CN-121318104-B - Energy-saving glass processing equipment and processing method thereof

Abstract

The invention relates to the technical field of glass processing, in particular to energy-saving glass processing equipment and a processing method thereof. The method has the beneficial effects that the energy consumption in the infiltration process can be reduced while the infiltration efficiency of the molten material is accelerated. The utility model provides an energy-saving glass processing equipment, includes the box, and both sides all rigid coupling has the connecting block around the box inside, and the rigid coupling has vacuum device between two connecting blocks, all rotates on two connecting blocks to be connected with the dwang, sliding connection has the rocking arm on the dwang, rotates between two rocking arms to be connected with the centrifugal part, and the rigid coupling has notes material portion in the detachable rigid coupling of centrifugal part upside, annotates material portion sliding connection on the pay-off frame, and the centrifugal part includes the bottom block, and the bottom block can be dismantled the rigid coupling on vacuum device, and the top block has been placed to the bottom block upside, and top block four corners department all is provided with the fixture block, and four fixture blocks all rotate to be connected on the bottom block, and the top block sideslip is connected with the heating apron, the inside upside rigid coupling of top block has the orifice plate, evenly is provided with a plurality of through-holes on the orifice plate.

Inventors

• WANG LUAN
• YANG HONGMEI

Assignees

• 安徽步华信息科技有限公司

Dates

Publication Date

20260505

Application Date

20251028

Claims (3)

1. 1. The energy-saving glass processing equipment is characterized by comprising a box body, wherein connecting blocks are fixedly connected to the front side and the rear side of the interior of the box body, a vacuum device is fixedly connected between the two connecting blocks, rotating blocks are rotatably connected to the two connecting blocks, rotating arms are slidably connected to the rotating blocks, a centrifugal part is rotatably connected between the two rotating arms, a material injection part is detachably and fixedly connected to the upper side of the centrifugal part, the material injection part is slidably connected to a feeding frame, the centrifugal part comprises a bottom block, the bottom block is detachably and fixedly connected to the vacuum device, top blocks are placed on the upper side of the bottom block, clamping blocks are arranged at four corners of the top block, the four clamping blocks are rotatably connected to the bottom block, a heating cover plate is slidably connected to the upper side of the top block, an orifice plate is fixedly connected to the upper side of the interior of the top block, and a plurality of through holes are uniformly formed in the orifice plate; a flow guide frame is also arranged in the top block; the two rotating arms are arranged on the long side of the eccentric part, and the rotating shafts of the four clamping blocks are arranged on the short side of the eccentric part; The rotating arm is rotatably connected with the midpoint of the centrifugal part, the rotating arm rotates on the upper side surface of the clamping block the distance between the bottom block and the lower side surface of the bottom block is the same; the edges of the clamping block and the bottom block are provided with round corners, a centrifugal rotating groove is formed in the box body, and the round corners correspond to the centrifugal rotating groove; External connection plates are fixedly connected to two sides of the long side of the bottom block, the rotating arm is connected to the corresponding external connection plate in a rotating mode, the top block can be inserted into the inner side of the external connection plate, and the upper side face of the external connection plate is overlapped with the lower side face of the heating cover plate; An extension rod is fixedly connected to the middle side of the rotating arm, two ends of the extension rod are both rotationally connected with one end of the side fixing rod, and a buckle corresponding to the other end of the side fixing rod is arranged on the outer connecting plate; notch corresponding to the lower side of the rotating arm is formed in each connecting block.
2. 2. The apparatus of claim 1, wherein the two sides of the housing are provided with housing cover plates, and wherein the two housing cover plates are capable of sliding back and forth on the housing and are fixed at end positions.
3. 3. A method of glass processing using an energy efficient glass processing apparatus as defined in claim 2, comprising the steps of: a, placing a base plate on a bottom block, and pressing a top block with a heating cover plate opened on the upper side of the base plate to obtain a centrifugal part to be initially pressed; b, pressing a material injection part on the upper side of a centrifugal part to be initially pressed, and pouring glass melt into the centrifugal part through the material injection part; starting a vacuum device, and carrying out vacuum adsorption on the inside of the centrifugal part through the vacuum device to enable the glass melt to completely enter the inside of the centrifugal part; Pushing the heating cover plate into the top block, closing the vacuum device, closing and removing the material injection part to obtain a rotatable centrifugal part; e, selecting a rotary centrifugal part according to a matrix form, and fixing the rotated centrifugal part through a rotating arm; f, starting a rotating block, and centrifugally penetrating the centrifugal part through the rotating block; And g, closing the rotating block, and repeating the steps c-f until finishing glass processing on the substrate.

