CN113526863B - Broken slag treatment method for glass production - Google Patents

Abstract

The invention relates to the technical field related to glass production, in particular to a glass production slag treatment method, which is completed by adopting glass production cutting slag treatment equipment, wherein the glass production cutting slag treatment equipment comprises a cutting box, one side of the cutting box is provided with an inlet, the rear side of the inlet is provided with a cutting moving part for carrying out fixed cutting moving cleaning action on glass, a separating part is arranged below the cutting moving part for separating glass slag from water, a crushing part is arranged below the separating part for crushing large glass blocks of glass firstly and then carrying out multiple grinding on the glass, and a storage and taking-out part is arranged below the crushing part for storing the ground glass. According to the invention, the water and the glass slag are separated through the cooperation of the rotation of the workbench and the water pump, so that the recycling of the water and the glass slag is facilitated; grinding glass into powder by multiple grinding has been used to reproduce new glass by melting.

Description

Broken slag treatment method for glass production

Technical Field

The invention relates to the technical field related to glass production, in particular to a method for treating broken slag in glass production.

Background

The glass cutting process can produce a certain amount of glass fragments, can't handle through artifical bare-handed to glass fragments, easily scratch staff's hand, current glass cutting fragment treatment facility can not separate fragments and the water of cutting, can not carry out abundant interests to the fragments, and the processing of current glass cutting fragment treatment facility fragment is smashed and is retrieved just not, and the fragment also can improve to grind to melt and produce new glass again.

Disclosure of Invention

The invention aims at solving the problems in the prior art and provides a method for treating broken slag in glass production, which comprises the steps of separation, grinding and recycling.

In order to achieve the above purpose, the present invention adopts the following technical scheme: a glass production slag treatment method comprises the following steps:

s1, putting glass into a cutting box through an inlet;

s2, moving and fixing, namely moving the glass through a sucker, and fixing the glass through a rotating fixing block;

s3: cutting glass, namely fixing two sides of the glass, and cutting the glass;

s4: cleaning and removing, namely cleaning the surface of the glass by using a sucker, and sucking the glass by using the sucker and moving the glass out of the box body;

s5: separating, namely separating and absorbing glass slag and water generated in the cutting process, and keeping the water on a workbench for absorption, wherein the glass slag is thrown out and falls down in a rotating way;

s6: breaking glass, and breaking and dropping large glass into the grinding cylinder through the breaking component;

s7, multiple grinding, namely, grinding the glass slag for multiple times and then dropping the glass slag into a storage box;

s8: taking out, heating and melting the ground glass slag to produce new glass;

the steps S1-S8 are completed by adopting glass production cutting slag treatment equipment, the glass production cutting slag treatment equipment comprises a cutting box, an inlet is formed in one side of the cutting box, a cutting moving part is arranged on the rear side of the inlet to conduct fixed cutting, moving and cleaning functions on glass, a separating part is arranged below the cutting moving part to separate glass slag from water, a crushing part is arranged below the separating part to crush large glass firstly and then conduct multiple grinding on the glass, a storage and taking-out part is arranged below the crushing part to store the ground glass, an outlet is formed in one side of the inlet, and a sliding door is arranged in the sliding mode in the inlet.

Preferably, the cutting moving part comprises a first roller, the first roller is located on one side wall of the cutting box and is in sliding connection, the first roller is provided with a second roller towards the inner direction of the cutting box, the second roller is far away from the first roller on one side wall of the cutting box and is in sliding connection, the first roller is fixedly provided with a first connecting column towards one end of the second roller, the second roller is fixedly provided with a second connecting column towards one end of the first roller, a sliding groove is fixedly connected between the first connecting column and the second connecting column, a sliding block is arranged in the sliding groove in a sliding mode, the lower end of the sliding block is fixedly provided with a circular plate, and the lower end of the circular plate is fixedly provided with a cutting column.

