CN113387595B - Hollow glass brick treatment process - Google Patents

Abstract

The invention belongs to the field of glass brick processing, and particularly relates to a hollow glass brick processing technology which is completed by matching hollow glass brick processing equipment, wherein the hollow glass brick processing equipment comprises a shell, a working cavity with an opening at one side is arranged in the shell, a cylinder wall is embedded on the inner wall of the working cavity far away from the opening, a piston rod is arranged in the cylinder wall in a sliding manner, a sucking disc is fixedly arranged at the opening end of the piston rod, a water guide pipe and a water inlet pipe are fixedly arranged in the opening of the shell close to the working cavity, plaster spraying mechanisms are arranged on the cylinder wall, four ethylene spraying mechanisms are uniformly arranged at the opening of the working cavity in a ring shape, four eliminating mechanisms are uniformly arranged in the shell in a ring shape, four control mechanisms are uniformly arranged on the sucking disc in a ring shape close to the side wall end of the working cavity, and four openings of the water guide pipe are respectively communicated with the four ethylene spraying mechanisms, the casing is provided with an annular transmission groove with an opening facing the working cavity, the ethylene spraying mechanism, the eliminating mechanism and the control mechanism are all in corresponding directions, and the ethylene and the plaster can be effectively prevented from being thrown off from the glass brick by the process and the equipment.

Description

Hollow glass brick treatment process

Technical Field

The invention belongs to the field of glass brick processing, and particularly relates to a hollow glass brick processing technology.

Background

The glass brick is a block-shaped or hollow box-shaped glass product which is formed by pressing transparent or colored glass material, has a larger body shape, can be used as a structural material, and can be used as a wall body, a screen, a partition and the like.

Disclosure of Invention

The invention aims to solve the problems in the prior art and provides a hollow glass brick treatment process capable of accurately coating liquid ethylene and plaster on the side surface of a glass brick.

In order to achieve the purpose, the invention adopts the following technical scheme:

preferably, the hollow glass brick treatment process is completed by matching the following hollow glass brick treatment equipment, and the hollow glass brick treatment equipment comprises a shell, wherein a working cavity with an opening at one side is arranged in the shell, a cylinder wall is embedded on the inner wall of the working cavity far away from the opening, a piston rod is arranged in the cylinder wall in a sliding manner, a sucker is fixedly arranged at the opening end of the piston rod, a water guide pipe and a water inlet pipe are fixedly arranged in the opening part of the shell close to the working cavity, plaster spraying mechanisms are arranged on the cylinder wall, four ethylene spraying mechanisms are uniformly and annularly arranged at the opening part of the working cavity, four eliminating mechanisms are uniformly and annularly arranged in the shell, four control mechanisms are uniformly and annularly arranged at the end of the sucker close to the side wall of the working cavity, and four openings of the water guide pipe are respectively communicated with the four ethylene spraying mechanisms, the ethylene spraying mechanism, the eliminating mechanism and the control mechanism are all in corresponding directions.

Preferably, the plaster spraying mechanism comprises a threaded gear in threaded connection with the cylinder wall, a supporting plate is arranged on the cylinder wall in a sliding mode, the side, far away from the rotating shaft, of the supporting plate is annularly and uniformly connected to the inner wall of the first return spring through four first return springs, a plaster pipe is fixedly arranged on the side wall, close to the working cavity, of the threaded gear, and a plaster spray head is fixedly arranged on the other side of the plaster pipe.

Preferably, the ethylene spraying mechanism comprises a button groove and an ethylene groove which are arranged on the side wall of the working cavity close to the opening and have an opening facing the working cavity, the ethylene groove is closer to the opening of the working cavity than the button groove, the opening of the ethylene groove is fixedly provided with an atomizing nozzle, a water inlet pipe is arranged in the button groove in a sliding manner, the water inlet pipe is connected to the inner wall of the button groove through a second return spring, a sliding groove with an opening facing the button groove is arranged in the opening of the shell close to the working cavity, the sliding groove corresponds to the button groove, a sliding rod is arranged in the sliding groove in a sliding manner, one end of the sliding rod is fixed on the water inlet pipe, the other end of the sliding rod is fixedly provided with a supporting rod close to the working cavity side, the other end of the supporting rod is fixedly provided with a sealing block, and the sealing block is arranged on the inner wall, close to the aqueduct, of the ethylene groove in a sealing and sliding mode.

