序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
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121 | PERMEABLE, SHAPED STRUCTURES OF ACTIVE PARTICULATE BONDED WITH PSA POLYMER MICROPARTICULATE | EP96941491.0 | 1996-11-26 | EP0865314A1 | 1998-09-23 | SENKUS, Raymond; YOUNG, Chung, L.; BARRETT, Leonard, W.; LU, Ying-Yuh |
A fluid permeable composite structure having active particulate bonded together using a pressure-sensitive adhesive (PSA) polymer microparticulate. Use of the PSA polymer microparticulate to bond the active particulate together produces a bonded structure that, unlike previously-developed active bonded structures, is flexible and therefore can be conformed into a variety of shapes. The shaped structures may be used as gaseous filters in a wide variety of respirators. | ||||||
122 | Imprägnierung für Atemschutzfilter mit Aktivkohle | EP91104400.6 | 1991-03-21 | EP0450414B1 | 1995-03-15 | von der Smissen, Carl Ernst, Dr. |
123 | VERFAHREN, FILTER UND VORRICHTUNG ZUR BEREITSTELLUNG VON ATEMLUFT MIT HOHER LUFTGÜTE | EP88904533.2 | 1988-05-26 | EP0317593B1 | 1993-01-27 | IGELBÜSCHER, Heinrich; GRESCH, Heinrich; HöLTER, Heinz |
Process, filter and device for eliminating from the air inhaled bacteria and/or viruses and/or fungi and/or spores and/or germs and/or allergens and/or contaminants and/or odors, etc, by means of a filter consisting of one or several layers of chemisorption mixture. In order to prevent the possible release of fungus spores and bacteria by biofilters in operation for a long time, it is proposed to use downstream of a biofilter layers of bulk material as chemisorption mixture layers alternately of a very strongly alkaline and very strongly acid nature or vice-versa. For the bulk material, use is made of coal coke of types III or IV of crushed coke with strongly alkaline and strongly acid chemisorption layers. The individual layers of chemisorption mixture are felt layers which are impregnated with alkaline, acid and/or neutral liquids or vice-versa, subsequently dried and superimposed in an alternating manner, being used as a chemisorption layer, hydrophobic separation layers being located between the chemisorption layers. In order to eliminate smells, said chemisorption layers consist of activated carbon treated with propylene glycol. Projecting from the inlet side of the air humidifier installation is a chemisorption filtering assembly which enables humidification of the air free from allergens and totally blocs the airborne allergens as well as the germs. After interruption of the unit by hand or by remote control, a bactericidal and fungicidal chemisorption filter also acts as a barrier on the discharge side. | ||||||
124 | Filter paper | EP84110513.3 | 1984-09-04 | EP0145849B1 | 1989-07-26 | Giglia, Robert Domenico |
125 | Oxidation catalysts | EP83306312.6 | 1983-10-18 | EP0107471B1 | 1989-03-08 | Holt, Andrew; Cheek, Martin Charles; Clegg, Ernest Neville |
Catalysts adapted to catalyse the oxidation of carbon monoxide to carbon dioxide comprise palladium, one or more of the metals platinum, ruthenium, rhodium and iridium and one or more of the metals copper, nickel, cobalt, iron, manganese, silver, lanthanum, cerium, praseodymium and neodymium on substantially chloride-free stannic oxide supports. | ||||||
126 | Pt-Katalysator auf einem Träger als Luftreinigungsmittel | EP84111819.3 | 1984-10-03 | EP0151685A1 | 1985-08-21 | van der Smissen, Carl-Ernst, Dr. |
In Kohlenoxid-Atemschutzfiltern wird das in der Einatemluft enthaltene giftige Kohlenoxid auf der Oberfläche von Kohlenoxid-Katalysatoren mit Luftsauerstoff zur Reaktion gebracht und damit beseitigt. Für viele Anwendungsbereiche von Luftfiltern ist es jedoch wünschenswert, außer CO auch noch andere schädliche Gase aus der Luft zu entfernen. Der hier verwendete Pt-Katalysator als Atemschutzfiltermaterial bietet vor allem nur geringen Schutz zusätzlich gegen saure Gase. Durch eine zusätzliche Imprägnierung mit den Oxiden amminbildender Schwermetalle wird die Abscheideleistung gegenüber den sauren Gasen außerordentlich erhöht, ohne die Fähigkeit des Pt-Katalysators zur katalytischen CO-Oxidation zu verringern. Es ergibt sich sogar eine Verstärkung der jeweiligen Wirksamkeit. |
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127 | Filter paper | EP84110513.3 | 1984-09-04 | EP0145849A1 | 1985-06-26 | Giglia, Robert Domenico |
A toxic vapour absorptive nonwoven filter material comprising a wet-laid sheet containing fibrillated binder fibre, active carbon in fibre or particle form and submicron diameter glass fibre. The surface of the filter material may by treated with a hydrophobic or an oleophobic agent. |
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128 | METHOD FOR PRODUCING HYDROPHOBIZED MIXED METAL OXIDE NANOPARTICLES AND USE THEREOF FOR HETEROGENEOUS CATALYSIS | US15737299 | 2016-07-01 | US20180154200A1 | 2018-06-07 | Tim BIEMELT; Julia GROTHE; Stefan KASKEL |
