CN113402158A

CN113402158A - Building glass homogenizing furnace

Info

Publication number: CN113402158A
Application number: CN202110578232.5A
Authority: CN
Inventors: 刘献永; 马可文
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-05-26
Filing date: 2021-05-26
Publication date: 2021-09-17

Abstract

The invention relates to the technical field of glass production devices, in particular to a building glass homogenizing furnace, which comprises a furnace body, a support frame, a filter box body, a driving box body, a communicating pipe, a circulating fan and a heating box, wherein the circulating fan is fixedly connected at the center of the top end of the furnace body, the filter box body is fixedly connected on the outer side walls of the front end and the rear end of the furnace body, the filter box body is positioned at the two sides of the front end and the rear end of the furnace body, the filter box body is communicated with the circulating fan through the communicating pipe, the bottom end of the filter box body is fixedly communicated with the top end of the driving box body, the bottom end of the driving box body is fixedly communicated with the top end of the heating box, and the bottom end of the heating box is fixedly communicated with a gas conveying pipe. The convection effect of the upper part in the glass is enhanced, and the temperature uniformity of the glass is improved.

Description

Building glass homogenizing furnace

Technical Field

The invention relates to the technical field of glass production devices, in particular to a building glass homogenizing furnace.

Background

In the process of carrying, storing, installing and using the building glass, a small amount of products can be subjected to self-explosion without external force, mainly because nickel sulfide stones exist in the glass, when the nickel sulfide stones are subjected to phase transition in the glass, the volume of the nickel sulfide stones expands, microcracks are generated around the nickel sulfide stones, when the microcracks enter a tensile stress area, the glass can be subjected to spontaneous explosion, in order to solve the problem, the nickel sulfide finishes crystal phase transition before leaving a factory by heating the glass in a homogenizing furnace and preserving the heat for a certain time, the glass which is likely to be subjected to spontaneous explosion is detonated and broken in advance in the factory, and the heat treatment technology for the glass is called as homogenizing treatment.

In the prior patent (publication number: CN103265167B), a toughened glass homogenizing furnace comprises a box-type furnace body and a control device, wherein a furnace chamber in the box-type furnace body is connected with a glass frame for fixing toughened glass sheets in a sliding way through a rail, the front end of the box-type furnace body is provided with an opening-closing furnace door for sealing the furnace chamber, one end of the rail extends out of the furnace door, two heating chambers are arranged at two sides of the furnace chamber, a heat circulation air inlet is arranged at the transverse bottom surface of a transverse expansion cavity, an axial flow fan is arranged at the top of the furnace body, heated air flows from bottom to top through the heat circulation air inlet and a heat circulation air outlet, and then the heated air enters the heating chambers to circularly heat and then flows up and down, so that the whole space in the furnace chamber is fully utilized, and the glass sheets on the glass frame can be detected in a temperature field with uniform temperature.

However, the invention is suitable for plate glass in actual use, but when facing arc glass, the upward flowing air flow is easily blocked by the bottom end of the glass, which will affect the actual air convection effect and easily cause the temperature distribution of the arc glass sheet to be uneven, and because the air outlet is arranged at the bottom end, which will cause the convection effect at the bottom end of the glass to be stronger than that at the top end, resulting in a larger temperature difference between the top and bottom of the glass.

Therefore, the building glass homogenizing furnace is provided.

Disclosure of Invention

The invention aims to provide a building glass homogenizing furnace, which can change the distribution of nozzles at the bottom end according to the radian of glass, so that air flow sprayed by the nozzles can just pass through a gap between the glass to ensure that air convection cannot be blocked by the bottom end of the glass, and simultaneously, a side blowing mechanism is used for blowing air to the upper part of the glass to enhance the convection effect of the upper part of the glass, so that the upper part and the lower part of the glass are ensured to have better convection effect, and the temperature distribution of the upper part and the lower part of the glass is ensured to be more uniform, so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a building glass homogenizing furnace comprises a furnace body, a support frame, a filter box body, a driving box body, a communicating pipe, a circulating fan and a heating box, wherein the circulating fan is fixedly connected to the center of the top end of the furnace body, the filter box body is fixedly connected to the outer side walls of the front end and the rear end of the furnace body, the filter box body is positioned on the two sides of the front end and the rear end of the furnace body, the filter box body is communicated with the circulating fan through the communicating pipe, the bottom end of the filter box body is fixedly communicated with the top end of the driving box body, the bottom end of the heating box body is fixedly communicated with a gas pipe, a homogenizing cavity is formed in the furnace body, a sliding groove is formed in the bottom wall of the homogenizing cavity, a plurality of nozzles are connected in the sliding groove in a sliding mode, one end, far away from the heating box, of the gas pipe penetrates through the outer side wall of the furnace body and extends into the homogenizing cavity, one end of the gas pipe, which is positioned in the homogenizing cavity, is fixedly communicated with a plurality of spray heads, the support frame is connected to the bottom wall of the homogenizing cavity in a sliding manner, transmission cavities are formed in the left side and the right side of the bottom wall of the homogenizing cavity, a tooth condition is connected in the transmission cavities in a sliding manner, the front end and the rear end of one side, which is close to the center of the furnace body, of the rack piece are respectively connected with a connecting gear in a meshing manner, the top end of the connecting gear is fixedly connected with a connecting rod, the support frame is provided with a detection mechanism, the connecting rod, which is positioned on the right side of the rear end, is in transmission connection with the detection mechanism in a transmission manner, the connecting rod penetrates through the top wall of the transmission cavity and extends into the homogenizing cavity to be fixedly connected with a side blowing mechanism, one side of the side blowing mechanism, which is close to the side wall of the homogenizing cavity, is in transmission connection with a transmission mechanism in a transmission manner, one end, which is far away from the side blowing mechanism, penetrates through the homogenizing cavity and extends into the driving box body, the transmission device comprises a plurality of transmission gears, wherein the transmission gears are distributed along the direction that the center of the rack piece is close to two ends, the radiuses of the transmission gears are gradually reduced, the center of each transmission gear is fixedly connected with a transmission rod, the transmission rod penetrates through the side wall of a transmission cavity, extends to the inner wall of a sliding groove and is in threaded connection with a spray head, and threads with opposite textures are distributed on the two sides of the center of the transmission rod in the circumferential direction;

