CN212488823U - Gold-coated silver ornament - Google Patents

Abstract

The utility model relates to a gold-coated silver ornament, which comprises a silver substrate, a first isolating layer, a second isolating layer, a gold-plated layer and a protective layer; the outer surface of the silver substrate is sequentially provided with a first isolating layer, a second isolating layer, a gold-plated layer and a protecting layer from inside to outside; the silver matrix is hollow or solid; the utility model discloses a gold alclad silver ornaments increases first isolation layer and second isolation layer in the middle of gold plating layer and silver base member, and the effect of two isolation layers prevents the gold plating layer, takes place the diffusion between the silver base member, can guarantee gold on the one hand, silver-colored, and on the other hand can prevent that the gold layer from taking place to fade to at gold plating layer outside plating one deck protective layer, the effect of protective layer is the wearability that improves the product, grease proofing nature, by the utility model discloses the Vickers hardness of gold alclad silver ornaments of preparation can reach about 110HV, and wherein gold and silver-colored all > 99.9%, and the product has good wear-resisting and corrosion resisting property simultaneously, can not appear skinning, fade or the scheduling problem that discolours, has better practicality.

Description

Gold-coated silver ornament

Technical Field

The utility model relates to a noble metal ornaments preparation technical field especially relates to a gold bao yin ornaments.

Background

The gold ornaments have the characteristics of bright color, good corrosion resistance and the like, are popular with consumers, but the expensive price of the gold ornaments is very prohibitive for many people, and in order to meet the requirements of people, many gold imitation ornaments or gold plating ornaments appear in the market, have the color of the gold ornaments, and have the price within the bearable range of wide consumers. However, the gold-like or gold-plated products are easy to have the problems of peeling, fading or discoloration after being worn for a period of time, and some products even cause allergic reaction of the skin, thereby bringing inconvenience to daily use of users and being not beneficial to large-scale application.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the not enough of prior art and providing a gold and silver look and hardness height, have good wear resistance and corrosion resisting property simultaneously, can not appear skinning, fade or the gold of the scheduling problem of discolouing adornment of silver-clad after wearing for a long time.

In order to achieve the above purpose, the utility model adopts the technical scheme that: a gold-coated silver ornament comprises a silver substrate, a first isolation layer, a second isolation layer, a gold-plated layer and a protection layer; the outer surface of the silver substrate is sequentially provided with a first isolation layer, a second isolation layer, a gold-plated layer and a protection layer from inside to outside.

Further, the silver matrix is hollow or solid.

Further, the first isolation layer is of a single-layer/multi-layer structure.

Further, each layer of the first isolation layer is made of one of gold, silver, platinum, palladium, rhodium, iridium, zinc, ruthenium, titanium and zirconium or an alloy thereof.

Further, the second isolation layer is of a single-layer/multi-layer structure.

Further, each layer of the second isolation layer is made of one of gold, silicon nitride, titanium nitride, aluminum nitride, zirconium nitride, titanium carbide and titanium aluminum nitride.

Furthermore, the weight percentage of the gold in the gold-plated layer and the weight percentage of the silver in the silver matrix are both 99.9-99.99%.

Further, the protective layer is of a single-layer/multi-layer structure.

Furthermore, each layer of the protective layer is one of fluoride, nitride, silicide and silicon-aluminum oxide.

Because of above-mentioned technical scheme's application, compared with the prior art, the utility model have the following advantage:

the gold-coated silver ornament prepared by the method has the following advantages:

the color of gold and silver is more than 99.9%.

And the Vickers hardness of the product can reach about 110 HV.

And the product has good wear resistance and corrosion resistance.

And fourthly, the problems of peeling, fading or discoloration and the like do not occur after the long-term wear, and the long-term wear can be realized.

Drawings

The technical scheme of the utility model is further explained by combining the attached drawings as follows:

FIG. 1 is a schematic structural view of the gold and silver-coated jewelry of the present invention;

FIG. 2 is a comparison of vacuum heating tests of first barrier layers of different samples;

FIG. 3 is a graph comparing the wear resistance effect of a second barrier layer of a different article;

FIG. 4 is a graph comparing the wear resistance effect of protective layers of different samples;

FIG. 5 is a comparison graph of the gold and silver coloration for samples of different gold plating layer thicknesses;

FIG. 6 is a graph comparing Vickers hardness of different samples;

FIG. 7 is a graph of the vulcanization resistance test behavior of various samples;

wherein: silver base member 1, first isolation layer 2, second isolation layer 3, gold-plated layer 4, protective layer 5.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1, the gold-coated silver ornament of the present invention includes a silver substrate 1, a first isolation layer 2, a second isolation layer 3, a gold-plated layer 4 and a protection layer 5; the outer surface of the silver substrate 1 is sequentially provided with a first isolation layer 2, a second isolation layer 3, a gold-plated layer 4 and a protection layer 5 from inside to outside.

