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JP3774112B2 - Method for producing negative ion generator - Google Patents
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JP3774112B2 - Method for producing negative ion generator - Google Patents

Method for producing negative ion generator Download PDF

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JP3774112B2
JP3774112B2 JP2000255114A JP2000255114A JP3774112B2 JP 3774112 B2 JP3774112 B2 JP 3774112B2 JP 2000255114 A JP2000255114 A JP 2000255114A JP 2000255114 A JP2000255114 A JP 2000255114A JP 3774112 B2 JP3774112 B2 JP 3774112B2
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JP2002065835A (en
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国男 福田
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Description

【0001】
【発明の属する技術分野】
本発明は、こんにゃくいもの精粉、またはこんにゃくの生玉とトルマリン微粉末および炭微粉末を基材とし、更に遠赤外線放射特性を有するセラミックス微粉末を添加材とするマイナスイオン生成体の製造方法に関するものである。
【0002】
【従来の技術】
従来、商用の低電圧電力を高電圧に変換し、高電圧放電によりマイナスイオンを発生させるマイナスイオン発生器が実用に供されていた。
【0003】
【発明が解決しようとする課題】
前記従来のマイナスイオン発生器では、マイナスイオンをある程度発生させることができるが、高電圧放電の際に相当量のオゾンの発生を伴うので、健康に対する安全性に関し危惧があるという課題があった。
【0004】
本発明は、前記従来の課題を解決すべくなされたもので、電力を全く使用することなく、従ってオゾンを全く発生させることなく、マイナスイオンを多量に発生させることができるマイナスイオン生成体の製造方法を提供しようとするものである。
【0005】
【課題を解決するための手段】
本発明は、第1の基材であるこんにゃくいもの精粉(こんにゃく粉)を、該精粉の重量に対して約5〜30倍の重量の水に投入して混合撹拌して前記精粉を充分に水に溶かし、粘着性が出るまで撹拌作用を続けて粘着性を有するこんにゃく溶液を得る第1工程と、前記第1工程で得られた粘着性を有するこんにゃく溶液に、前記こんにゃく溶液の重量に対して、第2の基材であるトルマリン微粉末10〜50重量%および第3の基材である炭微粉末10〜50重量%をそれぞれ混入すると共に、添加材として遠赤外線放射特性を有するセラミックス微粉末3〜10重量%を添加混入して混合撹拌し、前記各基材および添加材がこんにゃく溶液中に均等に分散するまで撹拌して混合溶液を得る第2工程と、前記第2工程で得られた混合溶液の重量に対して2〜5重量%の炭酸ナトリウム、もしくは木灰を固化材として前記混合溶液と共に熱湯に溶かし、該混合溶液が柔軟性を有する程度(つきたてのもちの状態)まで半固化するよう撹拌して半固化物を得る第3工程と、前記第3工程で得られた半固化物を最終使用形態の所定の形状に合わせて成型し、所定形状の成型体を得る第4工程と、
前記第4工程で得られた成型体を熱湯に投入して煮沸し、前記成型体をこんにゃく程度の硬さまで固化せしめた後、該煮沸した成型体を熱湯から取り出して−40〜−150℃で急冷凍し、然る後前記急冷凍した成型体を30〜50℃で真空乾燥させて前記成型体より水分を除去して固形物を得る第5工程とより成るマイナスイオン生成体の製造方法。または、
第1の基材であるこんにゃくいもの生玉をすりつぶし、該すりつぶした生玉を水の中に投入して沈殿させ、然る後上澄みを捨てて粘着性を有するこんにゃく溶液を得る第1工程と、前記第1工程で得られた粘着性を有するこんにゃく溶液に、前記こんにゃく溶液の重量に対して、第2の基材であるトルマリン微粉末10〜50重量%および第3の基材である炭微粉末10〜50重量%をそれぞれ混入すると共に、添加材として遠赤外線放射特性を有するセラミックス微粉末3〜10重量%を添加混入して混合撹拌し、前記各基材および添加材がこんにゃく溶液中に均等に分散するまで撹拌して混合溶液を得る第2工程と、前記第2工程で得られた混合溶液の重量に対して2〜5重量%の炭酸ナトリウム、もしくは木灰を固化材として前記混合溶液と共に熱湯に溶かし、該混合溶液が柔軟性を有する程度(つきたてのもちの状態)まで半固化するよう撹拌して半固化物を得る第3工程と、前記第3工程で得られた半固化物を最終使用形態の所定の形状に合わせて成型し、所定形状の成型体を得る第4工程と、前記第4工程で得られた成型体を熱湯に投入して煮沸し、前記成型体をこんにゃく程度の硬さまで固化せしめた後、該煮沸した成型体を熱湯から取り出して−40〜−150℃で急冷凍し、然る後前記急冷凍した成型体を30〜50℃で真空乾燥させて前記成型体より水分を除去して固形物を得る第5工程とより成るマイナスイオン生成体の製造方法。あるいは、
