121 |
Process of forming spheroidal catalyst particles |
US13407549 |
1949-12-20 |
US2652371A |
1953-09-15 |
GRING JOHN L |
|
122 |
Apparatus for manufacture of microspheroidal gel beads |
US17697850 |
1950-08-01 |
US2633454A |
1953-03-31 |
REX WALTER A; NELSON KARL J |
|
123 |
Manufacture of microspheroidal gel particles |
US6802848 |
1948-12-29 |
US2577631A |
1951-12-04 |
REX WALTER A; NELSON KARL J |
|
124 |
Apparatus for washing gel pellets |
US58169045 |
1945-03-08 |
US2450351A |
1948-09-28 |
PAYNE JOHN W; VALAS PETER D; ATWOOD EDWIN H; BERGSTROM ERIC V |
|
125 |
Product of mercury soluble in water and method of manufacturing same. |
US1898685477 |
1898-07-09 |
US628270A |
1899-07-04 |
LOTTERMOSER ALFRED |
|
126 |
PROCESS FOR MANUFACTURING COLLOIDAL MATERIALS, COLLOIDAL MATERIALS AND THEIR USES |
PCT/IB2009053960 |
2009-09-10 |
WO2010029508A3 |
2011-07-21 |
DUBERTRET BENOIT; ITHURRIA SANDRINE |
The present invention relates to a process for manufacturing a colloidal material, to colloidal materials obtainable by this process and to uses of said colloidal material for the manufacture of optic devices. The colloidal material obtainable by the process of the present invention is of formula An Xm, wherein A is an element selected from groups II, III or IV of the periodic table, wherein X is a metal selected from groups V or VI of the periodic table, and wherein, in the selection of the pair (A, X), the groups of the periodic table of A and X, respectively, are selected from the following combinations : (group II, group VI), (group III, group V) or (group IV, group VI); and wherein n and m are such that An Xm is a neutral compound. For example, the colloidal compound obtainable by the process of the present invention may be CdS, In P, or PbS. Other examples are provided below. The process of the present invention comprises a step of solution phase decomposition of a mixture of X and a carboxylate of formula A(R-COO)p in the presence of a non- or weakly-coordinating solvent, and a step of injecting an acetate salt or acetic acid in the mixture; wherein p is an integer between 1 and 2; R is a linear or branched C1-30alkyl group. The colloidal material of the present inveniton may be used for example for the manufacture of a laser or an optoelectronic device. |
127 |
NANOCRYSTAL/SOL-GEL NANOCOMPOSITES |
PCT/US2004037395 |
2004-11-10 |
WO2005049711A3 |
2006-02-02 |
PETRUSKA MELISSA A; KLIMOV VICTOR I |
The present invention is directed to solid composites including colloidal nanocrystals within a sol-gel host or matrix and to processes of forming such solid composites. The present invention is further directed to alcohol soluble colloidal nanocrystals useful in formation of sol-gel based solid composites. |
128 |
Neutral-tasting microcapsules, method for their manufacturing and their use |
PCT/DE9702557 |
1997-10-25 |
WO9818346A3 |
1998-07-30 |
HEINRICH HANS-WERNER; KUKLINSKI BODO; MEYER UDO; WESTPHAL FRITZ; TELLER JOACHIM |
The invention relates to neutral tasting microcapsules, the method for their manufacturing and their use as human or animal food additives and as carrier systems for medicaments. In accordance with the invention, said capsules consist of oligo and/or polysaccharides, for instance, alginates, which are normally indigestible in the digestive tract combined with digestible components. Preferred are substances which have an unpleasant taste on their own, for example, cod liver oil and/or linseed oil, including also their combination with other substances, e. g. mineral substances, trace elements or substances having an immunological or pharmacological effect. Said microcapsules can be used as valuable human or animal food additives and as vaccines or medicaments since the components are released in the digestive tract. |
129 |
GEL COMPOSITION |
US15559743 |
2017-06-15 |
US20180346847A1 |
2018-12-06 |
Natsu FUKUDA; Masatake JOYABU |
A gel composition having high adhesion, high whitening resistance, and high high-temperature stability is provided.The gel composition includes a polyoxyalkylene alkyl ether (A) represented by general formula (1) and water (B). R—O—(PO)m-(EO)n—H (1) In the formula (1), R is a linear alkyl group having 12 to 22 carbon atoms, PO represents an oxypropylene group, EO represents an oxyethylene group, m and n each represent an average number of moles added, m is a number of 1 to 20, and n is a number of 1 to 80. PO and EO are added in a configuration of block addition. |