Preferably, the inside mixing chamber that is equipped with of slider, cutting post lower extreme are equipped with high-pressure nozzle, are connected between high-pressure nozzle and the mixing chamber and are equipped with the passageway, and high-pressure nozzle periphery has set firmly the sucking disc, and sucking disc one side arc is equipped with the air pump, is connected between air pump and the passageway and is equipped with the outlet duct, and the air pump is equipped with the breathing pipe downwards and carries out suction effect to glass, and first gyro wheel and second gyro wheel below rotate on cutting case wall and are equipped with six revolving posts, and six revolving posts have set firmly six telescopic links to the inside direction of cutting case, and six telescopic links have set firmly six fixed posts to the cutting post direction.

Preferably, the separating component comprises a workbench, the workbench is positioned below the cutting moving component, four rotating columns are rotationally arranged around the workbench, four rotating plates are fixedly arranged in the direction away from the workbench, four telescopic fixing blocks are slidably arranged on four rotating plates and four walls of the cutting box, a water pump is fixedly arranged at the upper end of the middle part of the interior of the workbench, a water pipe is fixedly arranged at the upper end of the water pump, and a clamping groove is formed in the lower end of the middle part of the interior of the workbench.

Preferably, the crushing component comprises a motor, the motor is located the storage and takes out the part upper end, the motor upper end has set firmly the linkage post, linkage connection on linkage post upper end is equipped with flexible linkage post, slide on the outer periphery that flexible linkage post is close to the upper end and be equipped with four fixture blocks, four fixture blocks are corresponding with the draw-in groove, four fixture block below slide on flexible linkage post and be equipped with the fixed plate, the flexible linkage post periphery of fixed plate lower extreme is equipped with the spring, the outer periphery lower extreme of fixed plate has set firmly four and has knocked down, it contains and is equipped with the connection right angle pole to knock down to set firmly at fixed plate outer periphery lower extreme, it is equipped with the axis of rotation to connect right angle pole lower extreme rotation, the axis of rotation lower extreme has set firmly the connecting rod, the connecting rod lower extreme has set firmly to knock down the post, it is equipped with the funnel to knock down to set, the funnel is fixed on four walls of cutting box.

Preferably, the rotary extrusion group is fixedly arranged on the outer circumferential surface of the linkage column below the funnel, the rotary extrusion group comprises eight first rotary rods, one ends of the eight first rotary rods, far away from the linkage column, are rotationally connected with eight first rotary shafts, first rolling shafts are fixedly arranged on the outer circumferential surface of the first rotary shafts, the eight first rotary rods are divided into two layers of four first rotary rods, the grinding group is arranged below the rotary extrusion group and is fixedly arranged on the outer circumferential surface of the linkage column, the grinding group comprises four second rotary rods, the four second rotary rods are fixedly arranged on the outer circumferential surface of the linkage column, one ends of the four second rotary rods, far away from the linkage column, are rotationally connected with four second rotary shafts, second rolling shafts are fixedly arranged on the outer circumferential surface of the four second rotary shafts, three third rotary shafts are rotationally connected with the lower ends of the second rotary rods, and three third rolling shafts are fixedly arranged on the outer circumferential surface of the three third rotary shafts.

Preferably, the first speed control disc is arranged on the outer circumferential surface of the linkage column in a linkage way below the funnel, the second speed control disc is arranged below the first speed control disc, the third speed control disc is arranged below the second speed control disc, the first speed control disc, the second speed control disc and the third speed control disc can move up and down and control the rotating speed on the outer circumferential surface of the linkage column, the first grinding cylinder is fixedly arranged on the outer circumferential surface of the first speed control disc, the second grinding cylinder is fixedly arranged on the outer circumferential surface of the second speed control disc, and the third grinding cylinder is fixedly arranged on the outer circumferential surface of the third speed control disc.

Preferably, a plurality of first discharge holes are uniformly formed in the circumferential wall of the first grinding cylinder, a plurality of first grinding convex blocks are fixedly arranged on the outer circumferential surface of the first grinding cylinder at the upper and lower parts of the first discharge holes, a plurality of second grinding convex blocks are uniformly arranged on the inner circumferential surface of the second grinding cylinder, the first grinding convex blocks and the second grinding convex blocks are matched to grind glass, a second discharge hole is formed between every two second grinding convex blocks, a plurality of anti-blocking groups are fixedly arranged at the lower end of the second grinding cylinder, each anti-blocking group comprises a telescopic seat, a telescopic column is slidably arranged at the lower end of the telescopic seat, a plurality of third discharge holes are arranged at the lower end of the inner part of the third grinding cylinder, and the third discharge holes are aligned with the telescopic column.