第1の基材であるこんにゃくいもの精粉(こんにゃく粉)を、該精粉の重量に対して約5〜30倍の重量の水に投入して混合撹拌して前記精粉を充分に水に溶かし、粘着性が出るまで撹拌作用を続けて粘着性を有するこんにゃく溶液を得る第1工程と、前記第1工程で得られた粘着性を有するこんにゃく溶液に、前記こんにゃく溶液の重量に対して、第2の基材であるトルマリン微粉末10〜50重量%および第3の基材である炭微粉末10〜50重量%をそれぞれ混入すると共に、添加材として遠赤外線放射特性を有するセラミックス微粉末3〜10重量%を添加混入して混合撹拌し、前記各基材および添加材がこんにゃく溶液中に均等に分散するまで撹拌して混合溶液を得る第2工程と、前記第2工程で得られた混合溶液の重量に対して2〜5重量%の炭酸ナトリウム、もしくは木灰を固化材として前記混合溶液と共に熱湯に溶かし、該混合溶液が柔軟性を有する程度(つきたてのもちの状態)まで半固化するよう撹拌して半固化物を得る第3工程と、前記第3工程で得られた半固化物を熱湯に投入して煮沸し、前記半固化物をこんにゃく程度の硬さまで固化せしめた後、熱湯から取り出して−40〜−150℃で急冷凍し、然る後30〜50℃で真空乾燥させて水分を除去して固形物を得る第4工程と、前記第4工程で得られた固形物を最終使用形態の所定の形状に合わせて成型し、所定形状の成型体を得る第5工程とより成るマイナスイオン生成体の製造方法。更に、
第1の基材であるこんにゃくいもの生玉をすりつぶし、該すりつぶした生玉を水の中に投入して沈殿させ、然る後上澄みを捨てて粘着性を有するこんにゃく溶液を得る第1工程と、前記第1工程で得られた粘着性を有するこんにゃく溶液に、前記こんにゃく溶液の重量に対して、第2の基材であるトルマリン微粉末10〜50重量%および第3の基材である炭微粉末10〜50重量%をそれぞれ混入すると共に、添加材として遠赤外線放射特性を有するセラミックス微粉末3〜10重量%を添加混入して混合撹拌し、前記各基材および添加材がこんにゃく溶液中に均等に分散するまで撹拌して混合溶液を得る第2工程と、前記第2工程で得られた混合溶液の重量に対して2〜5重量%の炭酸ナトリウム、もしくは木灰を固化材として前記混合溶液と共に熱湯に溶かし、該混合溶液が柔軟性を有する程度(つきたてのもちの状態)まで半固化するよう撹拌して半固化物を得る第3工程と、前記第3工程で得られた半固化物を熱湯に投入して煮沸し、前記半固化物をこんにゃく程度の硬さまで固化せしめた後、熱湯から取り出して−40〜−150℃で急冷凍し、然る後30〜50℃で真空乾燥させて水分を除去して固形物を得る第4工程と、前記第4工程で得られた固形物を最終使用形態の所定の形状に合わせて成型し、所定形状の成型体を得る第5工程とより成るマイナスイオン生成体の製造方法。
のいずれかを採用することにより、上記課題を解決した。
【0006】
【発明の実施の形態】
本発明は、こんにゃくいもの精粉、またはこんにゃくの生玉、トルマリン微粉末、炭微粉末を基材とし、更に遠赤外線放射特性を有するセラミックス微粉末を添加材として製造するマイナスイオン生成体の製造方法であり、以下その製造方法につき詳細に説明する。
【0007】
本発明の第1の基材であるこんにゃくいも、またはこんにゃくの生玉は植物繊維を多く含んでいることが知られており、本発明方法ではこの植物繊維が重要な役目を果たす。そして、こんにゃくいもの水分を除いた無水物についての一般成分の組成は、種類と産地によってもあまり変わらず、平均して灰分6.1%、窒素0.57%、糖質95.3%、リン酸0.54%であり、前記糖質の主体は主成分であるコンニャクマンナンで、これを急冷真空乾燥させると繊維状のスポンジ状態となる。
【0008】
また、本発明の第2の基材であるトルマリンは、電気石と称されている誘導体であり、絶えず静電気を帯び続けるという特性を有すると共に、両端に陽極と陰極の電極を作る極性結晶体である。そして、トルマリンは陽極が周辺の大気や液体に存在する電子を引きつけて結晶内に取入れ、該取入れられた電子はトルマリン内部の電流に取込まれるが、そのために余ったマイナスイオンが陰極から放出されて、このマイナスイオンを生成し続けるという機能を有することが知られている。
【0009】
更に、本発明の第3の基材である炭は、竹炭や木炭より成り、炭素を主成分とするものであって、電気的誘導特性を有することが知られている。
【0010】
また更に、本発明の添加材である遠赤外線放射特性を有するセラミックスは、特に限定する必要はないが、好ましくは遠赤外線を放射することが知られている千枚石、水晶、ハモナイト、角閃石、蛇紋石、石英閃緑石、花崗班石、凝灰石、酸化カルシウム、マグネシア、シリカ等のセラミックスを使用することが推奨される。そして、前記セラミックスの放射する遠赤外線の光感現象が前記トルマリンに作用し、これにより該トルマリンからマイナスイオンを多量に放出できるよう、本発明では前記セラミックスを触媒として使用する。
【0011】
前記各基材および添加材を用いた本発明製造方法を更に詳細に説明する。先ず、第1工程として、第1の基材であるこんにゃくいもの精粉(こんにゃく粉)を、該精粉の重量に対して約5〜30倍、好ましくは15倍の重量の水に投入して混合撹拌して前記精粉を充分に水に溶かし、粘着性が出るまで撹拌作用を続け、そして充分粘着性が出たところで第1工程を終了して、粘着性を有するこんにゃく溶液を得る。
【0012】
なお、前記第1工程において、こんにゃくいもの精粉に代えてこんにゃくの生玉を使用することができる。この場合、こんにゃくの生玉をすりつぶし、該すりつぶした生玉を水の中に投入して沈殿させ、然る後上澄みを捨てると前記と同様の粘着性を有するこんにゃく溶液を得ることができる。
【0013】
次に、第2工程として、前記第1工程で得られた粘着性を有するこんにゃく溶液に、前記こんにゃく溶液の重量に対して、第2の基材であるトルマリン微粉末10〜50重量%、好ましくは30重量%および第3の基材である竹炭または木炭の炭微粉末10〜50重量%、好ましくは30重量%をそれぞれ混入すると共に、添加材として千枚石、水晶、ハモナイト、角閃石、蛇紋石、石英閃緑石、花崗班石、凝灰石、酸化カルシウム、マグネシア、シリカ等の遠赤外線放射特性を有するセラミックスの単体またはその複合物より成るセラミックス微粉末3〜10重量%、好ましくは5重量%を添加混入して混合撹拌し、前記各基材および添加材がこんにゃく溶液中に均等に分散するまで撹拌して第2工程を終了して、基材および添加材の混合溶液を得る。前記基材および添加材の粒径は、特に限定する必要はないが、100μm以下、好ましくは30μm以下とすることが推奨される。