130 |
SYSTEM AND METHOD FOR MAKING QUANTUM DOTS |
US15966078 |
2018-04-30 |
US20180312753A1 |
2018-11-01 |
Osman M. BAKR; Jun PAN; Ala'a EL-BALLOULI; Kristian Rahbek KNUDSEN; Ahmed L. ABDELHADY |
Embodiments of the present disclosure provide for methods of making quantum dots (QDs) (passivated or unpassivated) using a continuous flow process, systems for making QDs using a continuous flow process, and the like. In one or more embodiments, the QDs produced using embodiments of the present disclosure can be used in solar photovoltaic cells, bio-imaging, IR emitters, or LEDs. |
131 |
Dispersion and method for forming hydrogel |
US15679432 |
2017-08-17 |
US10105294B2 |
2018-10-23 |
Takayuki Imoto |
An object is to provide dispersion containing lipid peptide type compound useful as low molecular weight gelator, such as lipid dipeptide and lipid tripeptide, and dissolution accelerator capable of dissolving the lipid peptide type compound at lower temperature and more easily. It is also an object to provide dispersion that can form hydrogel by simpler method and under milder condition (low temperature) and from which gel can be obtained as gel having high thermal stability, and provide method for forming the gel. Dispersion including: a lipid peptide type compound in which peptide portion formed by repetition of at least two or more identical or different amino acids is bonded to lipid portion including C10-24 aliphatic group; dissolution accelerator having, in molecules thereof, hydrophilic portion and hydrophobic portion, the hydrophilic portion having betaine structure; and water; and method for producing hydrogel by use of the dispersion. |
132 |
OIL-IN-WATER TYPE EMULSION COMPOSITION AND METHOD FOR PRODUCING SAME |
US15572746 |
2016-12-15 |
US20180280261A1 |
2018-10-04 |
Atsushi NIOH; Kazuki MATSUO; Ippei FUJIYAMA; Haruka GOTO |
Disclosed is an oil-in-water type emulsion composition which has excellent temporal and temperature stability and exerts a good feeling of use; and a method of producing the same. Emulsification is carried out through a specific intermediate phase formed by mixing a surfactant capable of forming an Lα phase, a surfactant capable of forming an H1 phase, and water. The intermediate phase preferably has an interfacial tension of 0.01 to 8 mN/m in terms of relative value with respect to polyperfluoromethylisopropyl ether. The oil-in-water type emulsion composition is produced by a production method that includes the step of sequentially adding an oil phase component and an aqueous phase component to the intermediate phase. |
133 |
Sprayable freshening product comprising suspended particles and methods of freshening the air or a surface with the same |
US15661004 |
2017-07-27 |
US10080814B2 |
2018-09-25 |
Matthew Lawrence Lynch; Carla Jean Colina; Steven Anthony Horenziak; Brandon Philip Illie; Yonas Gizaw |
A method of freshening the air or a surface is provided. The method comprises the steps of: providing a freshening composition, the freshening composition comprising a plurality of particles and a structurant system; and spraying the freshening composition in the form of a plurality of spray droplets, wherein the plurality of spray droplets have: a normalized D(90) value of less than 2.5, when sprayed from a TS800 sprayer according to the SPRAY D(90) NORMALIZED AND SPRAY D(4,3) NORMALIZED TEST METHOD described herein, a residue value of less than about 8 at 5 sprays, according to the RESIDUE TEST METHOD described herein, and a phase stability grade of 1 or 2, according to the PHASE STABILITY GRADE AT 25° C. TEST METHOD described herein. |
134 |
Silica sols, method and apparatus for producing the same and use thereof in papermaking |
US15105801 |
2014-12-17 |
US09975781B2 |
2018-05-22 |
Wen Bai; Jian Xu; Jia Wu; Zhi Chen; Jian Kun Shen; Raymond D. Miller, Jr.; Jane B. Wong Shing |
The present invention relates to colloidal silicas having a low S-value and a high solids content, the preparation thereof, and the use thereof in the production of paper. When used in the production of paper, the colloidal silicas of the invention exhibit good retention and drainage performance so that they can be used in lower amounts compared to conventional colloidal silicas. The present invention also relates to an apparatus and a method for producing such activated colloidal silicas. |
135 |