Preferably, the storage and taking-out part comprises a blanking plate, the blanking plate is positioned at the lower end of the crushing part, a blanking opening is formed in the blanking plate, a storage box is arranged at the lower end of the blanking plate, and a handle is fixedly arranged at one end of the storage box towards the outlet.

The beneficial effects are that:

1. the water and the glass slag are separated through the cooperation of the rotation of the workbench and the water pump, so that the recycling of the water and the glass slag is facilitated.

2. Grinding glass into powder by multiple grinding has been used to reproduce new glass by melting.

3. The large glass is crushed by the crushing group, so that the large glass is prevented from being clamped in the cutting box.

Drawings

The invention is further explained below with reference to the drawings and examples:

FIG. 1 is a flow chart of the method of the present invention.

FIG. 2 is a schematic view of an isometric structure of the present invention.

Fig. 3 is a schematic diagram of the front view structure of the present invention.

FIG. 4 is a schematic cross-sectional view of the structure at A-A in FIG. 3.

Fig. 5 is a partially enlarged structural schematic view at a in fig. 4.

Fig. 6 is a partially enlarged structural schematic diagram at B in fig. 4.

Fig. 7 is a schematic top view of the present invention.

FIG. 8 is a schematic cross-sectional view of the structure at D-D in FIG. 7.

Fig. 9 is a partially enlarged structural schematic view at C in fig. 8.

In the drawing the view of the figure, cutting box 1, cutting moving part 2, separating part 3, crushing part 4, storage and removal part 5, inlet 101, outlet 102, sliding door 103, first roller 201, second roller 202, first connection column 203, second connection column 204, chute 205, slider 206, circular plate 207, cutting column 208, mixing chamber 209, channel 210, high-pressure head 211, suction cup 212, air pump 213, suction pipe 214, air outlet 215, rotary column 216, telescopic rod 217, fixed column 218, table 301, rotary plate 302, telescopic fixed block 303, rotary column 304, water pump 305, water pipe 306, clamping groove 307, motor 401, linkage column 402, telescopic linkage column 403, clamping block 404, fixed plate 405, spring 406, breaking group 407, rotary plate the right angle lever 408, the rotation shaft 409, the connecting rod 410, the breaking column 411, the rotating extrusion group 412, the grinding group 413, the first speed control disk 414, the second speed control disk 415, the third speed control disk 416, the first grinding drum 417, the second grinding drum 418, the third grinding drum 419, the first rotation lever 420, the first rotation shaft 421, the first rotation shaft 422, the second rotation shaft 423, the second rotation shaft 424, the second rotation shaft 425, the third rotation shaft 426, the third rotation shaft 427, the first grinding bump 428, the first discharge port 429, the second grinding bump 430, the second discharge port 431, the third discharge port 432, the anti-blocking group 433, the telescopic seat 434, the telescopic column 435, the funnel 436, the blanking plate 501, the blanking port 502, the storage box 503, and the handle 504.

Detailed Description

The following are specific embodiments of the present invention and the technical solutions of the present invention will be further described with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

In the description of the present invention, it should be noted that, the azimuth or positional relationship indicated by the terms "inner", "lower", etc. are based on the azimuth or positional relationship shown in the drawings, or the azimuth or positional relationship that the inventive product is conventionally put in use, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific azimuth, be configured and operated in a specific azimuth, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance.

