that the amounts of TFE powder and black tourmaline powder were changed as follows.
[Example 2] 50 g of TFE powder and 50 g of black tourmaline powder
[Example 3] 75 g of TFE powder and 25 g of black tourmaline powder
[Example 4] 90 g of TFE powder and 10 g of black tourmaline powder
[0027]
Example 5
Example 1 except that the TFE powder of Example 1 was changed to a polytetrafluoroethylene-hexafluoropropylene-perfluoroalkyl vinyl ether copolymer (Kausilica PPF-2300 manufactured by Techchem Laboratories: average particle size 0.2 mm powder). The amount of ions was measured by the same method as in 1.
[0028]
Comparative Example 1
Only the black tourmaline powder used in Example 1 was sealed inside a 5 × 10 cm square double bag of fine high density 100% cotton twill fabric that had been refined and bleached, and the amount of ions was measured.
[0029]
Comparative Example 2
The amount of ions was measured in the same manner as in Comparative Example 1 using black tourmaline powder imparted with negative static electricity.
[0030]
Comparative Example 3
Only the TFE powder used in Example 1 was sealed inside a double bag of 5 × 10 cm square fine fine 100% cotton twill fabric that had been refined and bleached, and the amount of ions was measured.
[0031]
Comparative Example 4
The amount of ions was measured in the same manner as in Comparative Example 3 using TFE powder provided with negative static electricity.
[0032]
The results obtained in Examples 1 to 5 and Comparative Examples 1 to 4 are shown in Table 1.
[0033]
[Table 1]
Example 6-Example of attaching negative ion generator to cotton fabric-
100 parts by weight of a 0.2% aqueous solution of polyacrylic resin-based viscous settlement inhibitor (Alcoprint PTF manufactured by Allied, UK), 5 parts by weight of polyurethane emulsion binder (Tech Coat WH960 manufactured by Furukawa Giken), migration As an inhibitor, 3 parts by weight of 10% sodium alginate aqueous solution, 1 part by weight of a blocked isocyanate-based crosslinking agent (Super Fresh JB-7300 manufactured by Furukawa Giken Co., Ltd.), diphenyl ether-based anionic surfactant penetrant (Perex SSH manufactured by Kao Corporation) Polytetrafluoroethylene / ethylene copolymer resin concentration 45 containing 4 parts by weight of black tourmaline powder (powder having a particle size of 0.5 μm or less) and 4% of nonylphenol surfactant in a stock solution in which 0.2 parts by weight was mixed and stirred uniformly % Aqueous dispersion (manufactured by Techchem Laboratories) Kaoshirika TEEC-45) 11 parts by weight were mixed and stirred for 5 minutes at Homodesupa -1000Rpm, to prepare a treatment liquid.
Sophisticated and bleached pharmacopoeia gauze is soaked in this treatment solution for 5 seconds, uniformly drawn with two mangles at a drawing rate of 80%, dried at 100 ° C. for 5 minutes, heat treated at 160 ° C. for 2 minutes, and then hot water at 50 ° C. For 1 minute, squeezed and dried at 100 ° C. for 3 minutes.
The treated gauze thus obtained was subjected to negative static electricity with an electrostatic load generator to obtain a test piece.
The test piece is cut into a 10 cm × 2 cm strip shape, stacked so that it becomes 20 g ± 0.2 g, one of the long sides is bound and bound, and the other is not bound, and the one bound to the ioner measuring instrument is The ion amount was measured with the above-mentioned measuring instrument and measurement conditions.
[0035]
Example 7
The same method as in Example 6 except that instead of the polytetrafluoroethylene / ethylene copolymer resin in Example 6, an aqueous dispersion having a polytetrafluoroethylene resin concentration of 45% (Kao Silica TEEC-45L manufactured by Techchem Laboratories) was used. And the amount of ions in the test piece was measured.
[0036]
Comparative Example 5
The same method as in Example 6 was performed except that the treatment gauze was not subjected to a treatment for applying negative static electricity with an electrostatic load generator.
[0037]
Comparative Example 6
A test piece was prepared by the method of Example 6 without using polytetrafluoroethylene / ethylene copolymer resin, and Example 6 was performed except that the treatment gauze was not subjected to a treatment for applying negative static electricity with an electrostatic load generator. A similar method was performed.
