JP3108959U - Bra metal parts - Google Patents

Abstract

【Task】
Maintains performance such as shape retention, moderate deformation, elasticity, washing resistance (fatigue resistance), corrosion resistance, etc. required as a wire or wire used in bust cups for women's clothing such as brassiere, The present invention provides a metal part for a brassiere that has antibacterial and deodorizing properties and has characteristics such as promoting blood circulation and relieving fatigue.
[Solution]
It is a wire or wire used for the lower peripheral part of the bust cup of the clothing for women, Comprising: It has Ge-containing metal coating layer containing 1 to 80 weight% of Ge on the base metal surface.
[Selection] Figure 1

Description

  The present invention retains the performance required as a bust cup wire or wire material for women's clothing such as brassiere, has antibacterial and deodorizing properties, and has characteristics such as promoting blood circulation and reducing fatigue. It relates to metal parts for brassiere.

  Wire or wire as a core material for shape retention used in the lower peripheral edge of bust cups for women's clothing such as brassiere, brassiere, body suit, leotard, swimsuit (hereinafter referred to as brassiere) is mainly metal material For example, a material obtained by punching a spring steel plate, a stainless steel plate or the like into a horseshoe shape (for example, Patent Document 1), a shape obtained by curving a thin line shape of a spring steel or the like into an arc shape (for example, a patent Document 2), those using titanium or a titanium alloy (for example, Patent Document 3), those using a shape memory alloy material, and others made of synthetic resin (for example, Patent Document 4) are used. It has been.

Japanese Patent Laid-Open No. 9-105003 JP 2003-328210 A JP 2001-214307 A JP 2001-131806 A

  The present invention is a shape-retaining property, moderate deformability, elasticity, washing resistance (fatigue resistance), and corrosion resistance required as a wire or wire used in the lower peripheral portion of a bust cup of a female clothing such as a brassiere. It is intended to provide a metal part for a brassiere that has the characteristics such as maintaining the performance such as antibacterial property and deodorizing property, promoting blood circulation and relieving fatigue.

  That is, the present invention is (1) a wire or wire used for a lower peripheral portion of a bust cup for women's clothing, wherein a Ge-containing metal coating layer containing 1 to 80% by weight of Ge on a base metal surface is provided. (2) The metal part for brassiere according to (1) above, wherein the Ge-containing metal film layer is partially provided, and (3) the Ge-containing metal film A metal part for a brassiere according to the above (1) or (2), further comprising a metal film layer on the layer, and (4) a resin film layer further on the Ge-containing metal film layer The metal part for brassiere according to any one of the above (1) or (2), characterized in that (5) the Ge-containing metal coating layer is a coating formed by plating with a Ge / metal alloy plating solution. To the (1) to brassieres for metal parts according to any one of (4), and the gist.

  Since the metal parts for brassiere according to the present invention have a Ge-containing metal coating layer on the surface of the base metal, the shape retention required for wires or wires used in bust cups for women's clothing such as brassieres. Maintains the performance of moderate deformation, elasticity, washing resistance (fatigue resistance), corrosion resistance, etc., does not induce allergies to the skin, etc. Therefore, it is possible to provide a brassiere and the like that has a special antibacterial and deodorizing properties, promotes blood circulation, has a special effect of relieving fatigue, such as relieving muscle punishment and pain, and the like.

The present invention relates to a wire or wire used for a lower peripheral portion of a bust cup of a female clothing, and relates to a metal part such as a brassiere having a Ge-containing metal coating layer on a base metal surface.
Here, in this specification, the bust cup covers and protects the bust (breast) in women's clothing such as brassiere, brassiere, body suit, leotard, and swimsuit (hereinafter referred to as a brassiere). A cup-shaped part that keeps the shape.

The base metal of the metal parts for brassiere in the present invention is a metal conventionally used for a wire or a wire used for a lower peripheral portion of a bust cup for women's clothing. For example, iron (steel), stainless steel, brass Of these, metals such as titanium and titanium alloys are preferable. Among them, titanium and titanium alloys are preferable as metals that are light and have good corrosion resistance.
The shape may be any shape conventionally used for so-called bust cups, such as a round bar shape, a flat shape, a flat plate shape, or a horseshoe shape obtained by punching a steel plate or a stainless steel plate.

In the metal part for brassiere of the present invention, the Ge-containing metal film can be obtained by subjecting the surface of a base metal used for a bust cup wire such as a brassiere or wire to a metal plating treatment using the following plating solution.
In other words, soluble metal compounds such as nickel, cobalt, rhodium, ruthenium, platinum, and gold are dissolved in metal in a stable conductive salt solution adjusted to pH 7.0 or lower and kept acidic to a concentration of 0.5 to 20 g / L. And by using a germanium / metal alloy plating solution in which a soluble germanium compound is dissolved as a Ge metal at a concentration of 1 to 20 g / L, it is used for wires and wires such as brassieres having a Ge-containing metal coating layer. Metal parts are obtained.

