JPH0327642B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a method for manufacturing dust-free gloves.

PRIOR ART Gloves made of vinyl chloride resin have long been known as household gloves for cooking, laundry, etc., but recently they have become known as work gloves in the precision industry.

Gloves made of vinyl chloride resin contain a large amount of plasticizer to give them flexibility, and as a result, the surface of the gloves is highly sticky and does not slip easily. It is difficult to release the mold from the hand mold because they stick together, and the ease of attaching and removing the mold from the hand during use is also extremely poor, making it extremely difficult to use. Therefore, the inner surface of the gloves is flocked with vile or powdered with calcium carbonate, magnesium carbonate, mica powder, etc., but when used as work gloves in the clean rooms of integrated circuit factories and biotechnology-related factories. is not suitable for use because the flocked fibers and powdered powder cause dust.

For this reason, there is a demand for work gloves for use in clean rooms that do not generate dust and are easy to put on and take off, and a glove disclosed in Japanese Patent Application Laid-open No. 119204/1983 has been proposed. The method for manufacturing dust-free gloves disclosed in the publication involves immersing a metal or ceramic hand mold in vinyl chloride resin sol, pulling it up, and heating it.
The vinyl chloride resin sol attached to the hand mold is turned into a gel,
This is immersed in a synthetic resin emulsion containing 0.1 to 8% by weight of finely divided silica that is uniformly dispersed.
It is attached to the outer periphery of the gelled vinyl chloride resin layer and heated again to melt the vinyl chloride resin, and at the same time, a synthetic resin emulsion that adheres to the outside is formed into a film to be integrated with the vinyl chloride resin layer and to contain it. This is a method of manufacturing dust-free gloves by fixing fine silica particles, cooling, and then inverting and removing the mold.

Problems to be Solved by the Invention In the manufacturing method shown in the above-mentioned Japanese Patent Application Laid-open No. 60-119204, even if fine silica is used, it is impossible to disperse it with a primary particle size, and in reality, it is impossible to disperse it with a primary particle size. It will be dispersed in micron units (1 to 5 μ) in diameter. Therefore, if an extremely thin silica-dispersed synthetic resin layer is formed on a vinyl chloride resin layer, the silica particles will protrude onto the synthetic resin layer, and if used for a long time, the silica protrusions will be scraped off. There was a problem that it caused dust to be generated.

The present invention solves these problems,
The object of the present invention is to provide a glove that is easy to release from the hand mold during manufacturing, is easy to put on and take off from the hand, and does not generate dust.

Means for Solving the Problem In order to solve this problem, the present invention immerses a metal or ceramic hand mold in a vinyl chloride resin sol, pulls it up, heats it, and removes the vinyl chloride attached to the hand mold. The resin sol is gelled, and this is immersed in a mixed emulsion solution, which is a mixture of a synthetic resin emulsion that has adhesive properties to vinyl chloride resin and a resin with high hardness such as methmethyl acrylate resin in an emulsion state. The mixed emulsion liquid is applied to the outer surface of the resin layer, and after being pulled up, it is heated again to melt the vinyl chloride resin. At the same time, the mixed emulsion liquid that adheres to the outer surface is formed into a film, and an integral sliding layer is formed on the outer surface of the vinyl chloride resin layer. After cooling, the layer is inverted and released from the mold.

Effect With this configuration, the inner surface of the glove made is coated with a slippery layer formed from a mixed emulsion liquid containing a highly hard resin.
It is easy to put on and take off during use, making it convenient to use, and since there are no deposits that fly off during use, there is no generation of dust. Moreover, when the glove is inverted and released from the hand mold, the slippery layer made of the mixed emulsion liquid is located on the front side, so the surfaces do not come into close contact with each other and are easily released from the hand mold. .

Example An embodiment of the present invention will be described below.