1-9, a glass production slag treatment method comprises the following steps:

s1, putting glass into a cutting box through an inlet;

s2, moving and fixing, namely moving the glass through a sucker, and fixing the glass through a rotating fixing block;

s3: cutting glass, namely fixing two sides of the glass, and cutting the glass;

s4: cleaning and removing, namely cleaning the surface of the glass by using a sucker, and sucking the glass by using the sucker and moving the glass out of the box body;

s5: separating, namely separating and absorbing glass slag and water generated in the cutting process, and keeping the water on a workbench for absorption, wherein the glass slag is thrown out and falls down in a rotating way;

s6: breaking glass, and breaking and dropping large glass into the grinding cylinder through the breaking component;

s7, multiple grinding, namely, grinding the glass slag for multiple times and then dropping the glass slag into a storage box;

s8: taking out, heating and melting the ground glass slag to produce new glass;

the steps S1-S8 are completed by adopting glass production cutting slag treatment equipment, the glass production cutting slag treatment equipment comprises a cutting box 1, an inlet 101 is formed in one side of the cutting box 1, a cutting moving part 2 is arranged on the rear side of the inlet 101 to conduct fixed cutting, moving and cleaning actions on glass, a separating part 3 is arranged below the cutting moving part 2 to separate glass slag from water, a crushing part 4 is arranged below the separating part 3 to crush large glass firstly and then conduct multiple grinding on the glass, a storage and taking-out part 5 is arranged below the crushing part 4 to store the ground glass, an outlet 102 is formed in one side of the crushing part 4, and a sliding door 103 is arranged in the sliding mode in the inlet 101.

Further, referring to fig. 4 and 8, the cutting moving member 2 includes a first roller 201, the first roller 201 is slidably connected to a side wall of the cutting box 1, the first roller 201 is provided with a second roller 202 in an inner direction of the cutting box 1, the second roller 202 is slidably connected to a side wall of the cutting box 1 far away from the first roller 201, one end of the first roller 201 in a direction of the second roller 202 is fixedly provided with a first connecting column 203, one end of the second roller 202 in a direction of the first roller 201 is fixedly provided with a second connecting column 204, a chute 205 is fixedly connected between the first connecting column 203 and the second connecting column 204, a slide block 206 is slidably provided in the chute 205, a circular plate 207 is fixedly provided at a lower end of the slide block 206, and a cutting column 208 is fixedly provided at a lower end of the circular plate 207.

Further, referring to fig. 4 and 8, a mixing cavity 209 is formed inside the slider 206, a high-pressure nozzle 211 is formed at the lower end of the cutting column 208, a channel 210 is connected between the high-pressure nozzle 211 and the mixing cavity 209, a sucking disc 212 is fixedly arranged on the periphery of the high-pressure nozzle 211, an air pump 213 is arranged on one side arc of the sucking disc 212, an air outlet pipe 215 is connected between the air pump 213 and the channel 210, an air suction pipe 214 is downwards arranged on the air pump 213 to perform suction action on glass, six rotary columns 216 are rotatably arranged on the wall of the cutting box 1 below the first roller 201 and the second roller 202, six telescopic rods 217 are fixedly arranged in the inner direction of the cutting box 1, and six fixing columns 218 are fixedly arranged in the direction of the cutting column 208 by the six telescopic rods 217.

Further, referring to fig. 4, the separating unit 3 includes a working table 301, the working table 301 is located below the cutting moving unit 2, four rotating columns 304 are rotationally arranged around the working table 301, four rotating plates 302 are fixedly arranged in the direction that the four rotating columns 304 are far away from the working table 301, four telescopic fixing blocks 303 are slidably arranged on four walls of the four rotating plates 302 and the cutting box 1, a water pump 305 is fixedly arranged at the upper end of the middle inside the working table 301, a water pipe 306 is fixedly arranged at the upper end of the water pump 305, and a clamping groove 307 is formed at the lower end of the middle inside the working table 301.

Further, referring to fig. 4, 5, 6, 8, and 9, the crushing member 4 includes a motor 401, the motor 401 is located at the upper end of the storage and taking member 5, a linkage column 402 is fixed at the upper end of the motor 401, a telescopic linkage column 403 is connected and provided at the upper end of the linkage column 402 in a linkage manner, four clamping blocks 404 are slidably provided on the outer circumference of the telescopic linkage column 403 near the upper end, the four clamping blocks 404 correspond to the clamping grooves 307, a fixing plate 405 is slidably provided on the telescopic linkage column 403 below the four clamping blocks 404, springs 406 are provided at the periphery of the telescopic linkage column 403 at the lower end of the fixing plate 405, four crushing groups 407 are fixed at the lower end of the outer circumference of the fixing plate 405, the crushing groups 407 include connection right angle rods 408, the connection right angle rods 408 are fixed at the lower end of the outer circumference of the fixing plate 405, a rotating shaft 409 is rotatably provided at the lower end of the connection right angle rods 408, a connecting rod 410 is fixed at the lower end of the rotating shaft 409, a crushing column 411 is fixed at the lower end of the connecting rod, a funnel 436 is provided below the crushing group 407, and the funnel 436 is fixed on four walls of the cutting box 1.