the gear condition consists of a first rack and a second rack, the first rack is fixedly connected with the second rack, the axes of the first rack and the second rack are arranged in parallel, one side of the first rack close to the center of the bottom wall of the transmission cavity is meshed with the connecting gear, and the top end of the second rack is meshed with the transmission gear;

when the upper laminar flow type homogenizing furnace and the lower laminar flow type homogenizing furnace face the cambered surface glass, the upward flowing air flow is easily blocked by the bottom end of the glass, so that the actual air convection effect is influenced, and the temperature distribution of the cambered surface glass sheet is easily uneven;

when the detection mechanism works, the radian of the cambered glass can be detected by the detection mechanism, when the support frame is pushed into the homogenizing cavity, the detection mechanism rotates through the connecting rod in transmission connection with the detection mechanism, the rotating connecting rod enables the first rack to move through the connecting gear, the first rack drives the plurality of transmission gears to rotate through the second rack fixedly connected with the first rack, due to the fact that the radiuses of the plurality of transmission gears are different, when the rack moves for the same distance, the number of rotating circles of the plurality of transmission gears is different, further, the number of rotating circles of the plurality of transmission rods fixedly connected with the transmission gears is different, the transmission rods drive the spray heads in threaded connection with the transmission rods to move left and right along the axis of the transmission rods, due to the fact that the number of rotating circles of the different transmission rods is different, further, the moving distances of the spray heads in threaded connection with the different transmission rods are different, and finally, the plurality of spray heads are distributed in an arc shape, the air current of shower nozzle spun can pass through the clearance between the glass just, and it is poor to avoid the air cycle effect that the air current of shower nozzle spun is blockked by the glass bottom and leads to, and the condition such as glass uneven distribution takes place.

Preferably, the support frame consists of a frame body, rollers, support rods and fixing strips, the rollers are provided with a plurality of rollers which are fixedly connected with the bottom end of the frame body, the bottom wall of the chute is provided with a slide way, the rollers are connected in the slide way in a rolling manner, the support rods and the fixing strips are fixedly connected in the frame body, the fixing strips are provided with two fixing strips which are symmetrically arranged at two sides of the support rods, the fixing strips are rotatably connected with a plurality of limiting blocks, the top ends of the limiting blocks are provided with fixing grooves, the middle part of the frame body is fixedly connected with a support plate, the detection mechanism consists of a transmission rack, a driving rack, a rotating gear, a steering gear, a connecting strip, a threaded rod and a turntable, the fixing strips are internally provided with through grooves, the transmission rack is slidably connected inside the through grooves, the bottom ends of the limiting blocks penetrate through the top walls of the through grooves and extend into the through grooves to be fixedly connected with the rotating gear, the rotating gear is meshed with the transmission rack, a plurality of connecting strips are arranged at the rear end of the fixing strip, the rear end of each connecting strip is fixedly connected with the rear end of the transmission rack, the rear end of each connecting strip is fixedly connected with the front end of the corresponding driving rack, the driving racks are meshed with the steering gears, the steering gears are fixedly connected with the connecting rods, the driving racks are slidably connected with the rear end side walls of the frame body, the threaded rod penetrates through the left side walls of the transmission racks and is in threaded connection with the transmission racks, the threaded rod is in rotating connection with the left side walls of the through grooves, and the left sides of the threaded rods are fixedly connected with the rotary table;

when the cambered glass fixing device works, the cambered glass can be fixed through the fixing groove at the top end of the limiting block, when the cambered glass is faced with glasses with different radians, the rotary disc needs to rotate to drive the threaded rod to rotate, the threaded rod can drive the transmission rack to move, the transmission rack can realize the rotation of the limiting block through the rotating gear, the direction of the fixing groove is changed, and the direction of the fixing groove is fixed for the glasses with different radians through the fixing groove; and when facing the glass of different radians, the position of the transmission rack at this moment is different for the through groove, the transmission rack at this moment will make the position of drive rack different through the connecting strip, and when the support frame is pushed into the homogeneity intracavity, and move to slide extreme position in-process, the drive rack will make the steering gear rotate, and when facing the glass of different radians, because the position of drive rack for the support frame is different, and then realize that the drive rack makes the number of turns of steering gear rotation different, the steering gear will make the connecting rod rotate different numbers of turns, and then the connecting rod will make rack spare remove different distances through the connecting gear, and then when guaranteeing the glass of facing different radians, a plurality of shower nozzles will present different arc distributions, and then guarantee to adapt to the glass of different radians.