Preferably, control mechanism includes opening that is equipped with on the sucking disc is towards the spout of shell, it is equipped with the kicking block to slide in the spout, the kicking block passes through the third reset spring to be connected on the inner wall of spout, the sucking disc is close to the working chamber is close to the mouth side and is equipped with the spacing groove that runs through, the spacing inslot is close to the working chamber is close to the mouth side and slides and be equipped with the pressing block, the spacing inslot is close to the spout side slides and be equipped with the bolt, the bolt with the pressing block links together through coupling spring, the pressing block is connected through two fourth reset spring about the slot symmetry on the spacing groove is close to on the inner wall of spout, be equipped with the opening on the kicking block and lean on the slot of mouth side towards the working chamber, the kicking block shrink advance behind the spout the slot with the bolt is corresponding.

Preferably, the elimination mechanism includes the pipe that absorbs water that sets up in the shell, the intraductal fixed clarifier that is equipped with of absorbing water, the clarifier passes through the drain pipe accesss to outside the shell, the one end of the pipe that absorbs water is close to the inlet tube, and the opening is to the working chamber.

Preferably, the elimination mechanism is still including rotating to be established axis of rotation and windmill axle on the drive groove inner wall, the axis of rotation compare in windmill axle is close to the working chamber, still be equipped with the negative pressure chamber in the shell, the negative pressure chamber is located the drive groove with between the pipe absorbs water, just the pipe intercommunication absorbs water the working chamber with the negative pressure chamber, windmill axle is close to one side in negative pressure chamber is stretched negative pressure intracavity, and the fixed windmill that is equipped with, the fixed driving gear that is equipped with in the axis of rotation, the last fixed driven gear that is equipped with of windmill axle, driven gear with the driving gear meshing is connected, the driving gear is kept away from driven gear side meshing is connected on the screw gear.

Preferably, the hollow glass brick molding process by adopting the hollow glass brick molding equipment comprises the following steps:

s1: detecting, wherein the prepared glass brick is detected manually;

s2: the sub-stations are used for placing the qualified glass bricks in different work stations manually for the next processing;

s3: fixing the glass bricks to a carrier, and fixing the glass bricks by the suckers through vacuum suction after the glass bricks are conveyed to the suckers;

s4: spraying ethylene, driving the glass brick to slide towards the cylinder wall by the sucker, pressing the water inlet pipe by the ejector block in the process, and spraying the ethylene in the water guide pipe through the atomizing nozzle until the ejector block passes through the water inlet pipe, so that the ethylene is just sprayed on the side surface of the glass brick;

s5: spraying plaster, wherein when the suction disc presses the threaded gear, the rotation of the threaded gear drives the plaster spray head to rotate, so that plaster is uniformly sprayed on the side surface of the glass brick;

s6: reset, after the glass brick spraying has finished plaster, the sucking disc resets, takes away the glass brick on the sucking disc, and after the glass brick on the sucking disc was taken away, the kicking block slided out from the spout, continued work.

Has the advantages that: the ejector block slides through the water inlet pipe to enable the atomizing nozzle to just spray the side face of the glass brick, and the ethylene is prevented from being sprayed outside the glass brick to cause pollution.

When the suction cup is pressed against the rotating shaft, the plaster spray head is just flush with the side edge of the glass brick, so that the plaster spray head can just spray plaster on the side surface of the glass brick, and plaster is prevented from being sprayed on the main surface of the glass brick.

The negative pressure cavity generates negative pressure, the residual ethylene in the working cavity is sucked into the purifier through the water suction pipe, and the ethylene is purified by the purifier and then is discharged through the water discharge pipe.

Drawings

FIG. 1 is a schematic diagram of a structural embodiment of the present invention;

FIG. 2 is a schematic view taken along the line A-A in FIG. 1;

FIG. 3 is a schematic view of the direction B-B in FIG. 1;

FIG. 4 is an enlarged view of FIG. 1 at C;

fig. 5 is an enlarged schematic view of fig. 4 at D.