Further, referring to fig. 4, 5, 6, 8, and 9, a rotating extrusion group 412 is fixedly arranged on the outer circumferential surface of the linkage column 402 below the funnel 436, the rotating extrusion group 412 includes eight first rotating rods 420, one ends of the eight first rotating rods 420, which are far away from the linkage column 402, are rotatably connected with eight first rotating shafts 421, a first roller 422 is fixedly arranged on the outer circumferential surface of the first rotating shafts 421, the eight first rotating rods 420 are divided into two layers of four first rotating rods 420, a grinding group 413 is arranged below the rotating extrusion group 412, the grinding group 413 is fixed on the outer circumferential surface of the linkage column 402, the grinding group 413 includes four second rotating rods 423, the four second rotating rods 423 are fixed on the outer circumferential surface of the linkage column 402, one ends of the four second rotating rods 423, which are far away from the linkage column 402, are rotatably connected with four second rotating shafts 424, second roller 425 are fixedly arranged on the outer circumferential surface of the four second rotating shafts 424, three third rotating shafts 426 are rotatably connected with the lower ends of the second rotating rods 423, and three third rotating shafts 426 are fixedly arranged on the outer circumferential surface of the third roller 427.

Further, referring to fig. 4, 5, 6, 8 and 9, a first speed control disc 414 is arranged under the funnel 436 on the outer circumferential surface of the linkage column 402 in a linkage manner, a second speed control disc 415 is arranged under the first speed control disc 414, a third speed control disc 416 is arranged under the second speed control disc 415, the first speed control disc 414, the second speed control disc 415 and the third speed control disc 416 can move up and down and control the rotating speed on the outer circumferential surface of the linkage column 402, a first grinding cylinder 417 is fixedly arranged on the outer circumferential surface of the first speed control disc 414, a second grinding cylinder 418 is fixedly arranged on the outer circumferential surface of the second speed control disc 415, and a third grinding cylinder 419 is fixedly arranged on the outer circumferential surface of the third speed control disc 416.

Further, referring to fig. 4, 5, 6, 8 and 9, a plurality of first discharge holes 429 are uniformly formed in the circumferential wall of the first grinding barrel 417, a plurality of first grinding bumps 428 are fixedly arranged on the outer circumferential surface of the first grinding barrel 417 above and below the first discharge holes 429, a plurality of second grinding bumps 430 are uniformly arranged on the inner circumferential surface of the second grinding barrel 418, the first grinding bumps 428 and the second grinding bumps 430 cooperate to grind glass, a second discharge hole 431 is formed between every two of the second grinding bumps 430, a plurality of anti-blocking groups 433 are fixedly arranged at the lower end of the second grinding barrel 418, each anti-blocking group 433 comprises a telescopic seat 434, a telescopic column 435 is slidably arranged at the lower end of the telescopic seat 434, a plurality of third discharge holes 432 are arranged at the lower end of the inner part of the third grinding barrel 419, and the third discharge holes 432 are aligned with the telescopic column 435.

Further, referring to fig. 2 and 8, the storage and taking-out unit 5 includes a blanking plate 501, the blanking plate 501 is located at the lower end of the crushing unit 4, a blanking opening 502 is formed in the blanking plate 501, a storage box 503 is disposed at the lower end of the blanking plate 501, and a handle 504 is fixedly disposed at one end of the storage box 503 toward the outlet 102.

Principle of operation

S1, putting glass into the cutting box 1 through the inlet 101, sliding the sliding door 103 upwards to open, and sliding the sliding door 103 downwards to close.