Preferably, the left end and the right end of the sliding chute are fixedly connected with fixed blocks, one side of each fixed block, which is close to the sliding chute, is fixedly connected with a blocking sleeve, one side of each blocking sleeve, which is close to a spray head, is fixedly connected with the spray heads, and a connecting plate is fixedly connected between every two adjacent spray heads;

when the glass is detonated, part of glass can be detonated in advance, so when the glass is detonated, part of glass scraps can fall into the chute, the glass scraps can block the chute and can influence the movement of the spray head;

during operation, can realize blockking to the spout through the fixed plate and avoid the glass piece to fall into the spout from between the shower nozzle, it can avoid the glass piece to enter into the spout from the clearance between spout both ends and the shower nozzle to block the sleeve inside, and block sleeve self and can play certain deformation effect, and then when the shower nozzle that the shower nozzle is located both ends and the distance between the spout both ends changes, it still can realize avoiding the glass piece to enter into inside the spout through the deformation of self to block the sleeve.

Preferably, the side blowing mechanism comprises a blowing shell, a rotating fan, a driving shaft, a worm wheel and supporting blocks, wherein the supporting blocks are provided with a plurality of supporting blocks which are fixedly connected to the side walls of the front end and the rear end of the homogenizing cavity, the top end of the connecting rod penetrates through the supporting blocks and is rotatably connected with the supporting blocks, the blowing shell is positioned at the top end of the supporting blocks and is fixedly connected with the connecting rod, the rotating fan is provided with a plurality of supporting blocks which are rotatably connected to one side of the blowing shell, which is far away from the side wall of the homogenizing cavity, a connecting cavity is formed in the blowing shell, one side of the rotating fan, which is close to the blowing shell, penetrates through the side wall of the blowing shell and extends into the connecting cavity to be fixedly connected with the worm wheel, the driving shaft is positioned in the connecting cavity and is rotatably connected with the side walls on the left side and the right side of the connecting cavity, the driving shaft is meshed with the worm wheels, and the meshed connection position of the driving shaft and the worm wheel is of a worm structure;

because the air outlet is arranged at the bottom end, the convection effect at the bottom end of the glass is stronger than that at the top end, and because the smoothness between the cambered surface glass is weaker than that between the plane glass, the temperature difference between the upper part and the lower part of the glass is larger;

the during operation, drive mechanism will realize the drive to the drive shaft, and then the drive shaft will drive the worm wheel and rotate, and the worm wheel will drive and rotate the fan and rotate, and then realize blowing to the middle and upper side of glass, strengthen the convection current effect at middle and upper position in the glass, and then ensure that glass upper and lower part all has better convection current effect, and then ensure that glass upper and lower part temperature distribution is comparatively even.

Preferably, the transmission mechanism comprises a transmission shaft, a wind wheel, a connecting shaft, a first bevel gear, a second bevel gear and a universal joint, the wind wheel is arranged inside the driving box body and is rotatably connected into the driving box body through the transmission shaft, one side of the transmission shaft, which is close to the furnace body, penetrates through the furnace body and extends into the homogenizing cavity to be in transmission connection with the connecting shaft through the universal joint, one end, far away from the universal joint, of the connecting shaft penetrates through and extends into the connecting cavity to be fixedly connected with the first bevel gear, the second bevel gear is fixedly connected with the driving shaft, and the first bevel gear is in meshing connection with the second bevel gear;

when the fan is rotated to blow air only from the side surface of the glass, due to the characteristic that the glass is an arc surface, more air flow is blocked by the glass and is difficult to enter between the glass, so that the enhancement of the convection effect of the upper part in the glass cannot reach the expected target;

when in work, when the glass with different radians is arranged on the supporting frame, the detection mechanism can lead the rotating rod to rotate by different angles, thereby realizing that the rotating rod at the moment can drive the blowing shell to rotate, leading the airflow blown out by the rotating fan to be tangent with the side surface of the glass, thereby ensuring that the air flow can well enter between the glasses and improving the air circulation speed between the glasses, in the process, the airflow entering the driving box body from the filtering box body drives the wind wheel to rotate, the wind wheel drives the transmission shaft to rotate, the transmission shaft drives the connecting shaft to rotate through the universal joint, the connecting shaft drives the driving shaft to rotate through the first bevel gear and the second bevel gear, and then realize the drive to rotating the fan, and at the pivoted in-process of blowing the casing, the universal joint can ensure to keep the transmission effect between transmission shaft and the connecting axle all the time.

Preferably, a filter cavity is formed in the filter box body, a heating rod is fixedly connected in the filter cavity, the communicating pipe is communicated with the bottom end of the filter cavity, water is filled in the filter cavity, a connecting pipe is fixedly connected in the filter cavity, the top end of the connecting pipe is positioned above the liquid level, and the bottom end of the connecting pipe penetrates through the bottom wall of the filter cavity and is communicated with the drive box body;

the glass in the homogenizing chamber is broken, so that the air in the homogenizing chamber drives the glass dust, when the glass dust is accumulated too much, a pipeline is blocked, the rotation of the wind wheel in the driving box body is influenced, and the glass dust adhered to the surface of the glass is also adhered to the surface of the glass along with the circulation of the air, so that the uniformity of the glass temperature is influenced;

