JPS623727A - Production of pearl - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an improved method for producing pearls and the pearls produced therefrom.

Shell-adhered pearl
) can be made into crafts and ornaments. A known production method for this shell-bound pearl involves inserting a nucleus-model into a mantle (
The nacre is inserted between the mantle (mantle) and the shell, and during culturing, the nacre secreted from the mantle gradually envelops the nuclide model, and when the nacre reaches a certain thickness, a shell-adhesive pearl is formed. be. The feature of this method is the nacre layer surrounding the nuclide model, and as a result, the nacre surface that adheres closely to the mantle constitutes the product surface. Since the nuclide model does not adhere firmly to the mantle, cracks often occur between the nuclide model and the nacre layer. Furthermore, when the nacre layer becomes thicker and secretion becomes uneven, a discrepancy occurs between the shape of the nacre surface and the carefully selected nuclide model shape.

This is especially the case with pattern pearls, where the pattern surface may become obscured or even disappear. The longer the culture period is, the thicker the Y-shaped difference between the nacre layer and the nuclide model becomes. Until now, no ideal solution to the above problem has been found. Recent shell-adhered pearls are hemispherical pearls. In addition, shell-adhesive pattern pearls have a screen structure.Due to quality and marketability issues, production is currently limited to small-scale or experimental production.In this case, the manufacturing method is "Shimizu". Zhang Yu, described in his book ``How to cultivate pearl oysters in China.''
It is based on the method of An-pei (1981).

The purpose of this invention is to develop a new technology for pearl production.

With this technology, pearls can be produced as designed, and
A normal or better pearlescent luster and shape are obtained.

The object of this invention can be achieved by inserting a pre-designed nuclide model between the mantle and shell of a pearl oyster. The shape of the nuclide model may be either concave or convex, and the material may be plastic, metal, or other plastic material. During the culturing period, shell-bound pearls are formed on this inserted nuclide model, and then a sharp tool or other special tool is used to separate the shell-bound pearls from the shell and nuclide model to obtain free pearl tissue pieces. It will be done. Therefore, if a surface that is in close contact with the nuclide model is selected as the product surface, the product surface and the nuclide model surface will match.

If the inserted nuclide model is concave, the resulting pearl surface (closely attached to the nuclide model) will be convex, and vice versa.

When a picture or pattern is engraved on the uneven nuclide model, the resulting pearl surface will have a convex or concave picture pattern. Grinding or cutting operations are performed to remove the worthless parts of the separated pearl tissue pieces;
Immerse the remainder in dilute acid (e.g. dilute hydrochloric acid), wash in ammonia and water, rub gently with a soft cotton cloth, and rub it on the surface (
When the thin and loose organic layer on the surface that is in close contact with the nuclide model is removed, pearlescent luster appears. Note that polishing treatment should increase the -m gloss. In order to meet various demands, the operation of the thus treated pearl) 41 woven pieces can be repeated. For example, it can be inlaid with metal or bonded to aggregated pearls as described below.

The feature of this invention is that pearls are manufactured by filling a model with stuffing, and furthermore, a special treatment is used to create a pearl surface that adheres to the nuclide model on the product surface. Since these two sides match, the shape, form, and surface pattern of the pearl match the shape, form, and surface pattern of the designed model. Therefore, the present invention is suitable for obtaining very elaborately patterned pearls such as dorabon, phoenix, and portrait pearls, and also requires various predetermined adjustment operations, such as correctly joining two sets of pearl tissue pieces to obtain accumulated pearls. This method is also suitable for

In addition, since the calcium carbonate pellet and thin layer of organic matter on the surface of the pearl tissue piece that is in close contact with the nuclide model are removed, its transparency increases, and this results in migration staining (trans-staining).
This method is also suitable for obtaining colorful pearls using the dyeing technique. The reason for this is that a relatively large nuclide model can be inserted as a result of pearls, and
This is because the surface area and thickness of the resulting pearls can both be increased compared to normal levels. In addition, since the quality of the pearl substance is affected by the initial secretion after nuclide insertion, it is extremely convenient to artificially change and control the secretion function of the pearl oyster to improve the quality of the pearl. That's why.

Claims (6)

[Claims] (1) a. Insert a nuclide model, which may or may not have a carved pattern on its surface, and serve as a pattern plate on the product surface, between the mantle and the shell; b. Place the nuclide surface in close contact with the nuclide model on the product surface. A pearl production method characterized by: (2) The method according to claim 1, wherein the inserted nuclide model has a concave shape, and a convex pearl surface that is in close contact with the nuclide model constitutes the product surface. (3) The inserted concave nuclide model is engraved with a pattern, the pattern is concave or convex, and the pattern obtained on the product surface is convex or concave.
The method described in section. (4) A pearl produced by the method described in claims 1 to 3, characterized in that the product surface is composed of a nacre layer in close contact with the nuclide model. (5) A pearl produced by the method according to claims 1 to 3, characterized in that it consists of two sets of pearl tissue pieces that are precisely joined. (6) The pearl according to claim 4 or 5, characterized in that a pattern is formed on the surface of the product pearl.