JPH01292106A - Production of vibration-insulating gloves - Google Patents

Abstract

PURPOSE:To obtain a vibration-insulating gloves usable over a long period, by laminating a piece of unfoamed raw rubber and a raw rubber sheet for surface to the main body of cloth gloves, bonding the sheets under pressure, putting the laminate on a steric mold, foaming with heat and bonding the foamed rubber piece to the cloth. CONSTITUTION:A main body 2 of cloth gloves is placed on a flat mold 10 and a rubber paste layer 3b is formed on the main body with a rubber paste liquid. Unfoamed raw rubber pieces 4a are applied through the rubber paste layer 3b to the palm-side of the main body 2 excluding the joint parts in such a manner as to increase the foaming ratio from the finger tip to the palm. A raw rubber sheet 5a for surface is laminated to the main body 2 of the gloves, and the raw rubber sheet 5a and the unfoamed raw rubber pieces 4a are bonded under pressure using an upper mold 11 made of a sponge rubber. The objective vibration-insulating gloves is produced by putting the main body 2 of the cloth gloves on a steric mold and heating the body to effect the foaming and vulcanization of the unfoamed raw rubber pieces 4a and the vulcanization of the raw rubber sheet 5a for surface.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to a method of manufacturing a vibration-isolating work glove in which a foam rubber piece is arranged on the palm side of the outer surface of the fabric glove body.

[Prior art] Work gloves for holding vibrating rock drills, etc. are made by gluing a piece of vulcanized foam rubber to the outer surface of the palm side of the fabric glove body, and then applying an unvulcanized rubber seal to the outside. Anti-vibration gloves were manufactured by attaching the material with adhesive and then vulcanizing it.

[Problems to be Solved by the Invention] Vulcanized foamed rubber pieces cannot obtain strong adhesion ability to fabrics, tend to peel off during wear, and have a short lifespan as a product. In addition, two types of vulcanization work are required: one to make vulcanized foam rubber pieces, and the other to vulcanize the unvulcanized rubber sheet I-, which has vulcanized foam rubber pieces arranged and pasted on the outside of the fabric glove body. This resulted in poor work efficiency and high costs.

The present invention aims to provide an inexpensive anti-vibration glove in which a piece of foam rubber that has a strong adhesive force and is difficult to peel off is fixed to fabric.

[Means to solve the problem] This will be explained with reference to the drawings.

The method for manufacturing anti-vibration gloves according to the present invention is to cover a flat plate mold 10 with a fabric glove body 2, apply rubber glue liquid 3 to the outer surface of the glove body 2, and apply rubber glue JW3b.
, and glue a piece of unfoamed raw rubber 4a with different foaming ratios depending on the part on the palm side of the glove body 2, excluding the joint part 2a, with rubber glue Ji53b.
A surface rubber sheet 5a is placed on the glove body 2 so as to cover the unfoamed raw rubber piece 4a, and the raw rubber sheet 5a and the unfoamed raw rubber piece 4a are pressurized by the sponge rubber upper mold 11. Adhesive, then flat plate mold 10
The cloth glove main body 2 is cut out from the outside, placed on a three-dimensional mold 14, heated to foam and vulcanize the unfoamed raw rubber piece 4a, and also vulcanize the surface raw rubber sheet 5a.

[Function] The gloves made by the method of the present invention are worn on the hands, such as when going to school, and are used to operate vibrating equipment.

[Example J As shown in FIGS. 2 to 4, a flat mold 1o was
Cover the gloves with the cloth glove body 2, such as a cloth glove.

As shown in FIG. 5, the glove body 2 is immersed in a rubber glue solution 3a and pulled up to form a rubber glue layer 3b on the outer surface of the glove body 2.

As shown in FIGS. 6 and 7, there is an unfoamed area on the palm side of the glove body 2, excluding the joints 2a, where the foaming ratio is small on the fingertip side and increases as the foaming ratio approaches the palm. A raw rubber piece 4a is adhered via a rubber glue layer 3b.

