CN115650555B - Defoaming and cooling device in float glass forming process - Google Patents

Abstract

The invention relates to the field of float glass production, in particular to a defoaming and cooling device in the float glass forming process, which comprises a reaction kettle, wherein a fixed plate and a bubbling tray are fixed on the reaction kettle, and a storage vat is also fixed on the reaction kettle, and is characterized in that the defoaming and cooling device in the float glass forming process further comprises: the stirring assembly is arranged in the reaction kettle; the piston cylinder is fixedly arranged on the reaction kettle, the piston cylinder is communicated with the bubbling tray through a guide pipe, a pumping mechanism connected with the stirring assembly is arranged on the reaction kettle, and the pumping mechanism comprises a pumping assembly and a piston movably arranged in the piston cylinder; the driven component is arranged on the fixed plate and connected with the stirring component, a discharging mechanism connected with the driven component is arranged in the storage barrel, and the discharging mechanism comprises a discharging component and a limiting wheel; the trigger mechanism is arranged in the reaction kettle and is connected with the stirring assembly.

Description

Defoaming and cooling device in float glass forming process

Technical Field

The invention relates to the field of float glass production, in particular to a defoaming and cooling device in the float glass forming process.

Background

Float glass is obtained by polishing molten glass on the surface of molten metal, and its advantages are high quality and yield and variety.

In order to meet the molding requirement, the glass production process can be divided into five stages, namely a silicate forming stage, a glass liquid clarifying stage, a glass liquid homogenizing stage and a glass liquid cooling stage, and can also be divided into a reaction sintering stage of a batch pile; silicate formation and its melt melting stage, mainly residual silica sand is dissolved in the formed silicate; the stage of clarifying and eliminating bubbles mainly reduces the supersaturation degree of various gases in the glass liquid; in the bubble removal process, the bubble removal method including bubbling, stirring, adding an antifoaming agent and the like is commonly used in the common glass production process, however, the methods are commonly used singly, so that the treatment effect is poor, and the operation flow is complex due to separate operations of defoaming and cooling, so that the production efficiency is reduced.

Disclosure of Invention

The invention aims to provide a defoaming and cooling device in the float glass forming process, so as to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions:

the utility model provides a defoaming cooling device in float glass shaping in-process, includes reation kettle, be fixed with fixed plate and bubble dish on the reation kettle, still be fixed with the storage vat that is used for holding the material on the reation kettle, its characterized in that, defoaming cooling device in the float glass shaping in-process still includes:

the stirring assembly is arranged in the reaction kettle and can stir materials in the reaction kettle;

the piston cylinder is fixedly arranged on the reaction kettle, the piston cylinder is communicated with the bubbling tray through a guide pipe, a pumping mechanism connected with the stirring assembly is arranged on the reaction kettle, the pumping mechanism comprises a pumping assembly and a piston movably arranged in the piston cylinder, and the pumping assembly can drive the piston to reciprocate in the piston cylinder and convey air into the bubbling tray through the guide pipe;

the driven component is arranged on the fixed plate and connected with the stirring component, a discharging mechanism connected with the driven component is arranged in the storage barrel, the discharging mechanism comprises a discharging component and limiting wheels which are symmetrically arranged, the discharging mechanism can drive the two limiting wheels to move close to or away from each other, and the driven component drives the discharging component to move through the limiting wheels so as to convey materials in the storage barrel into the reaction kettle;

the trigger mechanism is arranged in the reaction kettle and connected with the stirring assembly, and is used for controlling the working states of the pumping mechanism and the driven assembly.

As a further scheme of the invention: the stirring assembly comprises a motor fixedly mounted on the fixed plate, a transmission rod which is rotatably mounted between the fixed plate and the reaction kettle and is connected with an output shaft of the motor, a plurality of groups of stirring blades which are fixedly mounted on the transmission rod and are circumferentially equidistantly arranged, a movable sleeve is movably mounted on the transmission rod, the movable sleeve is connected with the pumping assembly, the driven assembly and the triggering mechanism, and threads are arranged in the middle section of the transmission rod.