The invention relates to methods for producing hydrophobized, doped or non-doped mixed metal oxide nanoparticles or doped metal oxide nanoparticles by flame spray pyrolysis, wherein a combustible precursor solution A, containing at least two metal alkyloates of general formula Me(OOC—R)x with differing metals Me, or a combustible precursor solution B containing at least one metal alkyloate of general formula Me(OOC—R)x and at least one metal salt containing a metal ion Me and at least one metal salt containing a metal ion Me, with Me selected from metal ions of the subgroups of the periodic system of the elements, with R=alkyl or aryl, wherein the alkyl chain is branched or straight, and wherein x corresponds to the oxidation step of the metal ion, is used in stoichiometric excess relative to a quantity of oxygen, and wherein a combustion ratio c of 3.5 bis 0.4 is established, and hydrophobized nanoparticles and the use thereof. | ||||||
129 | METAL ORGANIC FRAMEWORKS FOR THE CATALYTIC DETOXIFICATION OF CHEMICAL WARFARE NERVE AGENTS | US15412412 | 2017-01-23 | US20170128761A1 | 2017-05-11 | Joseph T. HUPP; Omar K. FARHA; Michael J. KATZ; Joseph E. MONDLOCH |
A method of using a metal organic framework (MOF) comprising a metal ion and an at least bidendate organic ligand to catalytically detoxify chemical warfare nerve agents including exposing the metal-organic-framework (MOF) to the chemical warfare nerve agent and catalytically decomposing the nerve agent with the MOF. | ||||||
130 | Metal organic frameworks for the catalytic detoxification of chemical warfare nerve agents | US14585718 | 2014-12-30 | US09623404B2 | 2017-04-18 | Joseph T. Hupp; Omar K. Farha; Michael J. Katz; Joseph E. Mondloch |
A method of using a metal organic framework (MOF) comprising a metal ion and an at least bidendate organic ligand to catalytically detoxify chemical warfare nerve agents including exposing the metal-organic-framework (MOF) to the chemical warfare nerve agent and catalytically decomposing the nerve agent with the MOF. | ||||||
131 | HYDROGEN RICH WATER GENERATOR | US15064516 | 2016-03-08 | US20160263535A1 | 2016-09-15 | Hsin-Yung Lin |
A hydrogen rich water generator includes a container, a hydrogen input, a dividing tube, a vibrator, and a cover. The container is used for containing water and comprises an opening and an inner wall. The hydrogen input is one-piece formed on the inner wall of the container and interconnects the inside and the outside of the container. The dividing tube is configured in the container and connected to the hydrogen input. The vibrator is used for vibrating the water. The cover is configured on the opening of the container wherein when the cover is removed, the water can be added or hydrogen rich water can be taken out. The vibrator of the creation can assist the hydrogen micro bubbles mixed with the water well to generate hydrogen rich water and humidified hydrogen. | ||||||
132 | METAL ORGANIC FRAMEWORKS FOR THE CATALYTIC DETOXIFICATION OF CHEMICAL WARFARE NERVE AGENTS | US14585718 | 2014-12-30 | US20160175827A1 | 2016-06-23 | Joseph T. HUPP; Omar K. FARHA; Michael J. KATZ; Joseph E. MONDLOCH |
A method of using a metal organic framework (MOF) comprising a metal ion and an at least bidendate organic ligand to catalytically detoxify chemical warfare nerve agents including exposing the metal-organic-framework (MOF) to the chemical warfare nerve agent and catalytically decomposing the nerve agent with the MOF. | ||||||
133 | Filtration Medium with Electrospun Metal Oxide Nanofiber Layer | US14394449 | 2012-04-17 | US20150250910A1 | 2015-09-10 | Gurdev Singh; Anbharasi Vanangamudi; James Antony Prince |
A multi-layered filtration medium for detoxification of chemical contaminants and disinfection of biological contaminants. The filtration medium includes two disinfection nanofiber layers and one detoxification nanofiber layer disposed between the two disinfection nanofiber layers. The filtration medium is loaded with high content of a detoxifying material which capable of achieving about 95% detoxification efficiency with no leaching of the detoxifying material. The filtration medium may also include a medicinal substance for medical applications and a sensor for indicating the lifetime of the filtration medium. | ||||||
134 | Process for producing spherical activated carbon | US11890356 | 2007-08-06 | US08927457B2 | 2015-01-06 | Hasso Von Blucher; Ernest De Ruiter |
Disclosure is made of a specific process for producing activated carbon in spherical form, starting with organic polymer spherules based on styrene and divinylbenzene, wherein said polymer spherules contain chemical groups leading to the formation of free radicals and thus to cross-linkages by their thermal decomposition, in particular sulfonic acid groups. Furthermore, various application purposes for the thus-produced activated carbon spherules are named. | ||||||