【0014】
更に、第3工程として、前記第2工程で得られた基材および添加材の混合溶液の重量に対して2〜5重量%、好ましくは3重量%の炭酸ナトリウム、もしくは木灰を固化材として前記混合溶液と共に熱湯に溶かし、該混合溶液が柔軟性を有する程度(つきたてのもちの状態)まで半固化するよう撹拌し、第3工程を終了して半固化物を得る。
【0015】
そして、第4工程として、前記第3工程で得られた半固化物を最終使用形態、例えば球状、多角形状、円盤状等の所定の形状に合わせて、例えば型抜き等により成型し、第4工程を終了して所定形状の成型体を得る。
【0016】
最後の第5工程として、前記第4工程で得られた成型体を熱湯に投入して約1〜3時間程度煮沸して、前記成型体をこんにゃく程度の硬さまで固化せしめた後、該煮沸した成型体を熱湯から取り出して−40〜−150℃、好ましくは−100℃で急冷凍し、然る後前記急冷凍した成型体を30〜50℃、好ましくは約40℃で真空乾燥させて、前記成型体より水分を除去することにより、本発明マイナスイオン生成体の製造工程を完了しマイナスイオン生成体を得る。
【0017】
前記製造方法によって得られたマイナスイオン生成体は、第5工程で急冷真空乾燥させて水分を除去することにより、こんにゃくいもの繊維質が収縮して強固に絡まり合うと共に、該各繊維質間にトルマリン微粉末、炭微粉末およびセラミックス微粉末が混合した形で取り込まれて一体化され、更に前記水分除去により前記こんにゃくいもの繊維質部分のみがスポンジ状態で残るため、前記トルマリン微粉末、炭微粉末およびセラミックス微粉末を一体に取り込んだマイナスイオン生成体は無数の微細孔を有する多孔質となり、従ってこれにより表面積が大となると共に、該トルマリン微粉末、炭微粉末およびセラミックス微粉末と大気や液体との接触面積が大きくなる。
【0018】
なお、前記第4工程の成型体の製造工程は、前記第5工程の完了後に行うこともできる。すなわち、第4工程として前記第3工程で得られた半固化物を熱湯に投入して、約1〜3時間程度煮沸して前記半固化物をこんにゃく程度の硬さまで固化せしめた後、熱湯から取り出して−40〜−150℃で急冷凍し、然る後30〜50℃で真空乾燥させて水分を除去して固形物を得る。その後、最後の第5工程として、前記第4工程で得られた固形物を最終使用形態の所定の形状に合わせて、例えば切削加工等により成型し、本発明マイナスイオン生成体の製造工程を完了しマイナスイオン生成体を得る。
【0019】
前記製造方法によって得られたマイナスイオン生成体によるマイナスイオン発生メカニズムは、前記したようにトルマリンはどんなに小さく砕き、粉体にしても常にその結晶状態は一定の形を保ち、その両端に陽極と陰極の電極が発生し、陽極が周辺の大気や液体に存在する電子を引きつけて結晶内に取入れ、この電子を陰極へ搬送して、陰極からマイナスイオンを放出し続けるという電気的特性を有している。そして、トルマリン原石から放出されるマイナスイオンは2000個/ccといわれている。
【0020】
前記電気的特性によりマイナスイオンを放出し続けるトルマリンに、炭素を主成分とする竹炭または木炭が保有する電気的誘導特性、および千枚石等のセラミックスが放射する遠赤外線による光感現象が作用して、その両作用の相乗作用により、トルマリンの結晶内に周辺の大気や液体に存在する電子を更に多く引きつけて取入れ、その分多くのマイナスイオンを放出すると共に、更にはトルマリンが微粉末であるため、前記のように大気や液体との接触面積が大であるため、大気や液体からトルマリンが取入れる電子が多くなり、従って前記トルマリンからマイナスイオンを更に多く発生させることができるのである。
【0021】
表1は、本発明製造方法によって得られたマイナスイオン生成体によるマイナスイオンの発生個数を測定した結果を示す表であり、前記したトルマリン原石からは2000個/ccしかマイナスイオンは発生しないが、本発明製造方法によって得られたマイナスイオン生成体によれば、平均9.457個/ccのマイナスイオンが放出されたことが確認できた。なお、測定条件は次の通りである。

Figure 0003774112
【0022】
【表1】
Figure 0003774112
【0023】
前記測定結果から、本発明製造方法によって得られたマイナスイオン生成体は、電力を用いることなく、多量のマイナスイオンを放出していることが証明できた。
【0024】
【発明の効果】
本発明は上述のようであるから、本発明製造方法によって得られたマイナスイオン生成体は、トルマリン微粉末、炭微粉末およびセラミックス微粉末が、こんにゃくいもの繊維質間に取込まれて一体化されると共に、全体が多孔質であるため大気や液体との接触面積が大となり、且つ炭微粉末の電気的誘導特性およびセラミックス微粉末の遠赤外線による光感現象の相乗作用により、トルマリン微粉末からのマイナスイオン放出量を増加させることができるのである。また、本発明製造方法によって得られたマイナスイオン生成体は、電力を使用せず、健康上問題があるオゾンを発生させることなく、多量のマイナスイオンを放出させることができ、そして空気中、水中いずれにおいても使用可能で、然もその形状は目的に応じて自由に成型でき、その用途は広く、空気清浄装置、浄水機、枕等健康機器に使用することにより、その効果を充分に発揮することができる。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for producing a negative ion product using konjac crumbs or konjac raw balls, tourmaline fine powder and charcoal fine powder as a base material, and further using ceramic fine powder having far-infrared radiation characteristics as an additive. Is.
