CN-122010408-A - Production process of optical glass touch decorative panel

CN122010408ACN 122010408 ACN122010408 ACN 122010408ACN-122010408-A

Abstract

The invention relates to the technical field of glass panels, in particular to a production process of an optical glass touch decorative panel, which comprises the following steps of S1, weighing raw materials according to the following weight ratio, S2, uniformly mixing all the components, heating the mixture at the temperature of 700-900 ℃ for 1-2 hours to form a semi-fluid material, S3, dividing the semi-fluid material into weighing devices to obtain a semi-fluid glass material with fixed mass, S4, performing die casting molding on the semi-fluid glass material by a die casting machine, and then rapidly cooling to obtain a finished product.

Inventors

Shang Mingwu

Assignees

湖北澜心智能物联有限公司

Dates

Publication Date: 20260512
Application Date: 20250731

Claims (9)

1. S1, weighing 60-80 parts of silicon dioxide, 3-6 parts of disodium hydrogen phosphate, 0.5-3 parts of titanium dioxide, 2-10 parts of boron oxide, 4-6 parts of sodium oxalate, 10-25 parts of aluminum oxide, 10-25 parts of calcium carbonate and 5-8 parts of potassium nitrate according to the weight ratio; s2, uniformly mixing the components, and then heating at 700-900 ℃ for 1-2 hours to form a semi-fluid material; S3, passing the semi-fluid material through a dividing and weighing device to obtain a semi-fluid glass material with fixed mass; And S4, performing die casting molding on the semi-fluid glass material by using a die casting machine, and then rapidly cooling to obtain a finished product.
2. The manufacturing process of the touch decorative panel of the optical glass is characterized in that the split weighing device comprises a box body (1) with fixed relative positions, a material cavity (2) is arranged in the box body (1), a feed inlet (3), a discharge outlet (4) and an air pipe (5) are arranged at the position of the material cavity (2), a sealing mechanism (6) for sealing the feed inlet (3) is arranged on the box body (1), a cutting mechanism (7) for cutting the discharge outlet (4) effluent is arranged on the box body (1), after the discharge outlet (4) is formed, the cutting mechanism (7) seals the structure of the discharge outlet (4), the air pipe (5) is communicated with negative pressure equipment, a multi-stage pushing mechanism (8) for pushing the material to flow out of the discharge outlet (4) is arranged at the position of the material cavity (2), and a weighing mechanism (9) for weighing the material is arranged below the discharge outlet (4) of the box body (1).
3. The process for producing the optical glass touch decorative panel according to claim 2, wherein a containing tube (10) with a bidirectional opening and a funnel-shaped structure is arranged in the box body (1), the top and the bottom of the containing tube (10) are fixedly connected with the box body (1), the containing tube (10) and the box body (1) at the top and the bottom form a material cavity (2), the upper part of the containing tube (10) is of a table-shaped structure, the lower part of the containing tube (10) is of a columnar structure, and the small opening end of the table-shaped structure is fixedly connected with the columnar structure.
4. The manufacturing process of the optical glass touch decorative panel according to claim 3, wherein the containing tube (10) is made of a heat conducting material, and the heating component (11) is installed at the outer side of the containing tube (10).
5. The optical glass touch decorative panel production process according to claim 3, wherein the multi-stage pushing mechanism (8) comprises a first push rod (8.1), the first push rod (8.1) is in sliding connection with the box body (1), the first push rod (8.1) is fixedly connected with the moving end of the first telescopic piece (8.3), the fixed end of the first telescopic piece (8.3) is fixedly connected with the box body (1), and the first push rod (8.1) is in seamless contact fit with the surface of the inner side surface of the columnar structure in the containing tube (10).
6. The process for producing the optical glass touch decorative panel according to claim 5, wherein an installation cavity is formed in the first push rod (8.1), a sliding hole communicated with the installation cavity is formed in a part, close to the discharge hole (4), of the first push rod (8.1), the first push rod (8.1) is in sliding connection with the second push rod (8.2) through the sliding hole, the second push rod (8.2) is fixedly connected with the movable end of the second telescopic piece (8.4), the fixed end of the second telescopic piece (8.4) is fixedly connected with the first push rod (8.1), and the second telescopic piece (8.4) is located in the installation cavity.
7. The optical glass touch decorative panel production process according to claim 2, wherein the sealing mechanism (6) comprises a cover plate (6.1), the cover plate (6.1) is in sliding connection with the box body (1), a third telescopic piece (6.2) is arranged between the cover plate (6.1) and the box body (1), a first sealing ring is arranged between the box body (1) and the cover plate (6.1) by the box body (1), and the first sealing ring is sleeved on the feed inlet (3).
8. The optical glass touch decorative panel production process according to claim 2, wherein the cutting mechanism (7) comprises a cutting plate (7.1), the cutting plate (7.1) is in sliding connection with the box body (1), a fourth telescopic piece (7.2) is arranged between the cutting plate (7.1) and the box body (1), the surface dimension of the cutting plate (7.1) contacted with the outer surface of the box body (1) where the discharge port (4) is arranged is larger than the caliber dimension of the discharge port (4), a second sealing ring is arranged between the box body (1) and the cutting plate (7.1), and the second sealing ring is sleeved outside the discharge port (4).
9. The optical glass touch decorative panel production process according to claim 2, wherein the weighing mechanism (9) comprises a bidirectional opening annular tube (9.1), the annular tube (9.1) is located under the discharge hole (4), the bottom of the annular tube (9.1) is rotationally connected with a first support plate (9.2) and a second support plate (9.3), the first support plate (9.2) and the second support plate (9.3) are matched with a bottom tube orifice of the closed loop tube (9.1), a fifth telescopic piece (9.4) is rotationally connected between the first support plate (9.2), the second support plate (9.3) and the annular tube (9.1), a first rod (9.6) is installed on the annular tube (9.1), the first rod (9.6) is fixedly clamped with the second rod (9.7), a heavy installation position (9.8) is arranged between the first rod (9.6) and the second rod (9.7), and the first rod (9.6) is installed at the bottom of the box.