the during operation, the inside air that enters into the filter chamber will contact with water, and then realize the glass dust of detached air, and realize the heating to water through the heating rod, avoid water to absorb a large amount of heats in the air, and the in-process can increase the content of the vapor in the air, and then realize improving the specific heat capacity of air, and then when the air passes and circulates between the glass, glass is slower at the temperature decline of circulating in-process self, avoid appearing because air self specific heat capacity is less, when the air is from lower to last circulation, the air carries out the heat exchange with articles such as glass, make the temperature decline of air self faster, the difference in temperature that leads to the not co-altitude air is great, and then the circumstances such as the difference in temperature that leads to the not co-altitude glass is bigger take place.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, by arranging the monitoring mechanism, the transmission rod, the transmission gear, the spray heads and other mechanisms, when facing glass with different radians, the positions of the spray heads can be changed, so that the plurality of spray heads are distributed in an arc shape, and further the plurality of spray heads can change the distribution of the spray heads along with the change of the radians of the glass, so that air flow sprayed by the spray heads can just pass through gaps among the glass, and the conditions of poor air circulation effect, uneven glass distribution and the like caused by the fact that the air flow sprayed by the spray heads is blocked by the bottom end of the glass are avoided;

2. the rotating fan can blow air to the upper side face of the glass through the side blowing mechanism and the transmission mechanism, blown air flow is tangent to the side face of the glass, the air flow can well enter the space between the glass and can improve the air circulation speed between the glass, the upper portion and the lower portion of the glass are guaranteed to have good convection effect, and the temperature distribution of the upper portion and the lower portion of the glass is guaranteed to be uniform.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a sectional view taken along line A-A of FIG. 1;

FIG. 3 is an enlarged view of the structure at B in FIG. 2;

FIG. 4 is a top cross-sectional view of the present invention;

FIG. 5 is a cross-sectional view taken along line C-C of FIG. 4;

FIG. 6 is a radial cross-sectional view of a fixation bar in accordance with the present invention;

figure 7 is a top cross-sectional view of a blower housing of the present invention.

In the figure: 1. a furnace body; 101. a homogenizing chamber; 102. a chute; 103. a transmission cavity; 104. a slideway; 2. a support frame; 201. a frame body; 202. a roller; 203. a support bar; 204. a fixing strip; 205. a limiting block; 206. a support plate; 207. a through groove; 208. grooving; 209. fixing grooves; 3. a filter box body; 301. a filter chamber; 302. a heating rod; 303. a connecting pipe; 4. a driving box body; 5. a communicating pipe; 6. a circulating fan; 7. a heating box; 8. a gas delivery pipe; 9. a spray head; 10. tooth condition; 1001. a first rack; 1002. a second rack; 11. a connecting gear; 12. a connecting rod; 13. a detection mechanism; 1301. a drive rack; 1302. a drive rack; 1303. a rotating gear; 1304. a steering gear; 1305. a connecting strip; 1306. a threaded rod; 1307. a turntable; 14. a side blowing mechanism; 1401. a blower housing; 1402. rotating the fan; 1403. a drive shaft; 1404. a worm gear; 1405. a support block; 1406. a connecting cavity; 15. a transmission mechanism; 1501. a drive shaft; 1502. a wind wheel; 1503. a connecting shaft; 1504. a first bevel gear; 1505. a second bevel gear; 1506. a universal joint; 16. a transmission gear; 17. a transmission rod; 18. a connecting plate; 19. a fixed block; 20. blocking the sleeve.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 to 7, the present invention provides a technical solution:

a building glass homogenizing furnace is shown in figures 1 to 5 and comprises a furnace body 1, a support frame 2, a filter box body 3, a driving box body 4, a communicating pipe 5, a circulating fan 6 and a heating box 7, wherein the circulating fan 6 is fixedly connected to the center of the top end of the furnace body 1, the filter box body 3 is fixedly connected to the outer side walls of the front end and the rear end of the furnace body 1, the filter box body 3 is positioned on the two sides of the front end and the rear end of the furnace body 1, the filter box body 3 is communicated with the circulating fan 6 through the communicating pipe 5, the bottom end of the filter box body 3 is fixedly communicated with the top end of the driving box body 4, the bottom end of the driving box body 4 is fixedly communicated with the top end of the heating box 7, the bottom end of the heating box 7 is fixedly communicated with a gas pipe 8, a homogenizing chamber 101 is arranged in the furnace body 1, a sliding groove 102 is arranged on the bottom wall of the homogenizing chamber 101, a plurality of nozzles 9 are slidably connected in the sliding groove 102, one end of the gas pipe 8, which is far away from the heating box 7, penetrates through the outer side wall of the furnace body 1 and extends into the homogenizing chamber 101, one end of the gas pipe 8, which is positioned in the homogenizing chamber 101, is fixedly communicated with a plurality of spray heads 9, the support frame 2 is slidably connected on the bottom wall of the homogenizing chamber 101, transmission chambers 103 are arranged inside the left side and the right side of the bottom wall of the homogenizing chamber 101, tooth conditions 10 are slidably connected in the transmission chambers 103, the front end and the rear end of one side, which is close to the center of the furnace body 1, of the tooth conditions 10 are respectively connected with a connecting gear 11 in a meshing manner, the top end of the connecting gear 11 is fixedly connected with a connecting rod 12, the support frame 2 is provided with a detection mechanism 13, the connecting rod 12, which is positioned on the right side of the rear end, is in transmission connection with the detection mechanism 13, the connecting rod 12 penetrates through the top wall of the transmission chamber 103 and extends into the homogenizing chamber 101 to be fixedly connected with a side blowing mechanism 14, one side of the side wall of the homogenizing chamber 101 is in a transmission connection with a transmission mechanism 15, one end, far away from the side blowing mechanism 14, of the transmission mechanism 15 penetrates through the homogenizing cavity 101 and extends into the driving box body 4, the top end of the tooth condition 10 is connected with a plurality of transmission gears 16 in a meshed mode, the radiuses of the transmission gears 16 are gradually reduced and distributed along the direction, close to the two ends, of the center of the tooth condition 10, the centers of the transmission gears 16 are fixedly connected with transmission rods 17, the transmission rods 17 penetrate through the side wall of the transmission cavity 103 and extend to the inner wall of the sliding groove 102 and are in threaded connection with the spray head 9, and threads with opposite textures are circumferentially distributed on the two sides of the center of each transmission rod 17;