[0002]
[Prior art]
Conventionally, negative ion generators that convert commercial low-voltage power into high voltage and generate negative ions by high-voltage discharge have been put to practical use.
[0003]
[Problems to be solved by the invention]
In the conventional negative ion generator, negative ions can be generated to some extent. However, since a considerable amount of ozone is generated during high voltage discharge, there is a problem that there is a concern about safety for health.
[0004]
The present invention has been made to solve the above-described conventional problems, and is capable of producing a negative ion generator capable of generating a large amount of negative ions without using any electric power, and thus without generating ozone. Is to provide a method.
[0005]
[Means for Solving the Problems]
In the present invention, the first base material, konjac flour, is poured into water having a weight of about 5 to 30 times the weight of the sperm, mixed and stirred, and then Is sufficiently dissolved in water and stirred until the stickiness comes out to obtain a sticky konjac solution, and the sticky konjac solution obtained in the first step is mixed with the konjac solution. While mixing 10 to 50% by weight of tourmaline fine powder as the second base material and 10 to 50% by weight of fine carbon powder as the third base material with respect to the weight, far-infrared radiation characteristics are added as an additive. 2nd step of adding and mixing 3 to 10% by weight of the ceramic fine powder having mixing and stirring, and stirring until each base material and additive are uniformly dispersed in the konjac solution, and the second step Weight of the mixed solution obtained in the process 2-5% by weight of sodium carbonate or wood ash as a solidifying material is dissolved in hot water together with the above mixed solution, and stirred so that the mixed solution is semi-solidified to a degree of flexibility (a state of freshness). A third step of obtaining a semi-solidified product, a fourth step of molding the semi-solidified product obtained in the third step according to a predetermined shape of the final use form, and obtaining a molded body of a predetermined shape,
The molded body obtained in the fourth step is poured into boiling water and boiled. After the molded body is solidified to a hardness of about konjac, the boiled molded body is taken out from the hot water at −40 to −150 ° C. A method for producing a negative ion product comprising the fifth step of rapid freezing and then vacuum drying the rapidly frozen molded body at 30 to 50 ° C. to remove moisture from the molded body to obtain a solid. Or
First step of grinding the raw konjac balls that are the first substrate, throwing the ground raw balls into water to precipitate, and then throwing away the supernatant to obtain a konjac solution having adhesiveness, In the konjac solution having adhesiveness obtained in the first step, 10-50% by weight of tourmaline fine powder as the second base material and charcoal fine powder as the third base material with respect to the weight of the konjac solution. 10 to 50% by weight are mixed together, and 3 to 10% by weight of ceramic fine powder having far-infrared radiation characteristics is added and mixed as an additive, mixed and stirred, and the above-mentioned base material and additive are evenly mixed in the konjac solution. A second step of obtaining a mixed solution by stirring until dispersed, and 2-5% by weight of sodium carbonate or wood ash with respect to the weight of the mixed solution obtained in the second step as a solidifying material It was obtained in the third step, which was dissolved in hot water together with the liquid, and stirred so that the mixed solution was semi-solidified to the extent that it was flexible (a state of freshness), and a semi-solidified product was obtained. The semi-solidified product is molded in accordance with the predetermined shape of the final use form, the fourth step to obtain a molded body of the predetermined shape, and the molded body obtained in the fourth step is poured into boiling water and boiled, and the molding After the body is solidified to a konjac hardness, the boiled molded body is taken out of hot water and rapidly frozen at -40 to -150 ° C, and then the rapidly frozen molded body is vacuum dried at 30 to 50 ° C. And producing a negative ion product comprising a fifth step of removing water from the molded body to obtain a solid. Or
The first base material, konjac flour, is poured into water having a weight of about 5 to 30 times the weight of the sperm, mixed and stirred, and the sperm powder is sufficiently water. The first step of obtaining a konjac solution having a stickiness by continuing the stirring action until the solution becomes sticky, and the konjac solution having the adhesive property obtained in the first step with respect to the weight of the konjac solution Ceramic fine powder having far-infrared radiation characteristics as an additive while mixing 10 to 50% by weight of tourmaline fine powder as the second base material and 10 to 50% by weight of fine carbon powder as the third base material It is obtained in the second step and the second step, in which 3 to 10% by weight is added and mixed and stirred to stir until each base material and additive are evenly dispersed in the konjac solution to obtain a mixed solution. Against the weight of the mixed solution -5% by weight sodium carbonate or wood ash as a solidifying material is dissolved in hot water together with the above mixed solution, and stirred so that the mixed solution is semi-solidified to a degree of flexibility (a state of freshness). The third step of obtaining a product, and the semi-solidified product obtained in the third step is poured into boiling water and boiled, and after the semi-solidified product is solidified to a konjac degree of hardness, it is taken out from the hot water and -40 to 40 A fourth step of rapidly freezing at −150 ° C. and then vacuum drying at 30 to 50 ° C. to remove moisture to obtain a solid, and the solid obtained in the fourth step is used as a predetermined final use form A method for producing a negative ion generator, which comprises the fifth step of obtaining a molded body having a predetermined shape by molding in accordance with the shape of the above. Furthermore,
First step of grinding the raw konjac balls that are the first substrate, throwing the ground raw balls into water to precipitate, and then throwing away the supernatant to obtain a konjac solution having adhesiveness, In the konjac solution having adhesiveness obtained in the first step, 10-50% by weight of tourmaline fine powder as the second base material and charcoal fine powder as the third base material with respect to the weight of the konjac solution. 10 to 50% by weight are mixed together, and 3 to 10% by weight of ceramic fine powder having far-infrared radiation characteristics is added and mixed as an additive, mixed and stirred, and the above-mentioned base material and additive are evenly mixed in the konjac solution. A second step of obtaining a mixed solution by stirring until dispersed, and 2-5% by weight of sodium carbonate or wood ash with respect to the weight of the mixed solution obtained in the second step as a solidifying material It was obtained in the third step, which was dissolved in hot water together with the liquid, and stirred so that the mixed solution was semi-solidified to the extent that it was flexible (a state of freshness), and a semi-solidified product was obtained. The semi-solidified product is poured into boiling water and boiled. After the semi-solidified product is solidified to a konjac hardness, it is taken out from the hot water and quickly frozen at -40 to -150 ° C, and then at 30 to 50 ° C. A fourth step of obtaining a solid by removing moisture by vacuum drying, and a step of obtaining a molded body of a predetermined shape by molding the solid obtained in the fourth step according to a predetermined shape of the final use form A method for producing a negative ion product comprising 5 steps.