Description

Production process of optical glass touch decorative panel Technical Field The invention relates to the technical field of glass panels, in particular to a production process of an optical glass touch decorative panel. Background When the traditional optical glass touch decorative panel is produced, the raw materials are generally melted and then die-cast to obtain a semi-finished product panel, and then the semi-finished product panel is subjected to cutting, polishing, cleaning and other procedures to obtain a finished product, so that the finished product cannot be die-cast into a finished product with a proper size at one time, more procedures are increased, and the production efficiency is reduced. Disclosure of Invention Aiming at overcoming the defects of the prior art, the invention aims to provide a production process of an optical glass touch decorative panel, which solves the problem that a finished product with a proper size cannot be die-cast at one time. The technical scheme is that the production process of the optical glass touch decorative panel comprises the following steps of S1, weighing raw materials of 60-80 parts of silicon dioxide, 3-6 parts of disodium hydrogen phosphate, 0.5-3 parts of titanium dioxide, 2-10 parts of boron oxide, 4-6 parts of sodium oxalate, 10-25 parts of aluminum oxide, 10-25 parts of calcium carbonate and 5-8 parts of potassium nitrate according to the weight ratio; s2, uniformly mixing the components, and then heating at 700-900 ℃ for 1-2 hours to form a semi-fluid material; S3, passing the semi-fluid material through a dividing and weighing device to obtain a semi-fluid glass material with fixed mass; And S4, performing die casting molding on the semi-fluid glass material by using a die casting machine, and then rapidly cooling to obtain a finished product. Preferably, the split weighing device comprises a box body with fixed relative positions, a material cavity is arranged in the box body, a feed inlet, a discharge outlet and an air pipe are arranged at the material cavity, a sealing mechanism for sealing the feed inlet is arranged on the box body, a cutting mechanism for cutting the discharge outlet effluent is arranged on the box body, after the discharge outlet material is cut, the cutting mechanism seals the discharge outlet, the air pipe is communicated with negative pressure equipment, a multi-stage pushing mechanism for pushing the material to flow out of the discharge outlet is arranged at the material cavity, and a weighing mechanism for weighing the material is arranged below the discharge outlet. Preferably, a holding pipe with a bidirectional opening and a funnel-shaped structure is arranged in the box body, the top and the bottom of the holding pipe are fixedly connected with the box body, the holding pipe and the box body structure at the top and the bottom enclose a material cavity, the upper part of the holding pipe is of a table-shaped structure, the lower part of the holding pipe is of a columnar structure, and the small opening end of the table-shaped structure is fixedly connected with the columnar structure. Preferably, the containing tube is made of heat conducting material, and the heating component is arranged at the outer side of the containing tube. Preferably, the multistage pushing mechanism comprises a first push rod, the first push rod is in sliding connection with the box body, the first push rod is fixedly connected with the moving end of the first telescopic piece, the fixed end of the first telescopic piece is fixedly connected with the box body, and the first push rod is in seamless contact fit with the surface of the inner side face of the column-shaped structure in the holding tube. Preferably, the installation cavity is formed in the first push rod, a sliding hole communicated with the installation cavity is formed in a part, adjacent to the discharge hole, of the first push rod, the first push rod is in sliding connection with the second push rod through the sliding hole, the second push rod is fixedly connected with the moving end of the second telescopic piece, the fixed end of the second telescopic piece is fixedly connected with the first push rod, and the second telescopic piece is located in the installation cavity. Preferably, the sealing mechanism comprises a cover plate, the cover plate is in sliding connection with the box body, a third telescopic piece is arranged between the cover plate and the box body, a first sealing ring is arranged between the box body and the cover plate, and the first sealing ring is sleeved outside the feed inlet. Preferably, the cutting mechanism comprises a cutting plate, the cutting plate is in sliding connection with the box body, a fourth telescopic piece is arranged between the cutting plate and the box body, the surface size of the cutting plate, which is in contact with the outer surface of the box body where the discharge hole is located, is larger than the caliber size of t