[0038]
Comparative Example 7
Same as Example 6 except that the black tourmaline powder and the polytetrafluoroethylene / ethylene copolymer resin are not mixed by the method of Example 6 and the treatment gauze is not subjected to a treatment for applying negative static electricity with an electrostatic load generator. The method of was implemented.
[0039]
Example 8
Long oil-based phthalic acid solvent paint (House Paint PRO white produced by Campe Pavilio Co., Ltd.) 100 parts by weight Toluene 50 parts by weight, acetone 50 parts by weight, polytetrafluoroethylene perfluoroalkyl vinyl ether copolymer resin (manufactured by Techken Laboratory) 10 parts by weight of powder with an average particle diameter of 20 μm (caosilica TEFAB-1501) and 3 parts by weight of pink tourmaline powder (powder with an average particle diameter of 10 μm or less manufactured by Enex) are mixed and stirred, and applied uniformly to a commercially available paper-based wallpaper. The sample was dried for 48 hours, negative static electricity was applied using an electrostatic load generator as in Example 6, and the amount of ions was measured as a strip-shaped test piece.
[0040]
Comparative Example 8
Only the commercially available paper-based wallpaper used in Example 8 was measured for the amount of ions as a strip without applying negative static electricity.
[0041]
Comparative Example 9
The same method as in Example 8 was carried out without mixing the polytetrafluoroethylene / perfluoroalkyl vinyl ether copolymer resin powder used in Example 8 and without applying negative static electricity.
The test results of Examples 6 to 8 and Comparative Examples 5 to 9 are shown in Table 2.
[0042]
[Table 2]
Example 9
An aqueous dispersion of 0.5 parts by weight of tourmaline 0.5 μm (manufactured by Enex) and 45% polytetrafluoroethylene / ethylene copolymer resin in order to supply negative ions to the indoor air (Kao Silica TEEC-45 manufactured by Techken Laboratory) A mixture of 1.2 parts by weight, 80 parts by weight of pure water, and 18.3 parts by weight of dimethyl ether is filled in a spray can, and sprayed onto an aluminum box connected to an ion meter for 1 second from a distance of 1 meter to give an ion amount. It was measured.
[0044]
Example 10
The same method as in Example 9 was performed except that the distance between the sprays and the box was 2 meters.
The test results of Examples 9 and 10 are shown in Table 3.
[0045]
[Table 3]
Example 11
Mixing 100 parts by weight of polytetrafluoroethylene resin negatively charged by the above-mentioned method (Kaosilica TFE-1010 manufactured by Techken Laboratory: average particle size 0.02 mm) and 100 parts by weight of tourmaline particle size 5 to 20 μm (manufactured by Enex) The prepared mixed powder and the following filter were prepared.
The filter was negatively charged by the above method to 100 parts by weight of an acrylic resin binder-containing mineral turpent fiber pigment printing paste (Unibinder MCO manufactured by Uni Kasei Co., Ltd .: white paste with a viscosity of 21000 cps) on the surface of a cotton cloth. 7 parts by weight of polytetrafluoroethylene powder having an average particle diameter of 10 μm (Kao silica TFE-2200 manufactured by Techken Laboratory) and 4 parts by weight of black tourmaline powder having an average particle diameter of 3 μm (manufactured by Enex Co., Ltd.) were added. Apply a 48,000 cps gray paste obtained by stirring and mixing for 10 minutes on a silk screen, dry for 6 hours, apply the same paste again, and after 12 hours of drying, The same processing is performed.
This filter is made of an aluminum cylinder (length 20 cm, diameter 6.5 cm, 72 holes with a diameter 2 cm are provided around it, and the center axis can be rotated as a rotation axis). The outer periphery is fixed so that the contents do not leak, the mixed powder is put, the cylinder is sealed with a lid, rotated at 3 revolutions / second about the axis, and 30 cm away from the ionary measuring instrument. The amount of ions at was measured.
[0047]
Example 12
The same method as in Example 12 was performed except that the aluminum cylinder of Example 11 was replaced with a wooden cylinder.
The test results of Examples 11 and 12 are shown in Table 4.
[0048]
[Table 4]
【The invention's effect】
Since the product of the present invention has substantially no risk of emitting radiation, and stably and efficiently emits negative ions for a long period of time, it is very easy to handle and enables various product development. .
Claims (7)
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Free format text: JAPANESE INTERMEDIATE CODE: R250 |
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| R250 | Receipt of annual fees |
Free format text: JAPANESE INTERMEDIATE CODE: R250 |
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| LAPS | Cancellation because of no payment of annual fees |