the gear rack 10 consists of a first rack 1001 and a second rack 1002, the first rack 1001 is fixedly connected with the second rack 1002, the axes of the first rack 1001 and the second rack 1002 are arranged in parallel, one side of the first rack 1001 close to the center of the bottom wall of the transmission cavity 103 is meshed with the connecting gear 11, and the top end of the second rack 1002 is meshed with the transmission gear 16;

during operation, the detection mechanism 13 can detect the radian of the arc-shaped glass, and when the support frame 2 is pushed into the homogenizing chamber 101, the detection mechanism 13 will rotate through the connecting rod 12 in transmission connection therewith, the rotating connecting rod 12 will make the first rack 1001 move through the connecting gear 11, the first rack 1001 will drive the plurality of transmission gears 16 to rotate through the second rack 1002 fixedly connected therewith, because the radiuses of the plurality of transmission gears 16 are different, when the tooth condition 10 moves the same distance, the number of rotating turns of the plurality of transmission gears 16 is different, and further, the number of rotating turns of the plurality of transmission rods 17 fixedly connected with the transmission gears 16 is different, as shown in fig. 5, when the transmission rods 17 rotate, the transmission rods 17 will drive the spray heads 9 in threaded connection therewith to move left and right along the axial direction of the transmission rods 7, and because the number of rotating turns of the different transmission rods 17 is different, and then realize different with the shower nozzle 9 of different transfer line 17 threaded connection's removal distance, and finally realize that a plurality of shower nozzles 9 present arc distribution, as shown in fig. 4 for the air current of shower nozzle 9 spun can pass through the clearance between the glass just, and the air cycle effect that the air current of avoiding shower nozzle 9 spun is blockked by the glass bottom is poor, and the condition such as glass uneven distribution takes place.

As an embodiment of the present invention, as shown in fig. 2, 3, 4, and 6, the supporting frame 2 includes a frame 201, a plurality of rollers 202, a supporting rod 203, and a fixing strip 204, the rollers 202 are provided with a plurality of rollers and are fixedly connected to the bottom end of the frame 201, the bottom wall of the sliding groove 102 is provided with a sliding way 104, the rollers 202 are rotatably connected in the sliding way 104, the supporting rod 203 and the fixing strip 204 are both fixedly connected in the frame 201, the fixing strip 204 is provided with two rollers and is symmetrically arranged on both sides of the supporting rod 203, the fixing strip 204 is rotatably connected with a plurality of limiting blocks 205, the top ends of the limiting blocks 205 are provided with fixing grooves 209, the middle portion of the frame 201 is fixedly connected with a supporting plate 206, the detecting mechanism 13 includes a driving rack 1301, a driving rack 1302, a rotating gear 1303, a steering gear 1304, a connecting strip 1305, a threaded rod 1306, and a rotating disc 1307, the fixing strip 204 is provided with a through groove 207, the transmission rack 1301 is slidably connected inside the through groove 207, the bottom end of the limiting block 205 penetrates through the top wall of the through groove 207 and extends into the through groove 207 to be fixedly connected with the rotating gear 1303, the rotating gear 1303 is engaged with the transmission rack 1301, the side wall of the rear end of the fixing strip 204 at the rear end is provided with a slot 208, the slot 208 is communicated with the through groove 207, a plurality of connecting strips 1305 are arranged and slidably connected inside the slot 208, the front end of each connecting strip 1305 is fixedly connected with the rear end of the transmission rack 1301, the rear end of each connecting strip 1305 is fixedly connected with the front end of the driving rack 1302, the driving rack 1302 is engaged with the steering gear 1304, the steering gear 1304 is fixedly connected with the connecting rod 12, the driving rack 1302 is slidably connected with the side wall of the rear end of the frame 201, the threaded rod 1306 penetrates through the side wall of the left side of the transmission rack 1301 and is in threaded connection with the transmission rack 1301, and the threaded rod 1306 is rotatably connected with the side wall of the left side of the through groove 207, the left side of the threaded rod 1306 is fixedly connected with the rotary table 1307;

when the cambered glass fixing device works, the cambered glass can be fixed through the fixing groove 209 at the top end of the limiting block 205, when the cambered glass faces glass with different radians, the rotary disc 1307 is required to rotate to drive the threaded rod 1306 to rotate, the threaded rod 1306 drives the transmission rack 1301 to move, the transmission rack 1301 moves to realize the rotation of the limiting block 205 through the rotating gear 1303, the direction of the fixing groove 209 is changed, and the direction of the fixing groove 209 is fixed for glass with different radians; when facing glass with different radian, the position of the transmission rack 1301 relative to the through groove 207 is different, the position of the driving rack 1302 is different by the transmission rack 1301 through the connecting strip 1305, and when the support frame 2 is pushed into the homogenizing chamber 101, and during the movement to the extreme position of the slide 104, driving the rack 1302 will cause the steering gear 1304 to rotate, and when facing glass of different arcs, due to the different positions of the driving rack 1302 relative to the supporting frame 2, and thus the driving rack 1302 makes the steering gear 1304 rotate for different numbers of turns, the steering gear 1304 will make the connecting rod 12 rotate for different numbers of turns, the connecting rod 12 will then move the rack member 10 different distances via the connecting gear wheel 11, and further ensure that when facing glass with different radians, the plurality of spray heads 9 can present different arc distribution, thereby ensuring the adaptation to glass with different radians.