By adopting any of the above, the above-mentioned problems were solved.
[0006]
DETAILED DESCRIPTION OF THE INVENTION
The present invention relates to a method for producing a negative ion product, which is produced by using konjac pure powder or konjac raw balls, tourmaline fine powder, charcoal fine powder as a base material, and ceramic fine powder having far infrared radiation characteristics as an additive. The manufacturing method will be described in detail below.
[0007]
It is known that the first base material of the present invention, konjac, or konjac raw balls, contains a large amount of plant fiber, and this plant fiber plays an important role in the method of the present invention. And the composition of the general component about the anhydride except the moisture of konjac does not change so much depending on the type and the place of origin, and on average 6.1% ash, 0.57% nitrogen, 95.3% saccharides, The main component of the saccharide is konjac mannan, which is a main component, and when it is rapidly cooled and vacuum dried, it becomes a fibrous sponge state.
[0008]
The tourmaline, which is the second substrate of the present invention, is a derivative called tourmaline, which has the property of being constantly charged with static electricity, and is a polar crystal that creates anode and cathode electrodes at both ends. is there. Tourmaline attracts electrons present in the surrounding atmosphere and liquid by the anode and takes them into the crystal, and the taken-in electrons are taken into the current inside the tourmaline. Thus, it is known to have a function of continuously generating these negative ions.
[0009]
Furthermore, the charcoal which is the third base material of the present invention is made of bamboo charcoal or charcoal, and has carbon as a main component, and is known to have electrical induction characteristics.
[0010]
Further, the ceramic having far infrared radiation characteristics as the additive of the present invention is not particularly limited, but is preferably a phyllite, quartz, hamonite, amphibole known to emit far infrared radiation. It is recommended to use ceramics such as serpentine, quartz diorite, granite, tuff, calcium oxide, magnesia and silica. Then, in the present invention, the ceramic is used as a catalyst so that the photosensitivity phenomenon of far infrared rays radiated from the ceramic acts on the tourmaline, thereby releasing a large amount of negative ions from the tourmaline.
[0011]
The production method of the present invention using the respective base materials and additives will be described in more detail. First, as a first step, the first base material, konjac flour (konjac flour), is poured into water having a weight of about 5 to 30 times, preferably 15 times the weight of the fine powder. Then, the fine powder is sufficiently dissolved in water by mixing and stirring, and the stirring action is continued until the stickiness is obtained. Then, when the stickiness is sufficiently obtained, the first step is finished to obtain a sticky konjac solution.
[0012]
In the first step, konjac raw balls can be used instead of konjac potato fine powder. In this case, konjac raw balls are ground, and the ground raw balls are poured into water for precipitation, and then the supernatant is discarded to obtain a konjac solution having the same stickiness as described above.
[0013]
Next, as the second step, the adhesive konjac solution obtained in the first step is 10 to 50% by weight of tourmaline fine powder which is the second base material, based on the weight of the konjac solution, preferably Is mixed with 30% by weight and 10 to 50% by weight, preferably 30% by weight, of bamboo charcoal or charcoal fine powder as the third base material, respectively, and as an additive, staghorn, quartz, hamonite, amphibole, Ceramic fine powder of 3 to 10% by weight, consisting of a single substance of ceramics having far-infrared radiation characteristics such as serpentine, quartz diorite, granite, tuff, calcium oxide, magnesia, silica, etc., or a composite thereof, preferably Add 5% by weight, mix and stir, stir until each base material and additive are evenly dispersed in the konjac solution, finish the second step, and mix the base material and additive Get the liquid. The particle size of the base material and additive is not particularly limited, but it is recommended that the particle size is 100 μm or less, preferably 30 μm or less.
[0014]
Further, as the third step, 2 to 5% by weight, preferably 3% by weight of sodium carbonate or wood ash is used as a solidifying material based on the weight of the mixed solution of the base material and additive obtained in the second step. The mixture is dissolved in hot water together with the mixed solution, and stirred so that the mixed solution is semi-solidified to a degree of flexibility (a state of freshly prepared), and the third step is completed to obtain a semi-solid.
[0015]
Then, as the fourth step, the semi-solidified product obtained in the third step is molded according to a predetermined shape such as a spherical shape, a polygonal shape, a disc shape, etc., for example, by die cutting, etc. The process is completed to obtain a molded body having a predetermined shape.