As a further preferred embodiment, the silver matrix 1 is hollow or solid, and the weight percentage of the silver in the silver matrix 1 is 99.9-99.99%.

As a further preferred embodiment, the first isolation layer 2 may be a single layer, or may be two or more layers, and the composition of each layer may be one of gold, silver, platinum, palladium, rhodium, iridium, zinc, ruthenium, titanium, and zirconium, or an alloy thereof; the first isolating layer can prevent silver in the silver substrate from diffusing to the gold plating layer, so that the color of gold and silver can be ensured, and the color fading of the gold layer can be prevented.

As a further preferred embodiment, the second isolation layer 3 may be a single layer, or may be two or more layers, and each layer has one of gold, silicon nitride, titanium nitride, aluminum nitride, zirconium nitride, titanium carbide, and titanium aluminum nitride; wherein the second isolating layer can increase the wear resistance of the gold-coated hard ornament.

As a further preferred embodiment, the material of the protective layer 5 may be a single layer, or may be two or more layers, each layer has one of fluoride, nitride, silicide and silicon-aluminum oxide as a component, and the protective layer has the characteristics of water resistance, oil resistance, scratch resistance, fingerprint resistance, pollution prevention, easy cleaning and the like, and can improve the corrosion resistance of the product.

In addition, the utility model discloses still contain a preparation method of gold alclad silver ornaments, include the following step:

step 1: the silver matrix is prepared by a fusion casting or calendering method, wherein the weight percentage content of the silver is 99.9-99.99%.

Step 2: and forming a first isolating layer on the surface of the silver substrate by adopting an electroplating or chemical plating process, wherein the thickness of the first isolating layer is 0.01-5 mu m.

Step 3: and forming a second isolation layer with a thickness of 0.001-0.5 μm on the first isolation layer by vacuum coating or electroplating process.

Step 4: and forming a gold-plated layer on the second isolation layer by a cyanide-free electroplating process, wherein the gold in the gold-plated layer accounts for 99.9-99.99% by weight and has a thickness of 1-100 mu m.

Step 5: and forming a transparent protective layer with a thickness of 0.0002-0.1 μm on the gold-plated layer by physical vapor deposition or electrophoresis.

Several examples are described below.

The first embodiment is as follows:

the preparation method of the gold-coated silver ornament comprises the following steps:

step 1: the silver matrix is prepared by a fusion casting method, the silver matrix is hollow, and the silver content is 99.96%.

Step 2: and forming a silver coating on the surface of the silver substrate by adopting an electroplating process, wherein the thickness of the silver coating is 5 mu m.

Step 3: titanium nitride was formed on the silver plating layer by a vacuum plating process to a thickness of 0.2 μm.

Step 4: and forming a gold-plated layer on the titanium nitride through a cyanide-free electroplating process, wherein the gold content of the gold-plated layer is 99.92% by weight and the thickness of the gold-plated layer is 3 mu m.

Step 5: and forming an AF film on the gold plating layer by adopting a physical vapor deposition process, wherein the thickness of the AF film is 0.01 mu m.

Example two:

the preparation method of the gold-coated silver ornament comprises the following steps:

step 1: the silver matrix is prepared by a fusion casting method, the silver matrix is hollow, and the silver content is 99.97%.

Step 2: a platinum coating with a thickness of 0.05 μm is formed on the surface of the silver substrate by an electroplating process.

Step 3: zirconium nitride was formed on the silver plating layer by a vacuum plating process to a thickness of 0.2 μm.

Step 4: and forming a gold-plated layer on the zirconium nitride by a cyanide-free electroplating process, wherein the gold content of the gold-plated layer is 99.92% by weight and the thickness of the gold-plated layer is 2 microns.

Step 5: and forming a ceramic film with the thickness of 0.005 mu m on the gold-plated layer by adopting a physical vapor deposition process.

Example three:

the preparation method of the gold-coated silver ornament comprises the following steps:

step 1: the silver matrix is prepared by a fusion casting method, and is solid, wherein the silver content is 99.99%.

Step 2: a palladium plating layer is formed on the surface of the silver substrate by adopting an electroplating process, and the thickness of the palladium plating layer is 0.05 mu m.

Step 3: 24K gold is formed on the palladium plating layer through a vacuum plating process, and the thickness of the gold is 0.03 mu m.

Step 4: a gold plating layer is formed on the 24K gold by a cyanide-free electroplating process, wherein the weight content ratio of gold in the gold plating layer is 99.95%, and the thickness of the gold plating layer is 3 mu m.

Step 5: and forming a layer of nano film on the gold-plated layer by adopting a physical vapor deposition process, wherein the thickness of the nano film is 0.01 mu m.