As an embodiment of the present invention, as shown in fig. 5, fixed blocks 19 are fixedly connected to both left and right ends of the sliding chute 102, a blocking sleeve 20 is fixedly connected to one side of the fixed block 19 close to the sliding chute 102, one side of the blocking sleeve 20 close to the spray head 9 is fixedly connected to the spray head 9, and a connecting plate 18 is fixedly connected between adjacent spray heads 9;

when the glass is in the homogenizing furnace, part of the glass is detonated in advance, so when the glass is detonated, part of glass scraps fall into the chute 102, the glass scraps can cause the inner part of the chute 102 to be blocked and can influence the movement of the spray head 9;

during operation, can realize blockking to spout 102 through the fixed plate and avoid the glass piece to fall into spout 102 from between shower nozzle 9, it can avoid the glass piece to enter into inside spout 102 from the clearance between spout 102 both ends and the shower nozzle 9 to block sleeve 20, and block sleeve 20 self and can play certain deformation effect, and then when the shower nozzle 9 that the shower nozzle 9 is located both ends and the distance between spout 102 both ends changes, it still can realize avoiding the glass piece to enter into inside spout 102 through the deformation of self to block sleeve 20.

As an embodiment of the present invention, as shown in fig. 2 and 7, the side blowing mechanism 14 comprises a blowing housing 1401, a rotating fan 1402, a driving shaft 1403, a worm wheel 1404, and a supporting block 1405, the supporting block 1405 is provided with a plurality of supporting blocks 1405 and fixedly connected to the side walls of the front and rear ends of the homogeneous chamber 101, the top end of the connecting rod 12 penetrates through the supporting block 1405 and is rotatably connected to the supporting block 1405, the blowing housing 1401 is located at the top end of the supporting block 1405 and is fixedly connected to the connecting rod 12, the rotating fan 1402 is provided with a plurality of supporting blocks 1401 and is rotatably connected to one side of the blowing housing 1401 far from the side wall of the homogeneous chamber 101, a connecting chamber 1406 is provided in the blowing housing 1401, one side of the rotating fan 1402 close to the blowing housing 1401 penetrates through the side wall of the blowing housing 1401 and extends into the connecting chamber 1406 and is fixedly connected to the worm wheel 1404, the driving shaft 1403 is located in the connecting chamber 1406 and is rotatably connected to the left and right side walls of the connecting chamber 1406, the driving shaft 1403 is meshed with the worm gears 1404, and the meshed connection part of the driving shaft 1403 and the worm gears 1404 is of a worm structure;

during operation, drive mechanism 15 will realize the drive to drive shaft 1403, and then drive shaft 1403 will drive worm wheel 1404 and rotate, and worm wheel 1404 will drive and rotate fan 1402 and rotate, and then realize blowing to the middle and upper side of glass, strengthen the convection current effect at middle and upper position in the glass, and then guarantee that glass upper and lower part all has better convection current effect, and then guarantee that glass upper and lower part temperature distribution is comparatively even.

As an embodiment of the invention, as shown in fig. 2 to 7, the transmission mechanism 15 is composed of a transmission shaft 1501, a wind wheel 1502, a connecting shaft 1503, a first bevel gear 1504, a second bevel gear 1505 and a universal joint 1506, wherein the wind wheel 1502 is arranged inside the drive box 4, the wind wheel 1502 is rotatably connected inside the drive box 4 through the transmission shaft 1501, one side of the transmission shaft 1501 close to the furnace body 1 penetrates through the furnace body 1 and extends into the homogenizing chamber 101 to be in transmission connection with the connecting shaft 1503 through the universal joint 1506, one end of the connecting shaft 1503 far away from the universal joint 1506 penetrates through and extends into the connecting chamber 1406 to be fixedly connected with the first bevel gear 1504, the second bevel gear 1505 is fixedly connected with the drive shaft 1403, and the first bevel gear 1504 is in meshing connection with the second bevel gear;

when the fan 1402 is rotated to blow air only from the side of the glass, the air flow is more blocked by the glass due to the characteristic of the curved glass, and the air flow is difficult to enter between the glass, so that the enhancement of the convection effect at the upper part of the glass cannot achieve the desired goal;

when in work, when glass with different radians is arranged on the supporting frame 2, the detection mechanism 13 can lead the rotating rod to rotate by different angles, and the rotating rod at this time drives the blowing shell 1401 to rotate, so that the airflow blown out by the rotating fan 1402 is tangential to the side surface of the glass, thereby ensuring that the air flow can well enter between the glasses and improving the air circulation speed between the glasses, in the above process, the airflow entering the inside of the driving box 4 from the filtering box 3 will drive the wind wheel 1502 to rotate, the wind wheel 1502 will drive the transmission shaft 1501 to rotate, the transmission shaft 1501 will drive the connection shaft 1503 to rotate through the universal joint 1506, the connection shaft 1503 will drive the driving shaft 1403 to rotate through the first bevel gear 1504 and the second bevel gear 1505, thereby, the driving of the rotating fan 1402 is realized, and during the rotation of the blower housing 1401, universal joint 1506 ensures that the drive effect is maintained between drive shaft 1501 and connecting shaft 1503.

