MANUFACTURING PROCESS OF HEAT-RESISTING GLASS OR ENAMEL COATING ON A THERMALLY INSULATED CONTAINER CHAMBER

Abstract

A manufacturing process of a heat-resisting glass or enamel coating of a thermally insulated container chamber is described. The process comprises selecting a thermally insulated metal container body, and performing sand blasting to a chamber surface of the body such that the chamber surface becomes a rough surface. The process comprises spraying a glass or enamel glazing material on the rough surface of the body and drying the glazing material on the rough surface. The process comprises placing a dried body on a bracket and sintering the dried body. After sintering is performed, the process comprises removing the body from the bracket. Using this disclosure the chemical properties of the glass coating or enamel coating are relatively stable, so corrosion will not occur. Because the thermal expansion and cold contraction are relatively small, the coating is suitable for manufacturing thermally insulated containers such as thermally insulated cups.

Claims

1. A manufacturing process of a heat-resisting glass or enamel coating on a thermally insulated container chamber, comprising: selecting a thermally insulated container body made of metal and performing sandblasting to inner chamber surface of the thermally insulated metal container body such that the inner chamber surface becomes a coarse surface; spraying a glass or enamel glazing material onto the coarse surface of the thermally insulated metal container body; drying the glazing material on the coarse surface; placing a dried thermally insulated metal container body on a bracket; sintering the dried thermally insulated metal container body; and after sintering is completed, removing the thermally insulated metal container body from the bracket to obtain a finished product.

2. The manufacturing process of claim 1, during selecting, using white corundum with 46-60 meshes as a material for performing the sandblasting under an air pressure ranging from 6-8 MPa; and during sandblasting, the thermally insulated metal container body is fixed with an opening end facing downwards and then rotated slowly for 60-120 seconds.

3. The manufacturing process of claim 1, further comprising shielding a non-effective surface of the thermally insulated metal container body by a barrier when performing the sandblasting.

4. The manufacturing process of claim 1, wherein the glazing material being used in the spraying has a specific gravity that ranges from 1.65 to 1.70, adhesion amount of the glazing material ranges from 120 to 130 grams per square meter (g/m.sup.2), and thickness of the glazing material is maintained at 180 μm.

5. The manufacturing process of claim 1, wherein the glaze material drying temperature ranges from 200 to 250° C. and a chain speed of the thermally insulated metal container body is between 1.5 and 3 meter/minute.

6. The manufacturing process of claim 1, further including cleaning excessive glazing material on the thermally insulated metal container body with a wiping object before placing said metal container body on said bracket, and positioning the thermally insulated metal container body on the bracket with an opening end of the body facing downwards.

7. The manufacturing process of claim 1, wherein sintering is performed at a temperature ranging from 780° C. to 840° C. and a chain speed of 3 meters per minute.

8. The manufacturing process of claim 1, wherein the thermally insulated metal container is a thermally insulated vessel.

9. The manufacturing process of claim 1, wherein the thermally insulated metal container is a thermally insulated cup.

10. A thermally insulated cup manufactured according to the manufacturing process as defined by claim 1.

Description

DETAILED DESCRIPTION

[0022] The disclosure discloses a manufacturing process of a heat-resisting glass or enamel coating for chamber of a thermally insulated container. The manufacturing process comprises the steps of: selecting a thermally insulated container body made of metal and performing sandblasting to inner chamber surface of the thermally insulated metal container body such that the inner chamber surface becomes a coarse surface; spraying a glass or enamel glazing material onto the coarse surface of the thermally insulated metal container body; drying the glazing material on the coarse surface; placing a dried thermally insulated metal container body on a bracket; sintering the dried thermally insulated metal container body; and after sintering is performed, removing the thermally insulated metal container body from the bracket to obtain a finished product.

[0023] During manufacturing process of the thermally insulated container according to the present disclosure, after a glass coating or enamel coating is formed on the inner chamber surface of the thermally insulated container body, because chemical properties of the glass coating or enamel coating are relatively stable, corrosion is prevented from occur. Meanwhile, because thermal expansion and cold contraction degree of the glass coating or enamel coating is relatively small, the glass coating or enamel coating is suitable for manufacture of thermally insulated containers such as thermally insulated cups.