As still further aspects of the invention: the pumping assembly comprises a first rotating rod which is rotatably arranged on the reaction kettle, a belt which is connected with the movable sleeve is sleeved on the first rotating rod, a limiting disc is fixed on the first rotating rod, a reciprocating structure which is connected with the limiting disc is arranged on the reaction kettle, and the reciprocating structure is fixedly connected with the piston and connected with the piston cylinder.

As still further aspects of the invention: the reciprocating structure comprises a movable rod movably mounted on the piston cylinder, a first spring abutted to the piston cylinder is sleeved on the movable rod, a fixed wheel is fixed on the movable rod, the fixed wheel is abutted to the limiting disc, and the movable rod is fixedly connected with the piston.

As still further aspects of the invention: the driven component comprises a first bevel gear fixedly arranged on the movable sleeve, a second rotating rod rotatably arranged on the fixed plate, and a second bevel gear fixedly arranged on the second rotating rod and meshed with the first bevel gear, wherein a cam is fixed on the second rotating rod, and the cam is in butt joint with the limiting wheel.

As still further aspects of the invention: the blanking assembly comprises a material guiding pipe fixedly arranged in the material storage barrel, the material guiding pipe is internally and movably provided with a blanking pipe penetrating through the material storage barrel, the material guiding pipe is internally and fixedly provided with a second spring fixedly connected with the blanking pipe, the reaction kettle is internally provided with an adjusting structure connected with the blanking pipe, and the adjusting structure is fixedly connected with the limiting wheel.

As still further aspects of the invention: the adjusting structure comprises a supporting plate fixedly installed on the blanking pipe, a sliding groove formed in the supporting plate, a blanking groove formed in the blanking pipe and a blanking groove formed in the material guiding pipe, a sliding piece connected with the supporting plate is arranged on the reaction kettle, and the sliding piece is fixedly connected with the limiting wheel.

As still further aspects of the invention: the sliding piece comprises a bidirectional screw rod rotatably mounted on the supporting plate, a first threaded sleeve which is symmetrically arranged is movably mounted on the bidirectional screw rod, a sliding block fixedly connected with the first threaded sleeve is slidably mounted in the sliding groove, the sliding block is fixedly connected with the limiting wheel, and the first threaded sleeve is in threaded fit with the bidirectional screw rod.

As still further aspects of the invention: the trigger mechanism comprises a second threaded sleeve movably mounted on the transmission rod, a guide disc fixedly mounted on the second threaded sleeve, and a fixed sleeve fixedly mounted on the fixed plate and symmetrically arranged, wherein a support rod movably connected with the fixed sleeve is fixed on the guide disc, and a limiting assembly connected with the guide disc is arranged on the reaction kettle.

As still further aspects of the invention: the limiting assembly comprises a hollow rod fixedly mounted on the movable sleeve, a limiting rod movably mounted in the hollow rod, and a limiting plate fixedly mounted on the limiting rod and matched with the guide plate, wherein the hollow rod is provided with a groove, a fixing ring clamped with the groove is fixed on the limiting rod, and a third spring abutted to the fixing ring is sleeved on the hollow rod.

Compared with the prior art, the invention has the beneficial effects that: this application can be under stirring assembly's effect, in carrying the bubbling dish through pumping mechanism, and carry to reation kettle in, thereby form big bubble in reation kettle, under the effect of big bubble, eliminate the little bubble that contains in the glass of molten state, simultaneously, under stirring assembly's effect, through driven component drive feed mechanism motion, make the material intermittent type in the feed mechanism carry to reation kettle in, the material in the storage vat is used for eliminating the bubble, under stirring assembly's effect, ensure to carry out comprehensive elimination to the bubble, stirring assembly still can drive trigger mechanism motion, and through trigger mechanism control feed mechanism and pumping mechanism's operating time.