Method and Device for Making Polymer Microparticles |
US15564265 |
2016-03-01 |
US20180133685A1 |
2018-05-17 |
Lianghua Lu; Lin Chen; Jie Gao; Zhida Pan; Wenqing Peng; Tobias E. Soderman |
A method includes spraying a liquid including polymer and a gas substantially inert to the liquid respectively from a first and second orifice of a nozzle into air to form mist of beads. The beads then are collected with a collecting medium at a temperature in a range from about −10° C. to about 80° C. The collecting medium includes at least one of water and alcohols. |
136 |
SIZE-TUNABLE NANOPARTICLE SYNTHESIS |
US15559534 |
2016-03-17 |
US20180093324A1 |
2018-04-05 |
Mickael TESSIER; Dorian DUPONT; Zeger HENS |
A method for synthesizing nanoparticles with a predetermined size at high or full yield comprises mixing a first precursor material comprising a first compound comprising a halide moiety and a metal or a metalloid, a second precursor material comprising a second compound comprising a polyatomic nonmetal, and a solvent. The method further comprises heating the mixture to colloidally form nanoparticles comprising the polyatomic nonmetal and the metal or metalloid. The halide moiety is selected such as to colloidally form the nanoparticles in a predetermined size range that is at least partially determined by this halide moiety. |
137 |
COMPOSITION FOR NANOEMULSION EMULSIFICATION, BICONTINUOUS MICROEMULSION, COSMETIC, AND METHOD FOR PRODUCING SAME |
US15556836 |
2016-03-09 |
US20180049956A1 |
2018-02-22 |
YUSUKE HARA; KAZUAKI WAKITA |
A nanoemulsion emulsification composition including the following components (A) to (D), in which the mass ratios of the components satisfy the following condition, [(A)+(B)]:(C):(D)=1:4 to 8:0.4 to 0.8; component (A) is a copolymer including a constitutional unit (a1) represented by Formula (1) and a constitutional unit (a2) represented by Formula (2), the molar ratio of the constitutional units (a1):(a2) being 5:95 to 60:40, and the weight average molecular weight being 5,000 to 5,000,000; R1 represents a hydrogen atom or a methyl group R2 represents a hydrogen atom or a methyl group, and R3 represents a hydrocarbon group having 12 to 24 carbons; component (B) is a nonionic surfactant having an HLB value of 10 to 14, component (C) is a polyhydric alcohol, and component (D) is water. |
138 |
NANOPARTICLE WITH PLURAL FUNCTIONALITIES, AND METHOD OF FORMING THE NANOPARTICLE |
US15691800 |
2017-08-31 |
US20180026186A1 |
2018-01-25 |
Qing CAO; Kangguo CHENG; Zhengwen LI; Fei LIU |
A method of forming a nanoparticle includes forming a layer of semiconductor material on a substrate, forming a first layer on the semiconductor material, and etching the semiconductor layer to form the nanoparticle including the first layer on a first side of the nanoparticle and the semiconductor material on a second side of the nanoparticle. |
139 |
Nanoparticle with plural functionalities, and method of forming the nanoparticle |
US15197207 |
2016-06-29 |
US09859494B1 |
2018-01-02 |
Qing Cao; Kangguo Cheng; Zhengwen Li; Fei Liu |
A nanoparticle includes a cuboid base including a semiconductor material, and a plurality of surfaces formed on the base and including a plurality of functionalities, respectively. |
140 |
Method and system for producing calibrated microcapsules |
US14113210 |
2012-04-23 |
US09737864B2 |
2017-08-22 |
Eric Leclerc; Anne-Virginie Salsac; Dominique Barthes-Biesel; Thi Xuan Chu |
The present invention relates to a method for producing microcapsules having a calibrated diameter and at least one parameter characteristic of the mechanical properties of an equally calibrated microcapsule, characterized in that the method includes the steps of: producing microcapsules by means of injection into a microsystem (10) of three fluids (f1, f2, f3); deforming the microcapsules by means generating a flow within a capillary tube (20); observing and acquiring the outline of at least one deformed microcapsule observed by an optical acquisition means (30); comparing the acquired outline with outlines from a collection of reference microcapsule outlines; determining the diameter and said at least one parameter characteristic of the mechanical properties of the observed microcapsule; and modifying the flow rates (Q1, Q2, and/or Q3) of the fluids (f1, f2, f3). The present invention also relates to a system for producing calibrated microcapsules. |