As an embodiment of the present invention, as shown in fig. 2, a filter chamber 301 is formed in the filter box 3, a heating rod 302 is fixedly connected in the filter chamber 301, the communicating pipe 5 is arranged to communicate with the bottom end of the filter chamber 301, the filter chamber 301 contains water, a connecting pipe 303 is fixedly connected in the filter chamber 301, the top end of the connecting pipe 303 is located above the liquid level, and the bottom end of the connecting pipe 303 penetrates through the bottom wall of the filter chamber 301 and is arranged to communicate with the drive box 4;

the glass in the homogenizing chamber 101 is broken, so that the air in the homogenizing chamber 101 drives the glass dust, when the glass dust is accumulated too much, not only the pipeline is blocked and the rotation of the wind wheel 1502 in the driving box body 4 is influenced, but also the glass dust adhered to the surface of the glass along with the circulation of the air influences the uniformity of the glass temperature;

during operation, the inside air that enters into filter chamber 301 will contact with water, and then realize the glass dust of detached air, and realize the heating to water through heating rod 302, avoid water to absorb a large amount of heats in the air, and the in-process can increase the content of vapor in the air, and then realize improving the specific heat capacity of air, and then when the air passes and circulates between the glass, glass is slower at the temperature decline of circulating in-process self, avoid appearing because air self specific heat capacity is less, the air is by during supreme circulation down, the air carries out the heat exchange with articles such as glass, make the temperature decline of air self faster, the difference in temperature that leads to the not co-altitude air is great, and then the circumstances such as the difference in temperature that leads to the not co-altitude glass is bigger take place.

The working principle is as follows:

during work, the cambered glass can be fixed through the fixing groove 209 at the top end of the limiting block 205, when facing glasses with different radians, the rotary disc 1307 is required to rotate to drive the threaded rod 1306 to rotate, the threaded rod 1306 drives the transmission rack 1301 to move, the transmission rack 1301 moves to realize the rotation of the limiting block 205 through the rotating gear 1303, the direction of the fixing groove 209 is changed, the glass with different radians is fixed through the fixing groove 209 in the direction, the position of the transmission rack 1301 relative to the through groove 207 is different, and the position of the driving rack 1302 is different through the connecting strip 1305 by the transmission rack 1301; when the support frame 2 is pushed into the homogenizing cavity 101 and moves to the limit position of the slide way 104, the driving rack 1302 will make the steering gear 1304 rotate, the steering gear 1304 will make the rotating rod rotate, the connecting rod 12 will make the first rack 1001 move through the connecting gear 11, the first rack 1001 will drive the plurality of transmission gears 16 to rotate through the second rack 1002 fixedly connected with the first rack 1001, because the radiuses of the plurality of transmission gears 16 are different, when the tooth condition 10 moves the same distance, the number of rotating turns of the plurality of transmission gears 16 is different, further the number of rotating turns of the plurality of transmission rods 17 fixedly connected with the transmission gears 16 is different, further the moving distance of the spray heads 9 in threaded connection with different transmission rods 17 is different, and finally the plurality of spray heads 9 are distributed in an arc shape, further the distribution of the plurality of spray heads 9 can be changed along with the change of the radian of the glass, the air flow sprayed by the spray head 9 can just pass through the gap between the glass, so that the conditions that the air circulation effect is poor, the glass is not uniformly distributed and the like caused by the fact that the air flow sprayed by the spray head 9 is blocked by the bottom end of the glass are avoided; meanwhile, airflow entering the driving box body 4 from the filtering box body 3 drives the wind wheel 1502 to rotate, the wind wheel 1502 drives the transmission shaft 1501 to rotate, the transmission shaft 1501 drives the connection shaft 1503 to rotate through the universal joint 1506, and the connection shaft 1503 drives the driving shaft 1403 to rotate through the first bevel gear 1504 and the second bevel gear 1505, so that the rotating fan 1402 is driven, air is blown to the upper side surface of the glass, the convection effect of the upper middle part of the glass is enhanced, and the good convection effect of the upper part and the lower part of the glass is ensured; when glass with different radians is arranged on the support frame 2, the detection mechanism 13 can enable the rotating rod to rotate by different angles, so that the rotating rod can drive the blowing shell 1401 to rotate, the air flow blown out by the rotating fan 1402 is tangent to the side surface of the glass, and the air flow can well enter between the glass and can improve the air circulation speed between the glass.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. A building glass homogenizing furnace is characterized by comprising a furnace body (1), a support frame (2), a filtering box body (3), a driving box body (4), a communicating pipe (5), a circulating fan (6) and a heating box (7), wherein the circulating fan (6) is fixedly connected to the center of the top end of the furnace body (1), the filtering box body (3) is fixedly connected to the outer side walls of the front end and the rear end of the furnace body (1), the filtering box body (3) is positioned on the two sides of the front end and the rear end of the furnace body (1), the filtering box body (3) is communicated with the circulating fan (6) through the communicating pipe (5), the bottom end of the filtering box body (3) is fixedly communicated with the top end of the driving box body (4), the bottom end of the driving box body (4) is fixedly communicated with the top end of the heating box (7), the bottom end of the heating box (7) is fixedly communicated with a gas pipe (8), a homogenizing cavity (101) is formed in the furnace body (1), the bottom wall of the homogenizing cavity (101) is provided with a sliding groove (102), the sliding groove (102) is connected with a spray head (9) in a sliding manner, a plurality of spray heads (9) are arranged, one end, far away from the heating box (7), of the gas conveying pipe (8) penetrates through the outer side wall of the furnace body (1) and extends into the homogenizing cavity (101), one end, located in the homogenizing cavity (101), of the gas conveying pipe (8) is fixedly communicated with the spray heads (9), the support frame (2) is connected to the bottom wall of the homogenizing cavity (101) in a sliding manner, transmission cavities (103) are formed in the left side and the right side of the bottom wall of the homogenizing cavity (101), the transmission cavities (103) are connected with tooth conditions (10) in a sliding manner, the front end and the rear end of one side, close to the center of the furnace body (1), of each tooth condition (10) are connected with a connecting gear (11) in a meshing manner, and the top end of each connecting gear (11) is fixedly connected with a connecting rod (12), the supporting frame (2) is provided with a detection mechanism (13), the connecting rod (12) positioned on the right side of the rear end is in transmission connection with the detection mechanism (13), the connecting rod (12) penetrates through the top wall of the transmission cavity (103) and extends into the homogeneous cavity (101) to be fixedly connected with a side blowing mechanism (14), one side, close to the side wall of the homogeneous cavity (101), of the side blowing mechanism (14) is in transmission connection with a transmission mechanism (15), one end, far away from the side blowing mechanism (14), of the transmission mechanism (15) penetrates through the homogeneous cavity (101) and extends into the driving box body (4), the top end of the tooth condition (10) is in meshing connection with a transmission gear (16), the transmission gear (16) is provided with a plurality of transmission gears (16), the transmission gears (16) are distributed in a manner that the radiuses of the transmission gears (16) are gradually reduced along the directions, close to the two ends, of the center of the tooth condition (10), and a transmission rod (17) is fixedly connected with the center of the transmission gear (16), the transmission rod (17) penetrates through the side wall of the transmission cavity (103), extends to the inner wall of the sliding groove (102) and is in threaded connection with the spray head (9), and threads with opposite textures are circumferentially distributed on two sides of the center of the transmission rod (17).

