A non-woven fiber mat for lead-acid batteries is provided. The non-woven fiber mat includes glass fibers coated with a sizing composition, a binder composition, and organic active compounds, wherein the organic active compounds are effective in reducing or preventing sulphation in lead-acid batteries.

The invention relates to a method of fabricating a conductive fabric by vapor phase polymerization, a multi-pressure sensor for a fiber type, and a multi-pressure measuring method employing the multi-pressure sensor. The method of fabricating a conductive fabric by vapor phase polymerization provides a conductive fabric having a resistance value which changes depending on pressure applied by a user. The multi-pressure measuring method employing the multi-pressure sensor has high resistance to moisture and repeated loading, is manufactured with lower costs than existing pressure sensors, is capable of measuring both dynamic and static pressures using a principle of a piezo-resistive sensor, has a simple circuit configuration, and is strong against a high-frequency disturbance.

A launderable bactericidal and virucidal fabric finish formulation. The first component is a bactericidal and virucidal agent represented by formula (I):

##STR00001## wherein n is 7; R.sub.1, R.sub.2, and R.sub.3 are jointly or independently selected from H or one of the following groups:

##STR00002## wherein R.sub.4 is selected from CH.sub.3 or H; m is an integer from 2 to 10; p is an integer from 9 to 15; q is an integer from 2 to 10. A second component includes one or more crosslinkers and/or one or more catalysts. A third component includes one or more transition metal salts.

The present invention relates to a surfactant composition capable of making a dimethylsiloxane highly remain the solid surface, which is a surfactant composition containing an anionic surfactant (A), a cationic surfactant (B), and a dimethylpolysiloxane (C), wherein the following molar ratio R.sub.A is 0.10 to 0.90; and the following molar ratio R.sub.b is 0.4 or more: R.sub.A: a molar ratio {(A)/[(A)+(B)]} of the amount of the anionic surfactant (A) to the total amount of the anionic surfactant (A) and the cationic surfactant (B) R.sub.b: a molar ratio {[(a1)+(b1)]/[(A)+(B)]} of the total amount of a branched-type anionic surfactant (a1) and a branched-type cationic surfactant (b1) to the total amount of the anionic surfactant (A) and the cationic surfactant (B).

The present invention relates to a surfactant composition capable of making a dimethylsiloxane highly remain the solid surface, which is a surfactant composition containing an anionic surfactant (A), a cationic surfactant (B), and a dimethylpolysiloxane (C), wherein the following molar ratio R.sub.A is 0.10 to 0.90; and the following molar ratio R.sub.b is 0.4 or more: R.sub.A: a molar ratio {(A)/[(A)+(B)]} of the amount of the anionic surfactant (A) to the total amount of the anionic surfactant (A) and the cationic surfactant (B) R.sub.b: a molar ratio {[(a1)+(b1)]/[(A)+(B)]} of the total amount of a branched-type anionic surfactant (a1) and a branched-type cationic surfactant (b1) to the total amount of the anionic surfactant (A) and the cationic surfactant (B).

The present invention relates to a surfactant composition capable of making a liquid oil highly remain on the solid surface, which is a surfactant composition containing an anionic surfactant (A), a cationic surfactant (B), a liquid oil (C), and water, wherein the water constitutes a continuous phase; the following molar ratio R.sub.A is 0.25 or more and 0.60 or less; and the following molar ratio R.sub.b is 0.6 or more: R.sub.A: a molar ratio {(A)/[(A)+(B)]} of the amount of the anionic surfactant (A) to the total amount of the anionic surfactant (A) and the cationic surfactant (B) R.sub.b: a molar ratio {[(a1)+(b1)]/[(A)+(B)]} of the total amount of a branched-type anionic surfactant (a1) and a branched-type cationic surfactant (b1) to the total amount of the anionic surfactant (A) and the cationic surfactant (B).

The present invention relates to a surfactant composition capable of making a liquid oil highly remain on the solid surface, which is a surfactant composition containing an anionic surfactant (A), a cationic surfactant (B), a liquid oil (C), and water, wherein the water constitutes a continuous phase; the following molar ratio R.sub.A is 0.25 or more and 0.60 or less; and the following molar ratio R.sub.b is 0.6 or more: R.sub.A: a molar ratio {(A)/[(A)+(B)]} of the amount of the anionic surfactant (A) to the total amount of the anionic surfactant (A) and the cationic surfactant (B) R.sub.b: a molar ratio {[(a1)+(b1)]/[(A)+(B)]} of the total amount of a branched-type anionic surfactant (a1) and a branched-type cationic surfactant (b1) to the total amount of the anionic surfactant (A) and the cationic surfactant (B).

The present invention relates to safety gloves with special rubber coating. Specifically, a kind of safety gloves with rubber coating which is specially designed and coated on fabric substrates to achieve proper hand protection effects, and exhibits properties such as good ventilation, abrasion resistance, and soft and comfortable wearing experience. A preparation method of safety gloves with special coating, comprising following steps: (1) treating a substrate with composite electrolyte digestion solution by a certain method; (2) spreading polymeric disperse coating over the substrate containing composite electrolyte digestion solution obtained in step (1), heating when the polymeric disperse coating is attached and obtaining a half-product with polymeric disperse coating; (3) treating the half-product with polymeric disperse coating in pre-foamed water chemical compound or non-foamed water chemical compound, by treating immersing or spraying or immersing and spraying is defined; and (4) dipping the product treated in step (3) in aromatic hydrocarbon solution.

The present invention relates to safety gloves with special rubber coating. Specifically, a kind of safety gloves with rubber coating which is specially designed and coated on fabric substrates to achieve proper hand protection effects, and exhibits properties such as good ventilation, abrasion resistance, and soft and comfortable wearing experience. A preparation method of safety gloves with special coating, comprising following steps: (1) treating a substrate with composite electrolyte digestion solution by a certain method; (2) spreading polymeric disperse coating over the substrate containing composite electrolyte digestion solution obtained in step (1), heating when the polymeric disperse coating is attached and obtaining a half-product with polymeric disperse coating; (3) treating the half-product with polymeric disperse coating in pre-foamed water chemical compound or non-foamed water chemical compound, by treating immersing or spraying or immersing and spraying is defined; and (4) dipping the product treated in step (3) in aromatic hydrocarbon solution.

A process of making a textile material antimicrobial includes a first process cycle including treating the textile material using a liquor application process that includes one or more antimicrobial agents, and subjecting the treated textile material to a heat treatment. The process also includes a second process cycle being performed after the first process cycle and including treating the textile material using a liquor application process that includes one or more antimicrobial agents, and drying the textile material to evaporate water in the textile material and curing the treated textile material after the water in the textile material has been evaporated by the drying.