[0016]
As the final fifth step, the molded body obtained in the fourth step was put into boiling water and boiled for about 1 to 3 hours, and the molded body was solidified to a konjac degree of hardness and then boiled. The molded body is taken out of hot water and rapidly frozen at −40 to −150 ° C., preferably −100 ° C., and then the rapidly frozen molded body is vacuum dried at 30 to 50 ° C., preferably about 40 ° C., By removing moisture from the molded body, the production process of the negative ion product of the present invention is completed to obtain the negative ion product.
[0017]
The negative ion product obtained by the above production method is rapidly cooled and vacuum-dried in the fifth step to remove moisture, whereby the konjac fiber is contracted and tightly entangled, and between the fibers. Since tourmaline fine powder, charcoal fine powder and ceramic fine powder are incorporated and integrated in a mixed form, and only the fiber portion of the konjac is left in a sponge state by the moisture removal, the tourmaline fine powder, charcoal fine powder, The negative ion generator in which the powder and the ceramic fine powder are integrally incorporated becomes a porous material having a myriad of fine pores. Accordingly, the surface area is increased, and the tourmaline fine powder, the fine carbon powder, the fine ceramic powder, and the atmosphere. The contact area with the liquid increases.
[0018]
In addition, the manufacturing process of the molded body in the fourth step can be performed after the completion of the fifth step. That is, after the semi-solid obtained in the third step as the fourth step is put into hot water and boiled for about 1 to 3 hours to solidify the semi-solid to a konjac hardness, It is taken out and rapidly frozen at −40 to −150 ° C., and then vacuum dried at 30 to 50 ° C. to remove moisture and obtain a solid. After that, as the final fifth step, the solid material obtained in the fourth step is molded according to the predetermined shape of the final use form, for example, by cutting or the like, and the manufacturing process of the present negative ion generator is completed. Thus, a negative ion generator is obtained.
[0019]
As described above, the mechanism of negative ion generation by the negative ion product obtained by the above manufacturing method is that tourmaline is crushed to a small size, and even if it is powdered, its crystal state always maintains a certain shape, and an anode and a cathode are provided at both ends. The electrode has an electrical property that the anode attracts electrons present in the surrounding atmosphere and liquid and takes them into the crystal, transports these electrons to the cathode, and continues to emit negative ions from the cathode. Yes. And it is said that 2000 negative ions are released from tourmaline ore.
[0020]
The tourmaline, which continues to release negative ions due to the above electrical characteristics, is affected by the electrical induction characteristics possessed by bamboo charcoal or charcoal mainly composed of carbon, and the photosensitivity phenomenon caused by far infrared rays emitted by ceramics such as slabs. As a result of the synergistic effect of these two effects, more electrons are attracted to the surrounding atmosphere and liquids in the tourmaline crystal, releasing more negative ions, and tourmaline is a fine powder. Therefore, since the contact area with the atmosphere or liquid is large as described above, the number of electrons taken in by the tourmaline from the atmosphere or liquid increases, and therefore more negative ions can be generated from the tourmaline.
[0021]
Table 1 is a table showing the results of measuring the number of negative ions generated by the negative ion product obtained by the production method of the present invention, and only 2,000 ions / cc are generated from the above tourmaline rough, According to the negative ion product obtained by the production method of the present invention, it was confirmed that an average of 9.457 ions / cc of negative ions was released. The measurement conditions are as follows.
Figure 0003774112
[0022]
[Table 1]
Figure 0003774112
[0023]
From the measurement results, it was proved that the negative ion product obtained by the production method of the present invention released a large amount of negative ions without using electric power.
[0024]
【The invention's effect】
Since the present invention is as described above, the negative ion product obtained by the production method of the present invention is formed by integrating tourmaline fine powder, charcoal fine powder and ceramic fine powder between konjac fibers. In addition, because the whole is porous, the contact area with the atmosphere and liquid becomes large, and the tourmaline fine powder is produced by the synergistic effect of the electrical induction characteristics of the fine carbon powder and the photosensitivity phenomenon by the far infrared rays of the ceramic fine powder Thus, the amount of negative ions released from can be increased. In addition, the negative ion product obtained by the production method of the present invention can release a large amount of negative ions without using electric power, without generating health-prone ozone, and in the air, underwater It can be used in any case, but its shape can be freely molded according to the purpose, its application is wide, and its effect is fully demonstrated by using it for health equipment such as air purifier, water purifier, pillow etc. be able to.

Claims (4)

第1の基材であるこんにゃくいもの精粉(こんにゃく粉)を、該精粉の重量に対して約5〜30倍の重量の水に投入して混合撹拌して前記精粉を充分に水に溶かし、粘着性が出るまで撹拌作用を続けて粘着性を有するこんにゃく溶液を得る第1工程と、
前記第1工程で得られた粘着性を有するこんにゃく溶液に、前記こんにゃく溶液の重量に対して、第2の基材であるトルマリン微粉末10〜50重量%および第3の基材である炭微粉末10〜50重量%をそれぞれ混入すると共に、添加材として遠赤外線放射特性を有するセラミックス微粉末3〜10重量%を添加混入して混合撹拌し、前記各基材および添加材がこんにゃく溶液中に均等に分散するまで撹拌して混合溶液を得る第2工程と、
前記第2工程で得られた混合溶液の重量に対して2〜5重量%の炭酸ナトリウム、もしくは木灰を固化材として前記混合溶液と共に熱湯に溶かし、該混合溶液が柔軟性を有する程度(つきたてのもちの状態)まで半固化するよう撹拌して半固化物を得る第3工程と、
前記第3工程で得られた半固化物を最終使用形態の所定の形状に合わせて成型し、所定形状の成型体を得る第4工程と、
前記第4工程で得られた成型体を熱湯に投入して煮沸し、前記成型体をこんにゃく程度の硬さまで固化せしめた後、該煮沸した成型体を熱湯から取り出して−40〜−150℃で急冷凍し、然る後前記急冷凍した成型体を30〜50℃で真空乾燥させて前記成型体より水分を除去して固形物を得る第5工程と、
より成ることを特徴とするマイナスイオン生成体の製造方法。
The first base material, konjac flour, is poured into water having a weight of about 5 to 30 times the weight of the sperm, mixed and stirred, and the sperm powder is sufficiently water. A first step of obtaining a konjac solution having a stickiness by continuing to stir until dissolved.