135 | Multifunctional electroprocessed membranes | US12840916 | 2010-07-21 | US08684189B2 | 2014-04-01 | Liang Chen; Lev E. Bromberg; Trevor Alan Hatton; Gregory C. Rutledge |
Described is the application of layer-by-layer (LbL) electrostatic assembly techniques to electrospun nanofibers in order to fabricate novel, breathable electrospun fiber-based chemical and biological detoxifying protective fabrics and filters. The combination of layer-by-layer electrostatic assembly and electrospinning technique allows one to take advantage of high specific surface area, light weight and breathability of electrospun fiber mats while simultaneously providing the versatility to incorporate different functional polyelectrolytes to achieve multifunctional coatings for both chemical and biological protection together. The functionalized fiber mats can be incorporated into breathable chemical and biological protective fabrics, filters and masks. In addition, LbL electrostatic coating of porous non-woven materials provides the versatility to generate multifunctional polymer-based membrane materials for other applications. | ||||||
136 | Zirconium hydroxide for decontaminating toxic agents | US12917811 | 2010-11-02 | US08530719B1 | 2013-09-10 | Gregory W. Peterson; Joseph A. Rossin; George W. Wagner |
The present invention relates to a process for decontaminating surfaces contaminated with toxic agents. The process comprises contacting a contaminated surface with a sorbent comprised of zirconium hydroxide onto which at least one reactive moiety is optionally impregnated. | ||||||
137 | Catalysts, Activating Agents, Support Media, and Related Methodologies Useful for Making Catalyst Systems Especially When the Catalyst is Deposited onto the Support Media Using Physical Vapor Deposition | US13650782 | 2012-10-12 | US20130045155A1 | 2013-02-21 | Larry A. Brey; Thomas E. Wood; Gina M. Buccellato; Marvin E. Jones; Craig S. Chamberlain; Allen R. Siedle |
Use of physical vapor deposition methodologies to deposit nanoscale gold on activating support media makes the use of catalytically active gold dramatically easier and opens the door to significant improvements associated with developing, making, and using gold-based, catalytic systems. The present invention, therefore, relates to novel features, ingredients, and formulations of gold-based, heterogeneous catalyst systems generally comprising nanoscale gold deposited onto a nanoporous support. | ||||||
138 | Catalysts, activating agents, support media, and related methodologies useful for making catalyst systems especially when the catalyst is deposited onto the support media using physical vapor deposition | US13167293 | 2011-06-23 | US08314048B2 | 2012-11-20 | Larry A. Brey; Thomas E. Wood; Gina M. Buccellato; Marvin E. Jones; Craig S. Chamberlain; Allen R. Siedle |
Use of physical vapor deposition methodologies to deposit nanoscale gold on activating support media makes the use of catalytically active gold dramatically easier and opens the door to significant improvements associated with developing, making, and using gold-based, catalytic systems. The present invention, therefore, relates to novel features, ingredients, and formulations of gold-based, heterogeneous catalyst systems generally comprising nanoscale gold deposited onto a nanoporous support. | ||||||
139 | MASK | US13395670 | 2010-09-30 | US20120192876A1 | 2012-08-02 | Yoshie Fujimori; Youhei Jikihara; Tetsuya Sato; Yoko Fukui; Tsuruo Nakayama |
A mask is provided that can inactivate viruses adhering thereto even in the presence of lipids and proteins regardless of whether or not the viruses have an envelope. The mask can inactivate viruses adhering thereto and includes a mask body provided with a member used when the mask is worn and virus inactivating fine particles having a virus inactivating ability and held by the mask body. The virus inactivating fine particles are particles of at least one selected from the group consisting of platinum(II) iodide, palladium(II) iodide, silver(I) iodide, copper(I) iodide, and copper(I) thiocyanate. | ||||||
140 | Material compositions for microbial and chemical protection | US12263782 | 2008-11-03 | US08192765B2 | 2012-06-05 | Shantha Sarangapani |
An antimicrobial and chemical deactivating composition for use in a liquid medium or for incorporation into a coating, structural plastic materials, thin microporous membranes, textiles and sponges. The composition includes macrosize or submicron particles of silver, platinum with silver and their salts with parabens, oxide, salicylate, acetate, citrate, benzoate and phosphate along with copper and zinc salts of the same. |