Description

Energy-saving glass processing equipment and processing method thereof Technical Field The invention relates to the technical field of glass processing, in particular to energy-saving glass processing equipment and a processing method thereof. Background The glass melt infiltration sintering method is a method of impregnating a molten material into a porous matrix and filling the matrix with the melt by capillary force and temperature gradient. In the actual processing process, the melted material is required to contact the porous matrix, then the temperature and the pressure are regulated to gradually infiltrate the melt into the matrix, and finally the glass finished product which is formed by completely combining the melt and the matrix is prepared through sintering and solidification, but the infiltration stage is required to continuously keep the pressure state in the heating process, so that the energy consumption is higher. The method can utilize a centrifugal mode to push melt to permeate, so that partial energy consumption is relatively reduced, but the energy consumption in the high-speed centrifugal process is also higher, and the integrity of the matrix in the centrifugal process cannot be ensured. When the matrix is a thin sheet, the matrix is easy to deform or damage in the centrifugation process, and when the matrix is a hard block, the melt is easy to infiltrate unevenly in the centrifugation process. Disclosure of Invention In order to overcome the defects of the prior art, the invention provides energy-saving glass processing equipment and a processing method thereof, and has the beneficial effects that the energy consumption in the infiltration process can be reduced while the infiltration efficiency of molten materials is accelerated. The technical scheme adopted for solving the technical problems is as follows: The utility model provides an energy-saving glass processing equipment, includes the box, and both sides all rigid coupling has the connecting block around the box inside, and the rigid coupling has vacuum device between two connecting blocks, all rotates on two connecting blocks to be connected with the dwang, sliding connection has the rocking arm on the dwang, rotates between two rocking arms to be connected with the centrifugal part, and the rigid coupling has notes material portion in the detachable rigid coupling of centrifugal part upside, annotates material portion sliding connection on the pay-off frame, and the centrifugal part includes the bottom block, and the bottom block can be dismantled the rigid coupling on vacuum device, and the top block has been placed to the bottom block upside, and top block four corners department all is provided with the fixture block, and four fixture blocks all rotate to be connected on the bottom block, and the top block sideslip is connected with the heating apron, the inside upside rigid coupling of top block has the orifice plate, evenly is provided with a plurality of through-holes on the orifice plate. And a flow guide frame is further arranged in the top block. Two sides of the box body are provided with box body cover plates, and the two box body cover plates can slide back and forth on the box body and are fixed at end point positions. The two rotating arms are arranged on the long side of the eccentric part, and the rotating shafts of the four clamping blocks are arranged on the short side of the eccentric part. A method of energy efficient glass processing, the method comprising the steps of: a, placing a base plate on a bottom block, and pressing a top block with a heating cover plate opened on the upper side of the base plate to obtain a centrifugal part to be initially pressed; b, pressing a material injection part on the upper side of a centrifugal part to be initially pressed, and pouring glass melt into the centrifugal part through the material injection part; starting a vacuum device, and carrying out vacuum adsorption on the inside of the centrifugal part through the vacuum device to enable the glass melt to completely enter the inside of the centrifugal part; Pushing the heating cover plate into the top block, closing the vacuum device, closing and removing the material injection part to obtain a rotatable centrifugal part; e, selecting a rotary centrifugal part according to a matrix form, and fixing the rotated centrifugal part through a rotating arm; f, starting a rotating block, and centrifugally penetrating the centrifugal part through the rotating block; And g, closing the rotating block, and repeating the steps c-f until finishing glass processing on the substrate. The stress direction of the substrate can be changed by changing the centrifugal direction of the centrifugal position, so that the substrate is prevented from being damaged in the centrifugal process, or the infiltration speed of glass melt is increased when the strength of the substrate is enough, and the melting infiltration efficiency of glass on