S2, moving and fixing, wherein the first roller 201 and the second roller 202 are in sliding fit with the sliding block 206 in the cutting box 1 and slide in the sliding groove 205 to drive the cutting column 208 to move, the cutting column 208 can move on the horizontal plane at will, the glass is sucked up and moved to a specified position by the suction force of the sucking disc 212 and the air pump in the middle of the glass, the rotating column 216 rotates to drive the telescopic rod 217 to rotate, the telescopic rod 217 stretches and fixes according to the cutting position of the glass, and the fixing column 218 is matched with the workbench 301 to fix the glass.

S3: glass cutting, fixing the two sides of glass, enabling water and fine sand in the mixing cavity 209 to reach the upper end of the high-pressure spray head 211 through the channel 210, enabling the air pump 213 to give out air to the channel 210 through the air outlet pipe 215, enabling the mixture to be pressed out through the high-pressure spray head 211 to cut the glass by a water knife, enabling the cutting column 208 to carry out horizontal one-end cutting according to the size of glass cutting through the high-pressure spray head 211, and enabling the cut mixture to be closed in the mixing cavity 209 through the channel 210.

S4: the cleaning and removing are carried out, the air pump 213 is used for cleaning the surface of the glass from the high-pressure spray head 211 through the air outlet pipe 215, the air pump 213 is used for sucking the glass through the matching action of the air suction pipe 214 and the sucker 212, the sliding door 103 is opened in a sliding way, the glass is moved out of the box, and the sliding door 103 is closed in a sliding way.

S5: in the separation, the flexible linkage column 403 rises to clamp into the clamping groove 307, the clamping block 404 is drawn to correspond to the clamping groove 307, the flexible fixed block 303 slides into the movable plate 302, the rotary column 304 rotates to enable the movable plate 302 to rotate upwards, water and glass residues are gathered towards the middle, the water pump 305 absorbs the water on the workbench 301 through the water pipe 306 and is discharged out of the cutting box 1, the motor 401 starts to rotate through the linkage column 402 to drive the flexible linkage column 403 to rotate, the flexible linkage column 403 rotates to drive the workbench 301 to rotate through the clamping block 404, the glass residues are thrown out of the workbench 301 through the rotating centrifugal effect, fine sand is arranged on the workbench 301, separation is completed, fine sand on the workbench 301 is completely treated through the sucker 212, and the glass residues are thrown out and fall.

S6: broken glass, glass broken slag is thrown out and falls through the funnel 436, large glass blocks are clamped on the funnel 436, the telescopic linkage column 403 drives the breaking group 407 to rotate through the fixing plate 405, and then the fixing plate 405 moves up and down on the telescopic linkage column 403 to break and fall into the first grinding barrel 417 through the breaking column 411 in a rotating mode.

And S7, multiple grinding, wherein glass residues fall into a first grinding drum 417, the linkage column 402 rotates to drive the rotary extrusion group 412 and the grinding group 413 to rotate, the first rotary rod 420 on the rotary extrusion group 412 breaks the fallen glass, the third roller 427 and the second roller 425 of the grinding group 413 grind the glass residues, the ground glass enters the second grinding drum 418 through a first discharge hole 429, the first speed control disc 414 controls the first grinding drum 417 to rotate at the same height and at the same speed on the linkage column 402, the second speed control disc 415 controls the second grinding drum 418 to rotate at the same medium speed on the linkage column 402 and move up and down, the glass residues entering the second grinding drum 418 are ground up and down through the first grinding lug 428 and the second grinding lug 430 when being moved up and down by the second grinding drum 418, the ground glass residues enter the third grinding drum 419 through a second discharge hole 431, the third speed control disc 416 controls the third grinding drum to rotate at the same low speed and move up and down, the bottom surface 418 and the third grinding drum 418 are further matched with the third grinding drum 419 to perform a telescopic action on the third grinding drum 419, and the bottom surface of the third grinding drum 419 is further matched with the third grinding drum 432.

S8: taking out, namely, the ground glass scraps fall into a storage box 503 through a blanking opening 502, and the storage box 503 is pulled out at an outlet 102 through a handle 504 to heat and melt glass powder in the storage box 503 to produce new glass;

the foregoing description is only illustrative of the present invention and is not intended to limit the scope of the invention, and all equivalent structures or equivalent processes using the descriptions and the drawings of the present invention or directly or indirectly applied to other related technical fields are included in the scope of the invention.