Drawings

FIG. 1 is a schematic view of an embodiment of a defoaming cooling apparatus in a float glass forming process.

FIG. 2 is a schematic view of an alternative embodiment of a defoaming cooling apparatus during float glass forming.

FIG. 3 is a schematic view of a semi-sectional structure of one embodiment of a defoaming cooling apparatus in a float glass forming process.

Fig. 4 is an enlarged schematic view of the structure at a in fig. 3.

Fig. 5 is a schematic structural view of a blanking mechanism in an embodiment of a defoaming and cooling apparatus in a float glass forming process.

Fig. 6 is a schematic diagram of an exploded structure of a blanking mechanism in one embodiment of a defoaming and cooling apparatus in a float glass forming process.

Fig. 7 is a schematic diagram of an explosion structure of a part of a trigger mechanism, a movable sleeve and a first bevel gear in an embodiment of a defoaming and cooling device in a float glass forming process.

FIG. 8 is a schematic diagram of the connection of the trigger mechanism and a portion of the stirring assembly in one embodiment of the defoaming and cooling apparatus in a float glass forming process.

In the figure: 1. a reaction kettle; 2. a fixing plate; 3. a motor; 4. a transmission rod; 5. stirring the leaves; 6. a movable sleeve; 7. a belt; 8. a first rotating rod; 9. a limiting disc; 10. a piston cylinder; 11. a movable rod; 12. a fixed wheel; 13. a first spring; 14. a piston; 15. a conduit; 16. a bubbling tray; 17. a first bevel gear; 18. a two-size bevel gear; 19. a second rotating rod; 20. a cam; 21. a storage barrel; 22. a material guiding pipe; 23. a second spring; 24. discharging pipes; 25. a support plate; 26. a chute; 27. a two-way screw rod; 28. a first threaded sleeve; 29. a sliding block; 30. a limiting wheel; 31. a second threaded sleeve; 32. a guide plate; 33. a fixed sleeve; 34. a support rod; 35. a hollow rod; 36. a limit rod; 37. a third spring; 38. and a limiting plate.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In addition, an element in the present disclosure may be referred to as being "fixed" or "disposed" on another element or being directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

Referring to fig. 1 to 8, in the embodiment of the invention, a defoaming and cooling device in a float glass forming process comprises a reaction kettle 1, wherein a fixed plate 2 and a bubbling tray 16 are fixed on the reaction kettle 1, and a storage bucket 21 for containing materials is also fixed on the reaction kettle 1, and the defoaming and cooling device in the float glass forming process is characterized by further comprising:

stirring assembly sets up in the reation kettle 1, stirring assembly can be right the material stirs in the reation kettle 1, stirring assembly is including fixed mounting motor 3 on the fixed plate 2, rotation install fixed plate 2 with between the reation kettle 1 and with motor 3 output shaft's transfer line 4, fixed mounting are in on the transfer line 4 and be the multiunit stirring leaf 5 that circumference equidistance set up, movable mounting has movable sleeve 6 on the transfer line 4, movable sleeve 6 with the pumping subassembly with driven component and trigger mechanism connects, 4 middle sections of transfer line are provided with the screw thread.

Referring to fig. 1-3 and fig. 8, it should be noted that, when molten glass is placed in the reaction kettle 1, since bubbles are contained in the glass in this state, the glass can be stirred to remove the bubbles, at this time, the motor 3 works to drive the driving rod 4 to rotate, so as to drive the stirring blade 5 to rotate, and the glass is stirred under the action of the stirring blade 5, so that the bubbles are removed.