As shown in FIGS. 8 and 9, a top raw rubber sheet 5a is placed on the glove body 2 so as to cover the unfoamed raw rubber piece 4a.

As shown in Figure ffllO, the raw rubber sheet is pressed and adhered using a sponge rubber upper mold 11.

As shown in FIG. 11, from the flat plate mold 10, the fabric glove body 2 is
pull out.

As shown in FIG. 12, the glove body 1 is placed over the three-dimensional mold 14.

As shown in FIG. 12, the unfoamed raw rubber piece 4a of the glove body 2 placed on the three-dimensional mold 14 is foamed and vulcanized by the heating vulcanizer 12 to form a waste foamed rubber piece 4b, and the raw rubber sheet 5a for the surface is also heated and vulcanized. It was sulfurized to form a surface rubber sheet 5b.

[Effects of the Invention] In the anti-vibration glove according to the present invention, an unfoamed raw rubber piece 4a and a surface raw rubber sheet 5a (IJ<m) are laid on the fabric glove body 2, and the upper die 11 made of sponge material is used to apply pressure and adhesive. At this time, pieces of raw rubber 4a mixed with a foaming agent have penetrated into the threads of the fabric 2. Therefore, when the foamed rubber piece 4b is placed on the three-dimensional mold 14 and heated for foaming and vulcanization, the foamed rubber piece 4b and the fabric 2 are sufficiently connected and bonded.

Therefore, the fabric 2 and the foamed rubber piece 4b do not peel off while the glove is being worn, and can be used for a long period of time.

Furthermore, since the vulcanization process only needs to be done once, it is easier and cheaper to manufacture than conventional products that use vulcanized and foamed rubber pieces.

[Brief explanation of the drawing]

The drawings are for explaining one embodiment of the present invention. Fig. 1 is a cutaway side view of the product, Fig. 2 is a plan view of the flat plate mold and the glove body, and Fig. 3 is a plan view of the glove body on the flat plate mold. A plan view of the glove with the main body covered, Figure 4' is a sectional view taken along N-IV in Figure 3, Figure 5 is a front view when applying rubber glue to the glove body, and Figure 6 is a foam rubber piece adhered. The top view of the glove body, Figure 7 is
Figure 8 is a plan view of the glove body with the raw rubber sheet covered over the foam rubber piece, Figure 9 is a cross-sectional view taken along line IX-IX in Figure 8, and Figure 10 is the raw rubber sheet covered with the raw rubber sheet. Figure 11 is a side view of the covered glove body being crimped with a press, Figure 11 is a side view of the glove body removed from the flat mold after press crimping, and Figure 12 is a side view of the glove body being pressed and pressed onto the three-dimensional mold. FIG. 2 (Fabric) Glove body 2a Joint part 3a Rubber glue liquid 3b Rubber glue layer 4a Unfoamed raw rubber piece 4b Foamed rubber piece 5a Raw rubber sheet 5b Surface rubber sheet 11 Sponge material upper mold 12 Heat vulcanizer 13 Lower mold 14 Three-dimensional metal mold

Claims (1)

[Claims] A fabric glove body (2) is placed on a flat plate mold (10), and a rubber glue layer (3a) is applied to the outer surface of the glove body (2).
3b), and adhere unfoamed raw rubber pieces (4a) with different foaming ratios depending on the part to the palm side of the glove body (2), excluding the joints (2a), via a rubber glue layer (3b). and the unfoamed raw rubber pieces (4
A raw rubber sheet for the surface (5a) is attached to the glove body (2) that covers
), the raw rubber sheet (5a) and the unfoamed raw rubber piece (4a) are pressure-adhered using the sponge rubber upper mold (11), and then the fabric glove body (2) is placed from the flat mold (10).
A method for manufacturing anti-vibration gloves, which comprises removing the unfoamed raw rubber sheet, placing it on a three-dimensional mold (14), and heating it to foam and vulcanize the unfoamed raw rubber piece (4a), as well as vulcanize the surface raw rubber sheet (5a). .