Dipping composite material for enhancing cut resistance of chemical-resistant gloves

Abstract

Disclosed is a dipping composite material for enhancing the cut resistance of chemical-resistant gloves, wherein an additive is added to a latex, and the additive is a metal oxide and/or silica and/or glass fiber and/or basalt fiber and/or aramid fiber. The present invention improves the formula of a dipping layer such that the dipping layer has the cut resistance, which can significantly improve the cut resistant level of gloves.

Claims

1. A dipping composite material for enhancing the cut resistance of chemical-resistant gloves, wherein an additive is added to a latex, and the dipping composite material is made of the additive and the latex, the additive is composed of titanium dioxide, silica, and glass fiber, and the mass ratio of titanium dioxide, silica, and glass fiber is 1:1:1, wherein the latex is nitrile rubber, neoprene or polyurea.

2. The dipping composite material for enhancing the cut resistance of chemical-resistant gloves according to claim 1, wherein the titanium dioxide is in a form of whisker or powder.

3. The dipping composite material for enhancing the cut resistance of gloves according to claim 1, wherein the glass fiber is staple fiber or pulp.

4. The dipping composite material for enhancing the cut resistance of chemical-resistant gloves according to claim 1, wherein the mass ratio of the additive to the latex is 1-6:10.

5. A dipping composite material for enhancing the cut resistance of chemical-resistant gloves, wherein an additive is added to a latex, and the dipping composite material is made of the additive and the latex, the additive is composed of basalt fiber and glass fiber, and the mass ratio of basalt fiber and glass fiber is 1:1, wherein the latex is nitrile rubber, neoprene or polyurea.

Description

DETAILED DESCRIPTION OF THE INVENTION

Example 1

(1) A dipping composite material for enhancing the cut resistance of chemical-resistant gloves, wherein a dipping composite was prepared by adding 0.5 Kg of titanium dioxide fine powder and 0.5 Kg of silica fine powder to 10 Kg of a neoprene rubber compound and stirring uniformly. An ordinary glove core without cut resistance was used. A glove was produced by dipping according to the existing dipping process.

Example 2

(2) A dipping composite was prepared by adding 1 Kg of silica fine powder to 10 Kg of a neoprene rubber compound and stirring uniformly. A glove core and a dipping process were the same as in Example 1.

Example 3

(3) A dipping composite was prepared by adding 1 Kg of silica fine powder and 1 Kg of glass staple fiber to 10 Kg of a neoprene rubber compound and stirring uniformly. A glove core and a dipping process were the same as in Example 1.

Example 4

(4) A dipping composite was prepared by adding 1 Kg of silica fine powder and 1 Kg of glass staple fiber to 10 Kg of a neoprene rubber compound and stirring uniformly. A glove core and a dipping process were the same as in Example 1.

Example 5

(5) A dipping composite was prepared by adding 1 Kg of titanium dioxide fine powder, 1 Kg of silica fine powder and 1 Kg of glass staple fiber to 10 Kg of a neoprene rubber compound and stirring uniformly. A glove core and a dipping process were the same as in Example 1.

Example 6

(6) A dipping composite was prepared by adding 1 Kg of basalt fiber staple fiber and 1 Kg of glass staple fiber to 10 Kg of a nitrile compound and stirring uniformly. A glove core and a dipping process were the same as in Example 1.

Example 7

(7) A dipping composite was prepared by adding 2 Kg of glass staple fiber to 10 Kg of a nitrile compound and stirring uniformly. A glove core and a dipping process were the same as in Example 1.

Example 8

(8) A dipping composite was prepared by adding 1 Kg of magnesium oxide, 1 Kg of calcium oxide, and 1 Kg of aramid fiber pulp to 10 Kg of a nitrile compound and stirring uniformly. A glove core and a dipping process were the same as in Example 1.

Example 9

(9) A dipping composite was prepared by adding 1 Kg of silica and 1 Kg of calcium oxide to 10 Kg of a polyurea material and stirring uniformly. A glove core and a dipping process were the same as in Example 1.

Example 10

(10) A dipping composite was prepared by adding 1 Kg of silica and 1 Kg of basalt taple fiber to 10 Kg of a polyurea material and stirring uniformly. A glove core and a dipping process were the same as in Example 1.

Comparative Example 1

(11) A dipping composite was only composed of a neoprene rubber compound, a glove core was identical to that in Example 1, and a glove was produced by the same dipping process.

Comparative Example 2

(12) A dipping composite was only composed of a nitrile compound, a glove core was identical to that in Example 1, and a glove was produced by the same dipping process.

Comparative Example 3

(13) A dipping composite was only composed of a polyurea compound, a glove core was identical to that in Example 1, and a glove was produced by the same dipping process.

(14) The dipping layers of the gloves prepared in Examples 1-10 and Comparative Examples 1-3 described above had the same thickness. The cut resistant level and fire resistance of the gloves in the above 13 groups were tested, and the resulting data are as follows:

(15) TABLE-US-00001 Thickness of Glove core Cut resistance Serial no. dipping layer specifications (ASTM) Example 1 0.3 mm 15-pin nylon glove core A1 Example 2 0.3 mm 15-pin nylon glove core A1 Example 3 0.5 mm 15-pin nylon glove core A2 Example 4 0.5 mm 15-pin nylon glove core A2 Example 5 0.6 mm 15-pin nylon glove core A3 Example 6 0.6 mm 15-pin nylon glove core A4 Example 7 0.3 mm 15-pin nylon glove core A2 Example 3 0.6 mm 15-pin nylon glove core A2 Example 9 0.6 mm 15-pin nylon glove core A2 Example 10 0.5 mm 15-pin nylon glove core A2 Comparative 0.3 mm 15-pin nylon glove core A0 example 1 Comparative 0.3 mm 15-pin nylon glove core A0 example 2 Comparative 0.3 mm 15-pin nylon glove core A0 example 3