The method for forming the Ge-containing metal coating layer on the base metal may be any conventional method as long as a coating layer with good adhesion strength is formed, and the electroplating method, ie, electrolytic plating is uniform. Therefore, it is generally used because a conventional plating film can be easily obtained and a conventional apparatus can be applied as it is. When performing Ge-containing metal plating on the base metal, pretreatment such as buffing, blasting, and polishing is performed on the surface of the base metal in the same manner as in general plating, and metal alloy plating is performed with a Ge / metal alloy plating solution. In the case of base metal base materials such as titanium, stainless steel, brass, etc., in addition to the pretreatment such as buffing, blasting, polishing, etc., base plating such as bright nickel plating or gold plating is performed, and the Ge / metal alloy plating solution is used in the same manner as above. It is preferable to perform metal alloy plating.
The Ge-containing metal coating layer is usually formed on the entire surface of the base metal, but the Ge-containing metal coating layer can be partially formed as desired. Moreover, a metal plating layer such as gold or a resin coating layer can be further formed on the Ge-containing metal coating layer.

  In the present invention, the thickness of the Ge-containing metal coating is preferably 0.1 to 5 μm, and if it is 0.1 μm or less, it is difficult to obtain an effect due to Ge metal. Although there is a difficulty in terms, the thickness of the plating film can be a film having an appropriate thickness.

  The conductive salt in the plating solution used for forming the Ge-containing metal coating layer of the present invention is, for example, phosphoric acid or alkali metal phosphate, pyrophosphoric acid or alkali metal salt thereof, sulfuric acid or alkali metal salt thereof, nitric acid or alkali metal thereof. Inorganic acids such as salts or salts thereof, sulfonic acids or alkali metal salts thereof, organic acids such as citric acid or salts thereof, salts thereof, amides, and the like conventionally used can be used. The content of the conductive salt in the plating solution used in the present invention is usually in the range of 5 to 300 g / L.

  Examples of the soluble germanium compound in the plating solution used for forming the Ge-containing metal coating layer of the present invention include germanium phosphate, germanium sulfate, and germanium nitrate. This soluble germanium compound is used in the range of 0.1 to 20 g / L as a metal.

  Examples of the soluble metal compound include nickel sulfate, nickel chloride, cobalt sulfate, cobalt chloride, rhodium phosphate, ruthenium sulfate, ruthenium nitrate, palladium sulfate, palladium nitrate, soluble palladium cyanide, soluble ammonium palladium chloride, and soluble cyanide. Examples include potassium secondary gold and potassium platinum dinitrosulfate. These soluble metal compounds are used in the range of 0.5 to 20 g / L as metals.

  For the plating solution used for forming the Ge-containing metal coating layer of the present invention, a conventionally known brightener such as potassium perfluorooctane sulfonate, a stress relieving agent such as sodium naphthalene sulfonate, A smoothing agent, a surfactant and the like can be appropriately added as desired.

The current density in the electrolytic plating according to the present invention is generally 0.1 to 3.0 A / dm ² , and the plating time is usually several minutes to several tens of minutes. The liquid temperature is in the range of room temperature (about 25 ° C.) to about 80 ° C. These are appropriately selected depending on the desired plating film thickness, the type of substrate to be plated, the type of conductive salt or metal compound of the plating solution, and the like.

  The plating solution according to the present invention is maintained in an acidic state at a pH of 7.0 or less, and is carried out in a stable state. However, depending on the type of conductive salt, the type of metal compound or germanium compound, the pH is generally 0.5 to 5. It is carried out in the range of about 5.

  In the Ge-containing metal coating layer of the present invention, a metal coating containing 1 to 80% by weight of Ge can be obtained by changing the component ratio of Ge metal and other alloy metal in the plating solution for forming the coating. If the Ge component ratio exceeds 80% by weight, the coating becomes extremely brittle. Conversely, if the Ge component ratio is less than 1% by weight, the effects due to Ge tend to be difficult to be exhibited. The Ge component ratio is 5-60% by weight. Is preferred.

If desired, the metal part having the Ge-containing metal coating layer of the present invention can form a resin coating layer on the Ge-containing metal coating layer in the same manner as in a conventional wire or wire such as a brassiere. By having a resin coating layer, it is easy to attach when attaching to a bag-like attachment part formed on the lower peripheral part of a bust cup such as a brassiere, and it can prevent fabric protection and penetration, and also rust There is an advantage that it can be prevented. In addition, a feeling of fit when the metal is worn without being seen through the cloth of the bust cup is also preferable.
In addition, the metal parts for brassiere of the present invention are conventionally used for covering the end of the wire or wire with a cap-like material or the like, similar to the wire or wire used for the bust cup of women's clothing such as brassiere. It can be used after being processed.

  FIG. 1 is a schematic cross-sectional view of a metal part having a Ge-containing metal coating layer on the surface of a metal substrate according to the present invention. FIG. 2 is a schematic cross-sectional view of a metal part having a resin coating layer on a Ge-containing metal coating layer.

  Examples of the metal part having the Ge-containing metal coating layer according to the present invention will be specifically described below.