In the drawings, a housing 10; a working chamber 11; a first return spring 12; a pallet 13; a screw gear 14; a rotating shaft 15; a driven gear 16; a drive gear 17; a windmill shaft 18; a drain pipe 19; a purifier 20; a stucco tube 22; a stucco spray head 23; a suction pipe 24; a suction cup 25; a piston rod 26; a negative pressure chamber 27; a windmill 28; a transmission groove 29; a cylinder wall 30; a water introduction pipe 31; a water inlet pipe 32; a top block 33; a third return spring 34; a chute 35; a water inlet pipe 36; a button slot 37; a second return spring 38; a slide groove 39; a slide bar 40; a support bar 41; a sealing block 42; an atomizing head 43; an ethylene tank 44; a slot 45; a fourth return spring 46; a limit groove 47; a pressing block 48; a connecting spring 49; a latch 50; a stucco spray mechanism 90; an ethylene spraying mechanism 91; a control mechanism 92; the cancellation mechanism 93.

Detailed Description

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

In the description of the present invention, it should be noted that the terms "inside", "below", and the like refer to orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention conventionally place when used, and are used only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

Further, with reference to fig. 1, a hollow glass brick treatment process is completed by matching the following hollow glass brick treatment equipment, and the hollow glass brick treatment equipment comprises a shell 10, a working chamber 11 with an opening on one side is arranged in the shell 10, a cylinder wall 30 is embedded on the inner wall of the working chamber 11 far away from the opening, a piston rod 26 is arranged in the cylinder wall 30 in a sliding manner, a suction cup 25 is fixedly arranged at the opening end of the piston rod 26, a water guide pipe 31 and a water inlet pipe 36 are fixedly arranged in the opening of the shell 10 close to the working chamber 11, a plaster spraying mechanism 90 is arranged on the cylinder wall 30, four ethylene spraying mechanisms 91 are uniformly arranged in a ring shape at the opening of the working chamber 11, four eliminating mechanisms 93 are uniformly arranged in the ring shape in the shell 10, four control mechanisms 92 are uniformly arranged in a ring shape at the end of the suction cup 25 close to the side wall of the working chamber 11, four openings of the water guide pipe 31 are respectively communicated with the four ethylene spraying mechanisms 91, the housing 10 is provided with an annular transmission groove 29 which is opened towards the working chamber 11, and the ethylene spraying mechanism 91 and the eliminating mechanism 93 correspond to the control mechanism 92 in direction.

Further, referring to fig. 1 and 3, the plaster spraying mechanism 90 includes a threaded gear 14 threaded on the cylinder wall 30, a support plate 13 is slidably disposed on the cylinder wall 30, the support plate 13 is annularly and uniformly connected to the inner wall of the first return spring 12 through four first return springs 12 on the side far away from the rotating shaft 15, a plaster pipe 22 is fixedly disposed on the side wall of the threaded gear 14 close to the working chamber 11, and a plaster nozzle 23 is fixedly disposed on the other side of the plaster pipe 22.

Further, referring to fig. 1 and 4, the ethylene spraying mechanism 91 includes a button groove 37 and an ethylene groove 44, which are provided on a side wall of the working chamber 11 near the opening and have an opening facing the working chamber 11, the ethylene groove 44 is closer to the opening of the working chamber 11 than the button groove 37, an atomizing nozzle 43 is fixedly provided at the opening of the ethylene groove 44, a water inlet pipe 32 is slidably provided in the button groove 37, the water inlet pipe 32 is connected to an inner wall of the button groove 37 through a second return spring 38, a sliding groove 39 having an opening facing the button groove 37 is provided in the housing 10 near the opening of the working chamber 11, the sliding groove 39 corresponds to the button groove 37, a sliding rod 40 is slidably provided in the sliding groove 39, one end of the sliding rod 40 is fixed to the water inlet pipe 32, a support rod 41 is fixedly provided at a side of the other end of the sliding rod 40 near the working chamber 11, a seal block 42 is fixedly provided at another end of the support rod 41, and the seal block 42 is slidably provided on an inner wall of the ethylene groove 44 near the aqueduct 31.

Further, with reference to fig. 5, the control mechanism 92 includes the sliding groove 35, which is provided with an opening on the suction cup 25 and faces the housing 10, the sliding groove 35 is provided with a top block 33 in the sliding groove 35, the top block 33 is connected to the inner wall of the sliding groove 35 through a third return spring 34, the suction cup 25 is provided with a through limiting groove 47 near the opening side of the working chamber 11, the limiting groove 47 is provided with a pressing block 48 near the opening side of the working chamber 11 in a sliding manner, the limiting groove 47 is provided with a bolt 50 near the sliding groove 35 in a sliding manner, the bolt 50 is connected with the pressing block 48 through a connecting spring 49, the pressing block 48 is connected to the inner wall of the limiting groove 47 near the sliding groove 35 through two fourth return springs 46 which are symmetrical with respect to the slot 45, the top block 33 is provided with a slot 45, which is provided with an opening facing the opening side of the working chamber 11, and the slot 45 corresponds to the bolt 50 after the top block 33 contracts into the sliding groove 35.