Example four:

the preparation method of the gold-coated silver ornament comprises the following steps:

step 1: the silver matrix is prepared by a fusion casting method, and is solid, wherein the silver content is 99.98%.

Step 2: a rhodium plating layer is formed on the surface of the silver substrate by adopting an electroplating process, and the thickness of the rhodium plating layer is 0.05 mu m.

Step 3: aluminum nitride was formed on the rhodium plating layer by a vacuum plating process to a thickness of 0.2 μm.

Step 4: a gold plating layer is formed on the aluminum nitride through a cyanide-free electroplating process, wherein the gold content ratio of the gold plating layer is 99.93%, and the thickness of the gold plating layer is 0.23 mu m.

Step 5: and forming an AF film and a nano film on the gold-plated layer by adopting a physical vapor deposition process, wherein the thickness of the AF film and the nano film is 0.011 mu m.

Example five:

the preparation method of the gold-coated silver ornament comprises the following steps:

step 1: the silver matrix is prepared by a fusion casting method, and is solid, wherein the silver content is 99.98%.

Step 2: a composite layer of a silver plating layer and a platinum plating layer is formed on the surface of the silver substrate by adopting an electroplating process, and the thickness of the composite layer is 5.05 mu m.

Step 3: and forming a composite layer of zirconium nitride and 24K gold on the composite layer of the silver plating layer and the platinum plating layer by a vacuum coating process, wherein the thickness of the composite layer is 0.23 mu m.

Step 4: and forming a gold-plated layer on the composite layer of the zirconium nitride and the 24K gold by a cyanide-free electroplating process, wherein the gold content ratio of the gold in the gold-plated layer is 99.94%, and the thickness of the gold-plated layer is 2 microns.

Step 5: and forming a layer of AF film and nano film composite film on the gold-plated layer by adopting a physical vapor deposition process, wherein the thickness of the AF film and the nano film composite film is 0.005 mu m.

Example six:

the preparation method of the gold-coated silver ornament comprises the following steps:

step 1: the silver matrix is prepared by a fusion casting method, the silver matrix is hollow, and the silver content is 99.98%.

Step 2: a composite layer of a silver plating layer and a palladium plating layer is formed on the surface of the silver substrate by adopting an electroplating process, and the thickness of the composite layer is 5.05 mu m.

Step 3: and forming a composite layer of zirconium nitride and 24K gold on the composite layer of the silver plating layer and the palladium plating layer by a vacuum coating process, wherein the thickness of the composite layer is 0.23 mu m.

Step 4: and forming a gold-plated layer on the composite layer of the zirconium nitride and the 24K gold by a cyanide-free electroplating process, wherein the gold content ratio of the gold in the gold-plated layer is 99.93%, and the thickness of the gold-plated layer is 2 microns.

Step 5: a composite film of a ceramic film and a nano film is formed on the gold-plated layer by adopting a physical vapor deposition process, and the thickness of the composite film is 0.006 mu m.

The present invention will be further described with reference to the related data.

1. First, the isolation effect of the first isolation layer is tested and explained.

Firstly, a gold plating layer is directly formed on one silver substrate in a cyanide-free electroplating mode, then, first isolation layers are formed on the other six silver substrates in an electroplating mode, materials of the first isolation layers are respectively six materials in the embodiments, then, the gold plating layer is directly formed on the first isolation layers in the cyanide-free electroplating mode, then, through a vacuum heating test, the isolation effect of the first isolation layers is compared, the test condition is that the temperature is heated to 180 ℃ in vacuum, the color change of a sample is observed, if the color of a product is lightened, the effect of the isolation layers is not achieved, and the test result is shown in attached figure 2.

It can be seen from fig. 2 that after the first isolation layer is plated on the surface of the silver substrate, the silver in the silver substrate can be effectively prevented from diffusing to the gold plating layer, the isolation effect of the silver plating layer is better than that without the isolation layer, and the platinum plating layer and the palladium plating layer have better isolation effect.

2. Next, the abrasion resistance of the second separator layer will be described.

Electroplating first isolation layer on the silver base member, first isolation layer is silver-plated layer and platinum coating, and the second isolation layer is formed through vacuum coating's mode, and the material of second isolation layer has adopted the material in six embodiments, then forms the gold layer through cyanide-free gilding technology on the second isolation layer, through the effect of wear-resisting experiment inspection second isolation layer, the wear-resisting experiment is gone on through paper tape friction test, and specific experimental result is shown in figure 3.

It can be seen from the results of the analytical wear test in fig. 3 that the wear resistance of the sample can be effectively increased by adding the second isolation layer, and the effects of titanium nitride and zirconium nitride are better than those of 24K gold, while the effects of the two layers are better than those of the single layer.