First, a metal or ceramic hand mold is mixed with plasticizers, stabilizers, pigments, gelling agents, diluents, fillers, etc. commonly used in vinyl chloride paste resin. The hand mold is immersed in vinyl resin sol, a thin film layer of vinyl chloride resin sol is attached to the hand mold, and then pulled up.The hand mold with a thin film layer of vinyl chloride resin sol adhered to the outer surface is rotated in a heating furnace at approximately 250°C. The thin film layer is gelled by heating for 1 minute. Next, a highly hard resin such as methmethyl acrylate resin is added to the emulsion of a synthetic resin such as vinyl chloride resin, acrylic ester resin, or vinyl chloride resin-acrylic ester copolymer resin, which has adhesive properties to vinyl chloride resin. The hand mold having the gelled thin film layer formed on the outer surface is immersed in the mixed emulsion solution prepared by mixing the mixed emulsion solution on the outer surface of the thin film layer. The highly hard resin used in this mixed emulsion liquid has a particle size of 0.05 μm to 0.5 μm. The mixing ratio of the resins in the mixed emulsion liquid is set as follows in order to satisfy the lubricity of the coating layer formed by the emulsion liquid and the adhesion to the vinyl chloride resin thin film layer. In other words, the ratio of resin for adhesion (A) [adhesive resin] and resin for slipperiness (B) [resin such as methmethyl acrylate resin] is (A):(B)=
You can choose as appropriate in the range of 30-60:70-40. Then, a surfactant, a thickener, an antifoaming agent, water, etc. are added to this mixed emulsion liquid as necessary, and the concentration and viscosity of this aqueous dispersion are adjusted so that a thin coating layer can be formed. That is, the concentration of the mixed resin relative to water is adjusted to about 3% to 15%, and the viscosity is adjusted to about 150 centipoise. A thin film layer of the mixed emulsion is attached to the outer surface of the thin film layer on the outer surface of the hand mold pulled up from the mixed emulsion liquid, and the thin film layer of the mixed emulsion is melted by heating again to melt the thin film layer of the vinyl chloride resin. is formed into a film and integrated with a thin film layer of vinyl chloride resin. As a result, a slippery thin film layer made of mixed emulsion is integrally formed on the outside of the vinyl chloride resin thin film layer, and after cooling, the glove with both the thin film layers integrated is formed. Invert and release from the hand mold. This completes the production of the glove, and the slippery thin film layer is located on the inner surface.

By the way, the particle size of the resin with high hardness such as methmethyl acrylate resin used as the material of the mixed emulsion liquid is 0.05μ~ as mentioned above.
0.5μ, and the particles are dispersed in the mixed emulsion liquid. Therefore, when the mixed emulsion liquid is thinly coated on the vinyl chloride resin thin film layer, the particles of the hard resin in the thin film layer made of the mixed emulsion integrated with the vinyl chloride thin film layer are mixed with the thin film layer of vinyl chloride resin. It is uniformly dispersed without protruding from the thin film layer made of emulsion. As a result, the thin film layer made of the mixed emulsion has lubricity and is easily attached to and removed from the hand during use. Moreover, since the high hardness resin is uniformly dispersed without protruding, it will not be scraped off even if used for a long time. In addition, since the thin film layer made of mixed emulsion uses a synthetic resin emulsion that has adhesive properties to vinyl chloride resin as an adhesive, this thin film layer itself may peel off from the thin film layer of vinyl chloride resin. There is no. Gloves made in this way can be easily released from the hand mold without causing the surfaces to come into close contact with each other, do not generate dust during use, and are easy to put on and take off from the hand.

Effects of the Invention As described above, according to the present invention, the following effects can be obtained.

That is, the inner surface of the glove made by the method of the present invention has a slippery layer formed from a mixed emulsion liquid containing a highly hard resin, making it easy to put on and take off during use. It is easy to use and does not generate dust as there is no deposit that scatters during use. Moreover, when the glove is inverted and released from the hand mold, the slippery layer made of the mixed emulsion liquid is located on the front side, so the surfaces do not come into close contact with each other and are easily released from the hand mold. .

Claims (1)

[Claims] 1. A metal or ceramic hand mold is immersed in vinyl chloride resin sol, pulled up, heated, and the vinyl chloride resin sol adhering to the hand mold is gelled. The resin emulsion is immersed in a mixed emulsion solution in which a highly hard resin such as metamethyl acrylate resin is mixed in the form of an emulsion to adhere the mixed emulsion solution to the outer surface of the gelled vinyl chloride resin layer, then pulled out and heated again. The method is characterized by melting the vinyl chloride resin and simultaneously forming a mixed emulsion that adheres to the outer surface to form an integral slippery layer on the outside of the vinyl chloride resin layer, and then inverting and releasing the mold after cooling. Method of manufacturing dust-free gloves.