Example 1
Metal parts made of titanium alloy are surface-finished with a buff. First, 0.1 μm of pure gold is coated by electroplating (underplating), and then Ge-containing palladium coating is plated with a Ge-containing palladium plating solution as shown below. Went. The resulting coating obtained a metal part having a Ge-containing palladium coating with good adhesion and excellent grayish white aesthetics. The film was an alloy film containing 3% by weight of Ge as a result of analysis by fluorescent X-ray analysis.

Ge-containing palladium plating solution and plating conditions
Palladium sulfate (Pd: 10 g / L)
Sulfuric acid (100g / L)
Germanium sulfate (Ge: 5g / L)
Potassium perfluorooctane sulfonate (10ppm)
pH (0.8)
Liquid temperature (25 ℃)
Anode (Pt / Ti)
Current density (1A / dm ² )
Plating time (20 minutes)

Example 2
A metal part having a surface finished by blasting and polishing a stainless wire was plated with a Ge-containing nickel film having a thickness of 1.1 μm using the following Ge-containing nickel plating solution. Resin coating was performed on this to form a resin coating layer. As a result of analysis by the fluorescent X-ray analysis method from the surface having the resin coating layer, it was an alloy coating having a Ge content of 30% by weight.

Ge-containing nickel plating solution and plating conditions
Nickel phosphate (Ni: 50 g / L)
Phosphoric acid (60g / L)
Germanium phosphate (Ge: 3g / L)
Potassium perfluorooctane sulfonate (5ppm)
pH (1.0)
Liquid temperature (50 ℃)
Anode (Pt / Ti)
Current density (1A / dm ² )
Plating time (10 minutes)

Example 3
After buffing the surface of the metal part produced from the iron substrate, pure nickel was plated (underplating) to a thickness of 2 μm by electroplating. Next, a metal part having a film thickness of 0.2 μm was obtained with the following Ge-containing cobalt plating solution. Further, a resin film was formed on this as in Example 2. As a result of analysis by fluorescent X-ray analysis from the surface of the resin coating layer in the same manner as in Example 2, it was an alloy coating having a Ge content of 13.2% by weight.

Ge-containing cobalt plating solution and plating conditions
Cobalt sulfate (Co: 20 g / L)
Amidosulfuric acid (20 g / L)
Germanium sulfate (Ge: 5g / L)
Potassium perfluorooctane sulfonate (10ppm)
pH (1.8)
Liquid temperature (70 ℃)
Anode (Pt / Ti)
Current density (1A / dm ² )
Plating time (3 minutes)

Example 4
A metal part made of stainless steel was surface-finished with a buff, and plated with a Ge-containing rhodium plating solution to a film thickness of 0.8 μm. The obtained coating was a metal part with good adhesion and grayish white color and aesthetics. As a result of analysis by fluorescent X-ray analysis in the same manner as in Example 1, it was an alloy film having a Ge content of 30% by weight.

Ge-containing rhodium plating solution and plating conditions
Rhodium sulfate (Rh: 5g / L)
Potassium sulfate (30g / L)
Germanium sulfate (Ge: 5g / L)
Potassium perfluorooctane sulfonate (10ppm)
pH (2.0)
Liquid temperature (65 ℃)
Anode (Pt / Ti)
Current density (1A / dm ² )
Plating time (10 minutes)

Example 5
After buffing the surface of a metal part using brass as a base metal, bright nickel was plated to a thickness of 5 μm (base plating) by electroplating. Next, a metal part having a film thickness of 0.2 μm was obtained with the following Ge-containing gold plating solution. The obtained coating was a metal part with good adhesion, gold color and aesthetics. As a result of analysis by fluorescent X-ray analysis in the same manner as in Example 1, it was an alloy film having a Ge content of 1.1% by weight.

Ge-containing gold plating solution and plating conditions
Potassium cyanide (Au: 4g / L)
Citric acid (60g / L)
Germanium sulfate (Ge: 20g / L)
pH (5.0)
Liquid temperature (25 ℃)
Anode (Pt / Ti)
Current density (1A / dm ² )
Plating time (5 minutes)

The cross-sectional schematic diagram of the metal component which has a Ge containing metal coating layer concerning this invention is shown. The cross-sectional schematic diagram of the metal component which has a resin film layer on Ge containing metal film layer is shown.

Explanation of symbols

1 Base metal 2 Ge-containing metal coating layer 3 Resin coating layer

Claims (5)

  A metal part for brassiere, which is a wire or wire used for a lower peripheral edge of a bust cup, and has a Ge-containing metal coating layer containing 1 to 80% by weight of Ge on a base metal surface.   2. The metal part for brassiere according to claim 1, wherein the Ge-containing metal coating layer is partially provided.   3. The metal part for brassiere according to claim 1, further comprising a metal coating layer on the Ge-containing metal coating layer.   3. The metal part for brassiere according to claim 1, further comprising a resin coating layer on the Ge-containing metal coating layer. The metal part for brassiere according to any one of claims 1 to 4, wherein the Ge-containing metal coating layer is a coating formed by plating with a Ge / metal alloy plating solution.

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