The piston cylinder 10 is fixedly installed on the reaction kettle 1, the piston cylinder 10 is communicated with the bubbling tray 16 through a guide pipe 15, a pumping mechanism connected with the stirring assembly is arranged on the reaction kettle 1, the pumping mechanism comprises a pumping assembly and a piston 14 movably installed in the piston cylinder 10, the pumping assembly can drive the piston 14 to reciprocate in the piston cylinder 10 and convey air into the bubbling tray 16 through the guide pipe 15, the pumping assembly comprises a first rotating rod 8 rotatably installed on the reaction kettle 1, a belt 7 connected with the movable sleeve 6 is sleeved on the first rotating rod 8, a limit tray 9 is fixed on the first rotating rod 8, a reciprocating structure connected with the limit tray 9 is arranged on the reaction kettle 1, the reciprocating structure is fixedly connected with the piston 14 and is connected with the piston cylinder 10, the reciprocating structure comprises a movable rod 11 movably installed on the piston cylinder 10, a first rotating rod 11 is sleeved with a first spring 10 and is abutted against the fixed wheel 11, and the first rotating rod 11 is abutted against the fixed wheel 11 and is fixedly connected with the fixed wheel 11.

Referring to fig. 1-3, further, a bubbling tray 16 is connected to a reaction kettle 1, two one-way valves are installed on a piston cylinder 10, one-way valve is connected to a conduit 15, the bubbling tray 16 is also provided with one-way valves, in order to remove bubbles in glass, large bubbles can be blown into glass, under the action of the large bubbles, small bubbles in glass are removed, a limiting tray 9 is obliquely arranged, in an initial state, a spring 13 is in a compressed state, so that a fixed wheel 12 is located at the end of travel far from the direction of the piston cylinder 10, the fixed wheel 12 is abutted against the limiting tray 9, at this time, a transmission rod 4 rotates to drive a movable sleeve 6 to rotate, so that a rotary rod 8 is driven to rotate by a belt 7, so that the limiting tray 9 rotates, under the action of the limiting tray 9, the fixed wheel 12 is driven to move towards the piston cylinder 10, the first spring 13 is compressed, the movable rod 11 is driven to move, the piston 14 moves in the piston cylinder 10, air in the piston cylinder 10 is conveyed into the bubbling tray 16 through the guide pipe 15, large bubbles are generated in the reaction kettle 1 under the action of the bubbling tray 16, small bubbles are removed under the action of the large bubbles, when the limiting tray 9 is separated from the fixed wheel 12, the first spring 13 is elastically released, the fixed wheel 12 is driven to be always abutted against the limiting tray 9, the piston 14 is driven to reset, the steps are repeated, the large bubbles are continuously blown into the reaction kettle 1, the glass can be cooled under the action of the large bubbles, and the glass is cooled while the small bubbles are removed.

The driven component is arranged on the fixed plate 2 and connected with the stirring component, and comprises a first bevel gear 17 fixedly arranged on the movable sleeve 6, a second rotating rod 19 rotatably arranged on the fixed plate 2, a second bevel gear 18 fixedly arranged on the second rotating rod 19 and meshed with the first bevel gear 17, a cam 20 is fixed on the second rotating rod 19, and the cam 20 is in butt joint with the limiting wheel 30.

Referring to fig. 1-3 and fig. 7-8, further, when the movable sleeve 6 rotates, the first bevel gear 17 is driven to rotate, so as to drive the second bevel gear 18 engaged with the first bevel gear to rotate, the second bevel gear 18 drives the second rotating rod 19 to rotate, and the cam 20 is driven to rotate, so that the discharging mechanism is driven to move by the limiting wheel 30, and the material in the material storage barrel 21 is intermittently conveyed into the reaction kettle 1.