[0024] Usually, the container body metal may be white corundum with 46-60 meshes is used as a material for performing sandblasting and sandblasting operation is performed under an air pressure ranging from 6 MPa to 8 MPa. During sandblasting, the thermally insulated metal container body is fixed with its opening end facing downwards and then rotated slowly for 60-120 seconds. After sandblasting, roughness of the inner chamber surface of the thermally insulated metal container body is about Ra3.2 μm to Ra6.3 μm. Because white corundum is hard, it is a good material for sandblasting. During sandblasting, the thermally insulated metal container body is kept facing downwards which can prevent dusts from accumulating inside the body chamber and the dusts generated can also directly fall off the container body. Because the surface roughness of the chamber directly affects the surface adhesion force of the glazing material, when the inner chamber surface is rough, the surface adhesion force is relatively higher. The denser the pits caused by the sandblasting are, the better the adhesion effect is. Some experiments show that the surface adhesion force of the glazing material is better when the surface roughness of the metal is ranging Ra3.2 μm to Ra6.3 μm.

[0025] In addition, during sandblasting, the non-effective surface of the thermally insulated metal container body by a barrier is shielded when performing sandblasting. This is advantageous on that, after shielding the non-effective surface, pits on unnecessary areas of the surfaces can be prevented.

[0026] The specific gravity of the glazing material being used in the spraying operation ranges from 1.65 to 1.70 (namely, mass ratio of the glazing material to water is between 1.65 and 1.70). Adhesion amount of the glazing material adhered to the inner chamber surface ranges from 120 to 130 g/m.sup.2 and thickness of the glazing material is maintained at 180 μm. The advantageous effect is that a good glazing effect can be ensured.

[0027] During the drying process, the drying temperature ranges from 200° C-250° C. and a chain speed of the thermally insulated metal container body is between 1.5 and 3 meter/minute. The chain speed refers to moving speed of the thermally insulated metal container body during the drying process. The advantageous effect is that a good drying effect can be ensured and the drying time can be shortened. If the temperature or the chain speed is too high, the thermally insulated metal container body may be damaged or suffer from an uneven drying.

[0028] Before placing the dried container body on a bracket, the manufacturing process further comprises cleaning excessive glazing material on the thermally insulated metal container body by using a wiping object. After placing the thermally insulated container body on the bracket, the container body is kept with its opening end facing downwards. With this configuration, the following advantageous effects can be produced: 1) usually, sponge with little clean water can be used for the cleaning; and 2) because the opening of the dried thermally insulated metal container body is kept facing downwards, the glazing material can be prevented from flowing back to the inside of the opening of the dried thermally insulated metal container body due to gravity and thus local clustering of the glazing material can be prevented.

[0029] During sintering, the sintering temperature is adopted as 780-840° C. and the chain speed is chosen as 3 meters per minute. This can ensure a good sintering effect.

[0030] The present disclosure also relates to a thermally insulated vessel manufactured according to the above manufacturing process. Specifically, the thermally insulated vessel is a thermally insulated cup.

[0031] With the thermally insulated cup manufactured according to the above manufacturing process, a glass coating or enamel coating is formed onto the chamber surface of the thermally insulated cup. Because chemical properties of the glass coating or enamel coating are relatively stable, corrosion will not occur. In addition, thermal expansion and cold contraction degree of the glass coating or enamel coating are also relatively lower.

[0032] When the thermally insulated cup of the present disclosure encounters with hot water, no unhealthy substances will be generated so that safety property of the thermally insulated cup is good. In addition, thermal expansion and cold contraction degree of the glass coating or enamel coating are relatively smaller, so sealing property of the thermally insulated cup of this disclosure will not degrade after long-term use.

[0033] When carbonated drinks, alkali drinks or tea is/are contained in the thermally insulated cup of the present disclosure, acids or alkalis in such drinks cannot corrode the glass coating or enamel coating and no metal ions will be generated. After long-term use, the thermally insulated cup according to the present disclosure will not generate a taste of rust which can bring good user experience.

[0034] The above are only some embodiments of the present disclosure. Various modifications and improvements can be made by those skilled in the art without departing from the inventive concept of the present disclosure as set forth in the appended claims.