In the konjac solution having adhesiveness obtained in the first step, 10-50% by weight of tourmaline fine powder as the second base material and charcoal fine as the third base material with respect to the weight of the konjac solution. 10 to 50% by weight of the powder is mixed, and 3 to 10% by weight of ceramic fine powder having far-infrared radiation characteristics is added as an additive, mixed and stirred, and the base material and additive are mixed in the konjac solution. A second step of stirring until evenly dispersed to obtain a mixed solution;
2-5% by weight of sodium carbonate or wood ash with respect to the weight of the mixed solution obtained in the second step was dissolved in hot water together with the mixed solution as a solidifying material, and the mixed solution was flexible (attached) The third step of obtaining a semi-solid by stirring to semi-solidify until the state of
A fourth step of obtaining the molded body having a predetermined shape by molding the semi-solidified product obtained in the third step according to a predetermined shape of the final use form;
The molded body obtained in the fourth step is poured into boiling water and boiled. After the molded body is solidified to a hardness of about konjac, the boiled molded body is taken out from the hot water at −40 to −150 ° C. A fifth step of rapidly freezing, and then vacuum drying the rapidly frozen molded body at 30 to 50 ° C. to remove moisture from the molded body to obtain a solid,
A method for producing a negative ion product, comprising:
第1の基材であるこんにゃくいもの生玉をすりつぶし、該すりつぶした生玉を水の中に投入して沈殿させ、然る後上澄みを捨てて粘着性を有するこんにゃく溶液を得る第1工程と、
前記第1工程で得られた粘着性を有するこんにゃく溶液に、前記こんにゃく溶液の重量に対して、第2の基材であるトルマリン微粉末10〜50重量%および第3の基材である炭微粉末10〜50重量%をそれぞれ混入すると共に、添加材として遠赤外線放射特性を有するセラミックス微粉末3〜10重量%を添加混入して混合撹拌し、前記各基材および添加材がこんにゃく溶液中に均等に分散するまで撹拌して混合溶液を得る第2工程と、
前記第2工程で得られた混合溶液の重量に対して2〜5重量%の炭酸ナトリウム、もしくは木灰を固化材として前記混合溶液と共に熱湯に溶かし、該混合溶液が柔軟性を有する程度(つきたてのもちの状態)まで半固化するよう撹拌して半固化物を得る第3工程と、
前記第3工程で得られた半固化物を最終使用形態の所定の形状に合わせて成型し、所定形状の成型体を得る第4工程と、
前記第4工程で得られた成型体を熱湯に投入して煮沸し、前記成型体をこんにゃく程度の硬さまで固化せしめた後、該煮沸した成型体を熱湯から取り出して−40〜−150℃で急冷凍し、然る後前記急冷凍した成型体を30〜50℃で真空乾燥させて前記成型体より水分を除去して固形物を得る第5工程と、
より成ることを特徴とするマイナスイオン生成体の製造方法。
First step of grinding the raw konjac balls that are the first substrate, throwing the ground raw balls into water to precipitate, and then discarding the supernatant to obtain a sticky konjac solution;
In the konjac solution having adhesiveness obtained in the first step, 10-50% by weight of tourmaline fine powder as the second base material and charcoal fine as the third base material with respect to the weight of the konjac solution. 10 to 50% by weight of the powder is mixed, and 3 to 10% by weight of ceramic fine powder having far-infrared radiation characteristics is added as an additive, mixed and stirred, and the base material and additive are mixed in the konjac solution. A second step of stirring until evenly dispersed to obtain a mixed solution;
2-5% by weight of sodium carbonate or wood ash with respect to the weight of the mixed solution obtained in the second step was dissolved in hot water together with the mixed solution as a solidifying material, and the mixed solution was flexible (attached) The third step of obtaining a semi-solid by stirring to semi-solidify until the state of
A fourth step of obtaining the molded body having a predetermined shape by molding the semi-solidified product obtained in the third step according to a predetermined shape of the final use form;
The molded body obtained in the fourth step is poured into boiling water and boiled. After the molded body is solidified to a hardness of about konjac, the boiled molded body is taken out from the hot water at −40 to −150 ° C. A fifth step of rapidly freezing, and then vacuum drying the rapidly frozen molded body at 30 to 50 ° C. to remove moisture from the molded body to obtain a solid,
A method for producing a negative ion product, comprising:
第1の基材であるこんにゃくいもの精粉(こんにゃく粉)を、該精粉の重量に対して約5〜30倍の重量の水に投入して混合撹拌して前記精粉を充分に水に溶かし、粘着性が出るまで撹拌作用を続けて粘着性を有するこんにゃく溶液を得る第1工程と、
前記第1工程で得られた粘着性を有するこんにゃく溶液に、前記こんにゃく溶液の重量に対して、第2の基材であるトルマリン微粉末10〜50重量%および第3の基材である炭微粉末10〜50重量%をそれぞれ混入すると共に、添加材として遠赤外線放射特性を有するセラミックス微粉末3〜10重量%を添加混入して混合撹拌し、前記各基材および添加材がこんにゃく溶液中に均等に分散するまで撹拌して混合溶液を得る第2工程と、
前記第2工程で得られた混合溶液の重量に対して2〜5重量%の炭酸ナトリウム、もしくは木灰を固化材として前記混合溶液と共に熱湯に溶かし、該混合溶液が柔軟性を有する程度(つきたてのもちの状態)まで半固化するよう撹拌して半固化物を得る第3工程と、
前記第3工程で得られた半固化物を熱湯に投入して煮沸し、前記半固化物をこんにゃく程度の硬さまで固化せしめた後、熱湯から取り出して−40〜−150℃で急冷凍し、然る後30〜50℃で真空乾燥させて水分を除去して固形物を得る第4工程と、
前記第4工程で得られた固形物を最終使用形態の所定の形状に合わせて成型し、所定形状の成型体を得る第5工程と、
より成ることを特徴とするマイナスイオン生成体の製造方法。
The first base material, konjac flour, is poured into water having a weight of about 5 to 30 times the weight of the sperm, mixed and stirred, and the sperm powder is sufficiently water. A first step of obtaining a konjac solution having a stickiness by continuing to stir until dissolved.