Further, referring to fig. 1, the eliminating mechanism 93 includes a suction pipe 24 disposed in the housing 10, a purifier 20 is fixedly disposed in the suction pipe 24, the purifier 20 is led out of the housing 10 through a drain pipe 19, and one end of the suction pipe 24 is close to the water inlet pipe 32 and opens into the working chamber 11.

Further, with reference to fig. 1, the eliminating mechanism 93 further includes a rotating shaft 15 and a windmill shaft 18 rotatably disposed on the inner wall of the transmission groove 29, the rotating shaft 15 is closer to the working chamber 11 than the windmill shaft 18, a negative pressure chamber 27 is further disposed in the housing 10, the negative pressure chamber 27 is located between the transmission groove 29 and the water suction pipe 24, the water suction pipe 24 communicates the working chamber 11 and the negative pressure chamber 27, one side of the windmill shaft 18 close to the negative pressure chamber 27 extends into the negative pressure chamber 27 and is fixedly provided with a windmill 28, a driving gear 17 is fixedly disposed on the rotating shaft 15, a driven gear 16 is fixedly disposed on the windmill shaft 18, the driven gear 16 is in meshing connection with the driving gear 17, and the side of the driving gear 17 far from the driven gear 16 is in meshing connection with the threaded gear 14.

Further, the hollow glass brick molding process by adopting the hollow glass brick molding equipment comprises the following steps:

s1: detecting, wherein the prepared glass brick is detected manually;

s2: the sub-stations are used for placing the qualified glass bricks in different work stations manually for the next processing;

s3: fixing the glass bricks to the carrier, and after the glass bricks are conveyed to the suction cups 25, fixing the glass bricks by the suction cups 25 through vacuum suction;

s4: spraying ethylene, wherein the sucker 25 drives the glass brick to slide towards the cylinder wall 30, the water inlet pipe 32 is pressed through the top block 33 in the process, and the ethylene in the water guide pipe 31 is sprayed out through the atomizing nozzle 43 until the top block 33 passes through the water inlet pipe 32, so that the ethylene is just sprayed on the side surface of the glass brick;

s5: spraying plaster, when the suction disc 25 presses the screw gear 14, the rotation of the screw gear 14 drives the plaster spray head 23 to rotate, so that the plaster is uniformly sprayed on the side surface of the glass brick;

s6: resetting, after the plaster is sprayed on the glass bricks, the suction cup 25 resets to take away the glass bricks on the suction cup 25, and after the glass bricks on the suction cup 25 are taken away, the top block 33 slides out of the sliding groove 35 to continue working.

Initial state: the first return spring 12 is in a normal state, the third return spring 34 is in a normal state, the second return spring 38 is in a normal state, the fourth return spring 46 and the connecting spring 49 are in a normal state, and the piston rod 26 is in an extended state.