Claims (1)

1. A method for treating broken slag in glass production, which is characterized by comprising the following steps:

s1, putting glass into a cutting box through an inlet;

s2, moving and fixing, namely moving the glass through a sucker, and fixing the glass through a rotating fixing block;

s3: cutting glass, namely fixing two sides of the glass, and cutting the glass;

s4: cleaning and removing, namely cleaning the surface of the glass by using a sucker, and sucking the glass by using the sucker and moving the glass out of the box body;

s5: separating, namely separating and absorbing glass slag and water generated in the cutting process, and keeping the water on a workbench for absorption, wherein the glass slag is thrown out and falls down in a rotating way;

s6: breaking glass, and breaking and dropping large glass into the grinding cylinder through the breaking component;

s7, multiple grinding, namely, grinding the glass slag for multiple times and then dropping the glass slag into a storage box;

s8: taking out, heating and melting the ground glass slag to produce new glass;

the method comprises the steps that S1-S8 are completed by adopting glass production cutting slag treatment equipment, the glass production cutting slag treatment equipment comprises a cutting box (1), an inlet (101) is formed in one side of the cutting box (1), a cutting moving component (2) is arranged on the rear side of the inlet (101) to fixedly cut, move and clean glass, a separating component (3) is arranged below the cutting moving component (2) to separate the glass slag from water, a crushing component (4) is arranged below the separating component (3), the crushing component (4) is used for crushing the glass and then carrying out multiple grinding on the glass, a storage and taking-out component (5) is arranged below the crushing component (4) and used for storing the ground glass, an outlet (102) is formed in one side of the storage and taking-out component (5), and a sliding door (103) is arranged in the inlet (101) in a sliding mode. The cutting moving part (2) comprises a first roller (201), the first roller (201) is connected to one side wall of the cutting box (1) in a sliding manner, a second roller (202) is arranged in the first roller (201) towards the inner direction of the cutting box (1), the second roller (202) is connected to one side wall of the cutting box (1) far away from the first roller (201) in a sliding manner, a first connecting column (203) is fixedly arranged at one end of the first roller (201) towards the second roller (202), a second connecting column (204) is fixedly arranged at one end of the second roller (202) towards the first roller (201), a sliding groove (205) is fixedly connected between the first connecting column (203) and the second connecting column (204), a sliding block (206) is arranged in the sliding groove (205), a round plate (207) is fixedly arranged at the lower end of the sliding block (206), and a cutting column (208) is fixedly arranged at the lower end of the round plate (207). The glass cutting device is characterized in that a mixing cavity (209) is formed in the sliding block (206), a high-pressure spray head (211) is arranged at the lower end of the cutting column (208), a channel (210) is connected between the high-pressure spray head (211) and the mixing cavity (209), a sucker (212) is fixedly arranged on the periphery of the high-pressure spray head (211), an air pump (213) is arranged on one side of the sucker (212), an air outlet pipe (215) is connected between the air pump (213) and the channel (210), an air suction pipe (214) is downwards arranged on the air pump (213) to perform suction action on the glass, six rotary columns (216) are rotationally arranged on the wall of the cutting box (1) below the first roller (201) and the second roller (202), six telescopic rods (217) are fixedly arranged in the direction of the inner side of the cutting box (1), and six fixed columns (218) are fixedly arranged in the direction of the cutting column (208); the separating component (3) comprises a workbench (301), the workbench (301) is located below the cutting moving component (2), four rotating columns (304) are rotationally arranged around the workbench (301), four rotating plates (302) are fixedly arranged in the direction away from the workbench (301) by the four rotating columns (304), four telescopic fixed blocks (303) are slidably arranged on the four rotating plates (302) and the four walls of the cutting box (1), a water pump (305) is fixedly arranged in the middle of the interior of the workbench (301), a water pipe (306) is fixedly arranged in the upper end of the water pump (305), and a clamping groove (307) is formed in the lower end of the middle of the interior of the workbench (301); the crushing part (4) comprises a motor (401), the motor (401) is positioned at the upper end of the storage and taking-out part (5), a linkage column (402) is fixedly arranged at the upper end of the motor (401), a