In the konjac solution having adhesiveness obtained in the first step, 10-50% by weight of tourmaline fine powder as the second base material and charcoal fine as the third base material with respect to the weight of the konjac solution. 10 to 50% by weight of the powder is mixed, and 3 to 10% by weight of ceramic fine powder having far-infrared radiation characteristics is added as an additive, mixed and stirred, and the base material and additive are mixed in the konjac solution. A second step of stirring until evenly dispersed to obtain a mixed solution;
2-5% by weight of sodium carbonate or wood ash with respect to the weight of the mixed solution obtained in the second step was dissolved in hot water together with the mixed solution as a solidifying material, and the mixed solution was flexible (attached) The third step of obtaining a semi-solid by stirring to semi-solidify until the state of
The semi-solidified product obtained in the third step is poured into boiling water and boiled, and after the semi-solidified material is solidified to a konjac hardness, it is taken out from the hot water and rapidly frozen at -40 to -150 ° C, Thereafter, vacuum drying at 30 to 50 ° C. to remove moisture and obtain a solid,
A fifth step of molding the solid material obtained in the fourth step according to a predetermined shape of the final use form, and obtaining a molded body of a predetermined shape;
A method for producing a negative ion product, comprising:
第1の基材であるこんにゃくいもの生玉をすりつぶし、該すりつぶした生玉を水の中に投入して沈殿させ、然る後上澄みを捨てて粘着性を有するこんにゃく溶液を得る第1工程と、
前記第1工程で得られた粘着性を有するこんにゃく溶液に、前記こんにゃく溶液の重量に対して、第2の基材であるトルマリン微粉末10〜50重量%および第3の基材である炭微粉末10〜50重量%をそれぞれ混入すると共に、添加材として遠赤外線放射特性を有するセラミックス微粉末3〜10重量%を添加混入して混合撹拌し、前記各基材および添加材がこんにゃく溶液中に均等に分散するまで撹拌して混合溶液を得る第2工程と、
前記第2工程で得られた混合溶液の重量に対して2〜5重量%の炭酸ナトリウム、もしくは木灰を固化材として前記混合溶液と共に熱湯に溶かし、該混合溶液が柔軟性を有する程度(つきたてのもちの状態)まで半固化するよう撹拌して半固化物を得る第3工程と、
前記第3工程で得られた半固化物を熱湯に投入して煮沸し、前記半固化物をこんにゃく程度の硬さまで固化せしめた後、熱湯から取り出して−40〜−150℃で急冷凍し、然る後30〜50℃で真空乾燥させて水分を除去して固形物を得る第4工程と、
前記第4工程で得られた固形物を最終使用形態の所定の形状に合わせて成型し、所定形状の成型体を得る第5工程と、
より成ることを特徴とするマイナスイオン生成体の製造方法。
First step of grinding the raw konjac balls that are the first substrate, throwing the ground raw balls into water to precipitate, and then discarding the supernatant to obtain a sticky konjac solution;
In the konjac solution having adhesiveness obtained in the first step, 10-50% by weight of tourmaline fine powder as the second base material and charcoal fine as the third base material with respect to the weight of the konjac solution. 10 to 50% by weight of the powder is mixed, and 3 to 10% by weight of ceramic fine powder having far-infrared radiation characteristics is added as an additive, mixed and stirred, and the base material and additive are mixed in the konjac solution. A second step of stirring until evenly dispersed to obtain a mixed solution;
2-5% by weight of sodium carbonate or wood ash with respect to the weight of the mixed solution obtained in the second step was dissolved in hot water together with the mixed solution as a solidifying material, and the mixed solution was flexible (attached) The third step of obtaining a semi-solid by stirring to semi-solidify until the state of
The semi-solidified product obtained in the third step is poured into boiling water and boiled, and after the semi-solidified material is solidified to a konjac hardness, it is taken out from the hot water and rapidly frozen at -40 to -150 ° C, Thereafter, vacuum drying at 30 to 50 ° C. to remove moisture and obtain a solid,
A fifth step of molding the solid material obtained in the fourth step according to a predetermined shape of the final use form, and obtaining a molded body of a predetermined shape;
A method for producing a negative ion product, comprising:
JP2000255114A 2000-08-25 2000-08-25 Method for producing negative ion generator Expired - Fee Related JP3774112B2 (en)

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CN103480253A (en) * 2012-07-13 2014-01-01 北京光耀东方科技开发有限公司 Passive negative-ion catalyst purificant and preparation method thereof

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103480253A (en) * 2012-07-13 2014-01-01 北京光耀东方科技开发有限公司 Passive negative-ion catalyst purificant and preparation method thereof
CN103480253B (en) * 2012-07-13 2015-06-10 北京光耀东方科技开发有限公司 Passive negative-ion catalyst purificant and preparation method thereof

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