The working principle is as follows: the glass brick is absorbed by the sucking disc 25, the pressing block 48 and the bolt 50 slide to the chute 35, the fourth return spring 46 is compressed, the piston rod 26 is contracted to drive the sucking disc 25 to move, the water inlet pipe 32 is pushed to slide to the chute 39 after the top block 33 pushes against the water inlet pipe 32, the second return spring 38 is compressed, the slide rod 40 is driven to interact simultaneously, the water guide pipe 31 is opened, liquefied ethylene in the water guide pipe 31 is uniformly sprayed on the side surface of the glass brick through the atomizing nozzle 43, the atomizing nozzle 43 just finishes spraying the side surface of the glass brick after the top block 33 slides through the water inlet pipe 32 to prevent ethylene from being sprayed outside the glass brick to cause pollution, the second return spring 38 restores to drive the water inlet pipe 32, the slide rod 40 and the sealing block 42 to reset after the top block 33 slides through the water inlet pipe 32, the sealing block 42 seals the opening of the water guide pipe 31 to prevent ethylene from being continuously sprayed, the shell 10 pushes the top block 33 into the chute 35 after the top block 33 slides through the water inlet pipe 32, the third return spring 34 is compressed, the jacking block 33 pushes the bolt 50 to slide towards the pressing block 48 in the sliding process of the jacking block 33, the connecting spring 49 is compressed, when the bolt 50 corresponds to the slot 45, the connecting spring 49 recovers to press the bolt 50 into the slot 45, the cylinder wall 30 is prevented from being pressed out of the chute 35 by the third return spring 34, the suction cup 25 is stopped by the water inlet pipe 32 when being reset and cannot be normally reset, the mortar spray head 23 is just flush with the side edge of the glass brick when the suction cup 25 pushes the rotating shaft 15, so that the mortar spray head 23 can just spray mortar on the side surface of the glass brick to prevent the mortar from being sprayed on the main surface of the glass brick, after pushing the rotating shaft 15, the rotating shaft 15 is pushed to slide towards the inner wall of the working chamber 11 while rotating, the first return spring 12 is compressed to drive the mortar pipe 22 and the mortar spray head 23 to rotate, so that the mortar spray head 23 sprays mortar on the side wall of the glass brick, during the process of spraying plaster by the plaster sprayer 23, the screw gear 14 drives the driven gear 16 through the driving gear 17, the driven gear 16 drives the windmill 28 to rotate, negative pressure is generated in the negative pressure cavity 27, residual ethylene in the working cavity 11 is sucked into the purifier 20 through the water suction pipe 24, the ethylene is purified by the purifier 20 and then is discharged through the water discharge pipe 19, after the plaster spraying on the side surface of the glass brick is finished, the piston rod 26 extends out of the cylinder wall 30 and is recovered by the first return spring 12, the supporting plate 13 and the screw gear 14 are driven to be recovered until the sucking disc 25 is recovered, after the glass brick is taken away from the sucking disc 25, the fourth return spring 46 is recovered, the pressing block 48 and the bolt 50 are driven to be recovered, the bolt 50 is pulled out of the slot 45, and the third return spring 34 is recovered to drive the top block 33 to be recovered, and the spraying of the next glass brick is continued.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (7)

1. The utility model provides a hollow glass brick processing technology, this hollow glass brick processing technology adopts following hollow glass brick processing equipment cooperation to accomplish, this hollow glass brick processing equipment, including shell (10), be equipped with one side open-ended working chamber (11) in shell (10), inlay on the open-ended inner wall is kept away from in working chamber (11) and be equipped with cylinder wall (30), it is equipped with piston rod (26) to slide in cylinder wall (30), piston rod (26) are located the fixed sucking disc (25) that are equipped with of open end, its characterized in that: the automatic cleaning device is characterized in that a water guide pipe (31) and a water inlet pipe (36) are fixedly arranged in an opening of the shell (10) close to the working cavity (11), plaster spraying mechanisms (90) are arranged on the cylinder wall (30), four ethylene spraying mechanisms (91) are annularly and uniformly arranged at the opening of the working cavity (11), four eliminating mechanisms (93) are annularly and uniformly arranged in the shell (10), four control mechanisms (92) are annularly and uniformly arranged at the end, close to the side wall of the working cavity (11), of the sucking disc (25), four openings of the water guide pipe (31) are respectively communicated with the four ethylene spraying mechanisms (91), an annular transmission groove (29) with an opening facing the working cavity (11) is formed in the shell (10), and the directions of the ethylene spraying mechanisms (91) and the eliminating mechanisms (93) correspond to the control mechanisms (92).

2. The hollow glass block treatment process according to claim 1, wherein: the plaster spraying mechanism (90) comprises a threaded gear (14) which is in threaded connection with the cylinder wall (30), a supporting plate (13) is arranged on the cylinder wall (30) in a sliding mode, the side, far away from the rotating shaft (15), of the supporting plate (13) is evenly connected to the inner wall of the first return spring (12) through four first return springs (12) in an annular mode, a plaster pipe (22) is fixedly arranged on the side wall, close to the working cavity (11), of the threaded gear (14), and a plaster spray head (23) is fixedly arranged on the other side of the plaster pipe (22).