The blanking mechanism connected with the driven component is arranged in the storage vat 21 and comprises a blanking component and limiting wheels 30 which are symmetrically arranged, the blanking mechanism can drive the two limiting wheels 30 to move close to or far away from each other, the driven component drives the blanking component to move through the limiting wheels 30 so as to convey materials in the storage vat 21 into the reaction kettle 1, the blanking component comprises a material guide pipe 22 fixedly arranged in the storage vat 21, a blanking pipe 24 penetrating through the storage vat 21 is movably arranged in the material guide pipe 22, a second spring 23 fixedly connected with the blanking pipe 24 is fixedly arranged in the material guide pipe 22, an adjusting structure connected with the blanking pipe 24 is arranged in the reaction kettle 1 and fixedly connected with the limiting wheels 30, the adjusting structure comprises a supporting plate 25 fixedly installed on the discharging pipe 24, a sliding groove 26 formed in the supporting plate 25, a discharging groove formed in the discharging pipe 24 and the discharging pipe 22, a sliding piece connected with the supporting plate 25 is arranged on the reaction kettle 1 and fixedly connected with a limiting wheel 30, the sliding piece comprises a bidirectional screw rod 27 rotatably installed on the supporting plate 25, a first threaded sleeve 28 symmetrically arranged is movably installed on the bidirectional screw rod 27, a sliding block 29 fixedly connected with the first threaded sleeve 28 is slidably installed in the sliding groove 26, the sliding block 29 is fixedly connected with the limiting wheel 30, and the first threaded sleeve 28 is in threaded fit with the bidirectional screw rod 27.

Referring to fig. 1-6, in an initial state, the second spring 23 is in a stretched state, the short shaft of the cam 20 is abutted against the limit wheel 30, so that the discharging tube 24 is located at the end of the travel in the material guiding tube 22, the two discharging grooves are in a separated state, the material in the material storage barrel 21 cannot be discharged, when the material needs to be conveyed, the cam 20 rotates, when the long shaft of the cam 20 is abutted against the limit wheel 30, the support plate 25 is driven to move in a direction away from the fixed plate 2 by the sliding block 29, so that the discharging tube 24 is driven to move in a direction away from the material guiding tube 22, the second spring 23 is stretched, when the discharging tube 24 moves to the end of the travel, the two discharging grooves are in a mutually connected state, the material in the material storage barrel 21 is conveyed into the reaction kettle 1 through the discharging tube 24, when the long shaft of the cam 20 is separated from the limit wheel 30, the second spring 23 is elastically contracted, and the discharging tube 24 is driven to move towards the material guiding tube 22, so that the two discharging grooves are in a separated state again, and the material in the material storage barrel 21 is not discharged any more, and the steps are repeated, thereby realizing intermittent conveying.

Preferably, in the initial state, the two limiting wheels 30 are at the end of the stroke close to each other, in order to control the conveying amount of the material, the distance between the two limiting wheels 30 is adjusted, at this time, the bidirectional screw rod 27 can be driven to rotate, so that the first threaded sleeve 28 is driven to move towards the direction away from each other, the sliding block 29 is driven to slide on the sliding groove 26, the two limiting wheels 30 are driven to move in the direction away from each other, at this time, under the action of the cam 20, the time for connecting the two blanking grooves is increased, and thus the blanking amount is increased.

The trigger mechanism is arranged in the reaction kettle 1 and is connected with the stirring assembly, the trigger mechanism is used for controlling the working state of the pumping mechanism and the driven assembly, the trigger mechanism comprises a second threaded sleeve 31 movably arranged on the transmission rod 4, a guide disc 32 fixedly arranged on the second threaded sleeve 31, a fixing sleeve 33 fixedly arranged on the fixing plate 2 and symmetrically arranged, a supporting rod 34 movably connected with the fixing sleeve 33 is fixed on the guide disc 32, a limiting assembly connected with the guide disc 32 is arranged on the reaction kettle 1, the limiting assembly comprises a hollow rod 35 fixedly arranged on the movable sleeve 6, a limiting rod 36 movably arranged in the hollow rod 35, a limiting plate 38 fixedly arranged on the limiting rod 36 and matched with the guide disc 32, a groove is formed in the hollow rod 35, a fixing ring clamped with the groove is fixedly arranged on the limiting rod 36, and a third spring 37 abutted to the fixing ring is sleeved on the hollow rod 35.