telescopic linkage column (403) is connected and arranged at the upper end of the linkage column (402) in a linkage manner, four clamping blocks (404) are slidably arranged on the outer circumferential surface of the telescopic linkage column (403) close to the upper end, the four clamping blocks (404) correspond to the clamping grooves (307), a fixed plate (405) is slidably arranged on the telescopic linkage column (403) below the four clamping blocks (404), a spring (406) is fixedly arranged at the periphery of the telescopic linkage column (403) at the lower end of the outer circumferential surface of the fixed plate (405), four crushing groups (407) are fixedly arranged at the lower end of the outer circumferential surface of the fixed plate (405), a connecting right-angle rod (408) is fixedly arranged at the lower end of the outer circumferential surface of the fixed plate (405), a rotating shaft (409) is rotatably arranged at the lower end of the connecting right-angle rod (408), a hopper (410) is fixedly arranged at the lower end of the fixed hopper (411), and a plurality of hopper (410) is fixedly arranged at the lower end of the connecting rod (436), and a plurality of hopper (411) are fixedly arranged at the lower end of the hopper (410). The rotary extrusion device is characterized in that a rotary extrusion group (412) is fixedly arranged on the outer circumferential surface of a linkage column (402) below the funnel (436), the rotary extrusion group (412) comprises eight first rotary rods (420), one ends of the eight first rotary rods (420) are far away from the linkage column (402) and are rotationally connected with eight first rotary shafts (421), a first rolling shaft (422) is fixedly arranged on the outer circumferential surface of the first rotary rods (421), the eight first rotary rods (420) are divided into two layers of four first rotary rods (420), a grinding group (413) is arranged below the rotary extrusion group (412), the grinding group (413) is fixedly arranged on the outer circumferential surface of the linkage column (402), the grinding group (413) comprises four second rotary rods (423), the four second rotary rods (423) are fixedly arranged on the outer circumferential surface of the linkage column (402), one ends of the four second rotary rods (423) far away from the linkage column (402) are rotationally connected with four second rotary shafts (424), and the outer circumferential surface of the four second rotary shafts (426) is fixedly arranged on the outer circumferential surface of the four second rotary shafts (424), and the third rotary shafts (426) are fixedly arranged on the outer circumferential surface of the third rotary shafts (426); a first speed control disc (414) is arranged on the outer circumferential surface of the linkage column (402) below the funnel (436) in a linkage way, a second speed control disc (415) is arranged below the first speed control disc (414), a third speed control disc (416) is arranged below the second speed control disc (415), the first speed control disc (414), the second speed control disc (415) and the third speed control disc (416) can move up and down and control the rotating speed on the outer circumferential surface of the linkage column (402), a first grinding cylinder (417) is fixedly arranged on the outer circumferential surface of the first speed control disc (414), a second grinding cylinder (418) is fixedly arranged on the outer circumferential surface of the second speed control disc (415), and a third grinding cylinder (419) is fixedly arranged on the outer circumferential surface of the third speed control disc (416); a plurality of first discharge holes (429) are uniformly formed in the circumferential wall of the first grinding cylinder (417), a plurality of first grinding convex blocks (428) are fixedly arranged on the outer circumferential surface of the first grinding cylinder (417) above and below the first discharge holes (429), a plurality of second grinding convex blocks (430) are uniformly arranged on the inner circumferential surface of the second grinding cylinder (418), the first grinding convex blocks (428) and the second grinding convex blocks (430) are matched to grind glass, a second discharge hole (431) is formed between each two of the second grinding convex blocks (430), a plurality of anti-blocking groups (433) are fixedly arranged at the lower end of the second grinding cylinder (418), a telescopic seat (434) is arranged at the lower end of the telescopic seat (434) in a sliding mode, a plurality of third discharge holes (432) are formed in the inner lower end of the third grinding cylinder (419), and the third discharge holes (432) are aligned with the telescopic seat (435); the storage takes out part (5) including flitch (501), flitch (501) are located broken part (4) lower extreme, be equipped with feed opening (502) on flitch (501), flitch (501) lower extreme is equipped with storage box (503), storage box (503) set firmly handle (504) to export (102) one end.