3. The hollow glass block treatment process according to claim 1, wherein: ethylene spraying mechanism (91) includes opening that working chamber (11) lateral wall is close to the opening part and is equipped with towards button groove (37) and ethylene groove (44) of working chamber (11), ethylene groove (44) compare in button groove (37) are closer to the opening in working chamber (11), the fixed atomizer (43) that is equipped with of opening part in ethylene groove (44), it is equipped with inlet tube (32) to slide in button groove (37), inlet tube (32) are connected through second reset spring (38) on the inner wall in button groove (37), shell (10) are close to be equipped with opening towards sliding tray (39) of button groove (37) in working chamber (11) opening part, sliding tray (39) with button groove (37) are corresponding, it is equipped with slide bar (40) to slide in sliding tray (39), the one end of slide bar (40) is fixed on inlet tube (32), the other end of slide bar (40) is close to working chamber (11) side is fixed and is equipped with bracing piece (41), the other end of bracing piece (41) is fixed and is equipped with sealed piece (42), sealed slip of sealed piece (42) is established ethylene groove (44) is close to on the inner wall of aqueduct (31).

4. The hollow glass block treatment process according to claim 1, wherein: control mechanism (92) include opening that is equipped with on sucking disc (25) is towards spout (35) of shell (10), it is equipped with kicking block (33) to slide in spout (35), kicking block (33) are connected through third reset spring (34) on the inner wall of spout (35), sucking disc (25) are close to working chamber (11) are close to mouthful side and are equipped with spacing groove (47) that run through, be close to in spacing groove (47) working chamber (11) are close to mouthful side and slide and be equipped with and press briquetting (48), be close to in spacing groove (47) spout (35) side is slided and is equipped with bolt (50), bolt (50) with press briquetting (48) to link together through coupling spring (49), be equipped with opening towards slot (45) that working chamber (11) are close to mouthful side on kicking block (33), press briquetting (48) through two about fourth reset spring (46) of slot (45) symmetry are connected spacing groove (47) are close to spacing groove (47) are by On the inner wall of the near sliding groove (35), the slot (45) corresponds to the bolt (50) after the top block (33) is contracted into the sliding groove (35).

5. The hollow glass block treatment process according to claim 1, wherein: eliminate mechanism (93) and include suction tube (24) that set up in shell (10), suction tube (24) internal fixation is equipped with clarifier (20), clarifier (20) lead to through drain pipe (19) outside shell (10), the one end of suction tube (24) is close to inlet tube (32), and the opening is to working chamber (11).

6. The hollow glass block treatment process according to claim 2, wherein: eliminating mechanism (93) still including rotating to be established axis of rotation (15) and windmill shaft (18) on transmission groove (29) inner wall, axis of rotation (15) compare in windmill shaft (18) are close to working chamber (11), still be equipped with negative pressure chamber (27) in shell (10), negative pressure chamber (27) are located between transmission groove (29) and suction pipe (24), just suction pipe (24) intercommunication working chamber (11) with negative pressure chamber (27), windmill shaft (18) are close to one side of negative pressure chamber (27) is stretched in negative pressure chamber (27), and fixed windmill (28) that are equipped with, fixed driving gear (17) that are equipped with on axis of rotation (15), fixed driven gear (16) that are equipped with on windmill shaft (18), driven gear (16) with driving gear (17) meshing is connected, the driving gear (17) is meshed with the threaded gear (14) at the side far away from the driven gear (16).

7. A hollow glass block treatment process according to any of claims 1 to 6, characterized in that:

the hollow glass brick forming process by adopting the hollow glass brick forming equipment comprises the following steps:

s1: detecting, wherein the prepared glass brick is detected manually;

s2: the sub-stations are used for placing the qualified glass bricks in different work stations manually for the next processing;

s3: fixing the glass bricks to the carrier, and after the glass bricks are conveyed to the sucking discs (25), fixing the glass bricks by the sucking discs (25) through vacuum suction;

s4: spraying ethylene, wherein the glass brick is driven by the sucking disc (25) to slide towards the cylinder wall (30), the water inlet pipe (32) is pressed by the top block (33) in the process, and the ethylene in the water guide pipe (31) is sprayed out through the atomizing nozzle (43) until the top block (33) passes through the water inlet pipe (32), so that the ethylene is just sprayed on the side surface of the glass brick;

s5: spraying plaster, when the suction disc (25) presses the screw gear (14), the screw gear (14) rotates to drive the plaster spray head (23) to rotate, so that the plaster is uniformly sprayed on the side surface of the glass brick;

s6: resetting, after the plaster is sprayed on the glass bricks, resetting the suction disc (25), taking the glass bricks on the suction disc (25) away, and after the glass bricks on the suction disc (25) are taken away, sliding the top block (33) out of the sliding groove (35) to continue working.

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