Referring to fig. 1-3 and 7-8, finally, the second threaded sleeve 31 and the driving rod 4 are threaded to form a threaded fit state, in an initial state, the second threaded sleeve 31 is located at the end of the travel far away from the movable sleeve 6, the driving rod 4 is provided with a limit hole, in an initial state, the third spring 37 is in a compressed state, the limit rod 36 penetrates through the movable sleeve 6 and is clamped with the limit hole, when the driving rod 4 rotates, under the action of the limit rod 36 and the limit hole, the movable sleeve 6 is driven to rotate, meanwhile, when the driving rod 4 rotates, the second threaded sleeve 31 is driven to move by threads and the guide disc 32 is driven to move, the guide disc 32 is provided with an annular inclined groove matched with the limit plate 38, under the action of the guide disc 32, the supporting rod 34 is driven to move towards the inside of the fixed sleeve 33, and the supporting rod 34 has a guiding effect, the second threaded sleeve 31 moves along the length direction of the transmission rod 4, the guide plate 32 moves towards the limit plate 38, the limit plate 38 is obliquely arranged towards one side of the guide plate 32, when an annular oblique groove formed on the guide plate 32 is abutted against the oblique surface of the limit plate 38, the limit plate 38 is driven to move away from the transmission rod 4 and the limit rod 36 is driven to move away from the limit hole, so that the fixing ring is driven to move along the length direction of the groove, the third spring 37 is compressed, when the limit rod 36 moves to a position separated from the limit hole, the limit plate 38 moves to the stroke end at the moment, the transmission rod 4 rotates, the movable sleeve 6 is not driven to rotate any more, the bubbling plate 16 is not bubble, the material is not conveyed by the storage barrel 21 any more, the transmission rod 4 continues to rotate for a period of time, after ensuring that the material conveyed by the storage vat 21 is uniformly stirred and removing bubbles in the glass, the motor 3 stops working, wherein when the movable sleeve 6 is not rotated any more, the short shaft of the cam 20 is abutted with the limiting wheel 30.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (8)

1. The utility model provides a defoaming cooling device in float glass shaping in-process, includes reation kettle (1), be fixed with fixed plate (2) and bubbling dish (16) on reation kettle (1), still be fixed with on reation kettle (1) and be used for holding storage vat (21) of material, its characterized in that, defoaming cooling device in the float glass shaping in-process still includes:

the stirring assembly is arranged in the reaction kettle (1) and can stir materials in the reaction kettle (1);

the piston cylinder (10) is fixedly arranged on the reaction kettle (1), the piston cylinder (10) is communicated with the bubbling tray (16) through a guide pipe (15), a pumping mechanism connected with the stirring assembly is arranged on the reaction kettle (1), the pumping mechanism comprises a pumping assembly and a piston (14) movably arranged in the piston cylinder (10), the pumping assembly can drive the piston (14) to reciprocate in the piston cylinder (10), and air is conveyed into the bubbling tray (16) through the guide pipe (15);

the driven component is arranged on the fixed plate (2) and connected with the stirring component, a discharging mechanism connected with the driven component is arranged in the storage barrel (21), the discharging mechanism comprises a discharging component and limiting wheels (30) which are symmetrically arranged, the discharging mechanism can drive the two limiting wheels (30) to move close to or away from each other, and the driven component drives the discharging component to move through the limiting wheels (30) so as to convey materials in the storage barrel (21) into the reaction kettle (1);

the trigger mechanism is arranged in the reaction kettle (1) and connected with the stirring assembly, and is used for controlling the working states of the pumping mechanism and the driven assembly;

the stirring assembly comprises a motor (3) fixedly arranged on the fixed plate (2), a transmission rod (4) rotatably arranged between the fixed plate (2) and the reaction kettle (1) and connected with an output shaft of the motor (3), a plurality of groups of stirring blades (5) fixedly arranged on the transmission rod (4) and arranged at equal intervals in circumference, a movable sleeve (6) is movably arranged on the transmission rod (4), the movable sleeve (6) is connected with the pumping assembly, the driven assembly and the triggering mechanism, and threads are arranged in the middle section of the transmission rod (4);

the trigger mechanism comprises a second threaded sleeve (31) movably mounted on the transmission rod (4), a guide disc (32) fixedly mounted on the second threaded sleeve (31), and a fixed sleeve (33) fixedly mounted on the fixed plate (2) and symmetrically arranged, wherein a supporting rod (34) movably connected with the fixed sleeve (33) is fixed on the guide disc (32), and a limiting assembly connected with the guide disc (32) is arranged on the reaction kettle (1).