3. The abrasion resistance of the protective layer is tested and illustrated.

The method comprises the steps of firstly electroplating a first isolation layer on a silver substrate, wherein the first isolation layer is a silver plating layer and a platinum plating layer, then plating a second isolation layer on the first isolation layer, the second isolation layer is titanium nitride, then forming a gold layer on the second isolation layer through a cyanide-free electroplating process, and finally forming a protection layer on the gold layer through a vacuum coating process or an electrophoresis process, wherein the protection layer is made of six materials in six embodiments, the effect of the protection layer is checked through a wear-resistant test, and the specific experimental result is shown in figure 4.

As can be seen from fig. 4, the protective layer has a certain effect of improving the wear resistance, wherein the effect of the composite film of the ceramic film and the nano film is better.

4. Test description of color formation.

The silver-coated ornaments with gold layers of 3 microns, 5 microns, 10 microns and 100 microns in thickness are prepared by taking a silver plating layer and a platinum plating layer as a first isolation layer, titanium nitride as a second isolation layer and ceramic films and nano films as protection layers, the color of the ornaments is respectively tested, the color detection method is to carry out color detection by a fire test gold method, and the specific result is shown in the attached figure 5:

as can be seen from the color forming results of the au-coated-ag samples with different au layer thicknesses shown in fig. 5, the color forming of the ag substrate and the au layer is more than 99.9%, which meets the actual requirement.

5. And (5) testing and explaining the hardness.

In order to analyze the effect of each layer of the plated layer on the hardness of the product, the following test was performed, and the results are shown in FIG. 6.

As can be seen from the hardness test result shown in fig. 6, the second isolation layer and the protective layer are beneficial to improving the hardness of the product, the thickness of the gold layer has a certain influence on the hardness of the product, when the thickness of the gold layer is less than 10 μm, the hardness is obviously improved along with the increase of the thickness of the gold layer, and when the thickness of the gold layer is greater than 10 μm, the hardness is not obviously improved.

6. And (5) performing salt spray testing.

The salt spray tests are respectively carried out on 4, 5, 6, 7 and four samples in the hardness test, the states of the samples have no obvious change, and the salt spray test method is mainly used for testing the corrosion resistance of the samples.

Wherein, the test conditions are 35 ℃/72h, pH is 6.8, spray pressure: 100 kPa.

7. And (4) testing vulcanization resistance.

The anti-vulcanization test was performed on 1, 2, 3, and 4 samples of the hardness test, and the test results are shown in fig. 7.

Wherein, the anti-vulcanization test method comprises the following steps: the samples were immersed in 1% Na according to the method provided for the quality inspection of the HB5051-77 silver coatings₂And (3) dipping in the S solution at the temperature of 15-25 ℃, observing the change of the sample, and as can be seen from the vulcanization resistance test result shown in the attached figure 7, the first isolation layer, the second isolation layer and the protective layer can improve the vulcanization resistance of the product.

In conclusion, the gold-coated silver ornament prepared by the method provided by the utility model has the following characteristics: a. the gold and silver have the color of more than 99.9%; b. the Vickers hardness of the product can reach about 110 HV; c. the product has good wear resistance; d. the product has better corrosion resistance.

The above is only a specific application example of the present invention, and does not constitute any limitation to the protection scope of the present invention. All the technical solutions formed by equivalent transformation or equivalent replacement fall within the protection scope of the present invention.

Claims (9)

1. A gold-coated silver ornament is characterized in that: comprises a silver substrate, a first isolating layer, a second isolating layer, a gold-plated layer and a protective layer; the outer surface of the silver substrate is sequentially provided with a first isolation layer, a second isolation layer, a gold-plated layer and a protection layer from inside to outside.

2. The gold-coated silver ornament of claim 1, wherein: the silver matrix is hollow or solid.

3. The gold-coated silver ornament of claim 1, wherein: the first isolation layer is of a single-layer/multi-layer structure.

4. The gold-coated silver ornament of claim 3, wherein: each layer of the first isolation layer is made of one or an alloy of gold, silver, platinum, palladium, rhodium, iridium, zinc, ruthenium, titanium and zirconium.

5. The gold-coated silver ornament of claim 1, wherein: the second isolation layer is of a single-layer/multi-layer structure.

6. The gold-coated silver ornament of claim 1, wherein: each layer of the second isolation layer is made of one of gold, silicon nitride, titanium nitride, aluminum nitride, zirconium nitride, titanium carbide and titanium aluminum nitride.

7. The gold-coated silver ornament of claim 1, wherein: the weight percentage of the gold in the gold-plated layer and the weight percentage of the silver in the silver matrix are both 99.9-99.99%.

8. The gold-coated silver ornament of claim 1, wherein: the protective layer is of a single-layer/multi-layer structure.

9. The gold-coated silver ornament of claim 1, wherein: each layer of the protective layer is composed of one of fluoride, nitride, silicide and silicon-aluminum oxide.

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