2. The defoaming and cooling device in the float glass forming process according to claim 1, wherein the pumping assembly comprises a first rotating rod (8) rotatably installed on the reaction kettle (1), a belt (7) connected with the movable sleeve (6) is sleeved on the first rotating rod (8), a limiting disc (9) is fixed on the first rotating rod (8), a reciprocating structure connected with the limiting disc (9) is arranged on the reaction kettle (1), and the reciprocating structure is fixedly connected with the piston (14) and connected with the piston cylinder (10).

3. The defoaming and cooling device in the float glass forming process according to claim 2, wherein the reciprocating structure comprises a movable rod (11) movably mounted on the piston cylinder (10), a first spring (13) abutted to the piston cylinder (10) is sleeved on the movable rod (11), a fixed wheel (12) is fixed on the movable rod (11), the fixed wheel (12) is abutted to the limiting disc (9), and the movable rod (11) is fixedly connected with the piston (14).

4. The defoaming and cooling device in a float glass forming process according to claim 1, wherein the driven assembly comprises a first bevel gear (17) fixedly mounted on the movable sleeve (6), a second rotating rod (19) rotatably mounted on the fixed plate (2), and a second bevel gear (18) fixedly mounted on the second rotating rod (19) and meshed with the first bevel gear (17), a cam (20) is fixed on the second rotating rod (19), and the cam (20) is abutted with the limiting wheel (30).

5. The defoaming and cooling device in the float glass forming process according to claim 1, wherein the blanking component comprises a material guiding pipe (22) fixedly installed in the material storage barrel (21), a blanking pipe (24) penetrating through the material storage barrel (21) is movably installed in the material guiding pipe (22), a second spring (23) fixedly connected with the blanking pipe (24) is fixedly installed in the material guiding pipe (22), and an adjusting structure connected with the blanking pipe (24) is arranged in the reaction kettle (1) and fixedly connected with the limiting wheel (30).

6. The defoaming and cooling device in a float glass forming process according to claim 5, wherein the adjusting structure comprises a supporting plate (25) fixedly installed on the blanking pipe (24), a sliding groove (26) formed in the supporting plate (25), a blanking groove formed in the blanking pipe (24) and the guiding pipe (22), and a sliding piece connected with the supporting plate (25) is arranged on the reaction kettle (1) and fixedly connected with the limiting wheel (30).

7. The defoaming and cooling device in a float glass forming process according to claim 6, wherein the sliding piece comprises a bidirectional screw rod (27) rotatably mounted on the supporting plate (25), a first threaded sleeve (28) symmetrically arranged is movably mounted on the bidirectional screw rod (27), a sliding block (29) fixedly connected with the first threaded sleeve (28) is slidably mounted in the sliding groove (26), the sliding block (29) is fixedly connected with the limiting wheel (30), and the first threaded sleeve (28) is in threaded fit with the bidirectional screw rod (27).

8. The defoaming and cooling device in the float glass forming process according to claim 1, wherein the limiting assembly comprises a hollow rod (35) fixedly installed on the movable sleeve (6), a limiting rod (36) movably installed in the hollow rod (35), and a limiting plate (38) fixedly installed on the limiting rod (36) and matched with the guide disc (32), the hollow rod (35) is provided with a groove, a fixed ring clamped with the groove is fixed on the limiting rod (36), and a third spring (37) abutted with the fixed ring is sleeved on the hollow rod (35).