2. The building glass homogenizing furnace according to claim 1, wherein fixing blocks (19) are fixedly connected to the left end and the right end of the sliding chute (102), a blocking sleeve (20) is fixedly connected to one side, close to the sliding chute (102), of each fixing block (19), one side, close to each spray head (9), of each blocking sleeve (20) is fixedly connected with each spray head (9), and a connecting plate (18) is fixedly connected between every two adjacent spray heads (9).

3. The architectural glass homogenizing furnace according to claim 1, wherein the rack member (10) is composed of a first rack (1001) and a second rack (1002), the first rack (1001) is fixedly connected with the second rack (1002), the first rack (1001) and the second rack (1002) are arranged in parallel, one side of the first rack (1001) close to the center of the bottom wall of the transmission cavity (103) is meshed and connected with the connecting gear (11), and the top end of the second rack (1002) is meshed and connected with the transmission gear (16).

4. The building glass homogenizing furnace according to claim 1, wherein the supporting frame (2) is composed of a frame body (201), rollers (202), supporting rods (203) and fixing strips (204), the rollers (202) are provided with a plurality of fixing strips (204) which are fixedly connected to the bottom end of the frame body (201), the bottom wall of the sliding chute (102) is provided with a sliding rail (104), the rollers (202) are connected in the sliding rail (104) in a rolling manner, the supporting rods (203) and the fixing strips (204) are fixedly connected in the frame body (201), the fixing strips (204) are provided with two fixing strips which are symmetrically arranged on two sides of the supporting rods (203), the fixing strips (204) are rotatably connected with a plurality of limiting blocks (205), the top ends of the limiting blocks (205) are provided with fixing grooves (209), and the middle part of the frame body (201) is fixedly connected with the supporting plate (206).

5. The architectural glass homogenizing furnace according to claim 4, wherein the detecting mechanism (13) is composed of a transmission rack (1301), a driving rack (1302), a rotating gear (1303), a steering gear (1304), a connecting strip (1305), a threaded rod (1306) and a turntable (1307), a through groove (207) is formed in the fixing strip (204), the transmission rack (1301) is slidably connected into the through groove (207), the bottom end of the limiting block (205) penetrates through the top wall of the through groove (207) and extends into the through groove (207) to be fixedly connected with the rotating gear (1303), the rotating gear (1303) is meshed with the transmission rack (1301), a groove (208) is formed in the rear end side wall of the fixing strip (204) at the rear end, the groove (208) is communicated with the through groove (207), a plurality of connecting strips (1305) are arranged and are slidably connected into the groove (208), the front end of the connecting strip (1305) is fixedly connected with the rear end of the transmission rack (1301), the rear end of the connecting strip (1305) is fixedly connected with the front end of the driving rack (1302), the driving rack (1302) is meshed with the steering gear (1304), the steering gear (1304) is fixedly connected with the connecting rod (12), the driving rack (1302) is slidably connected with the side wall of the rear end of the frame body (201), the threaded rod (1306) penetrates through the side wall of the left side of the transmission rack (1301) and is in threaded connection with the transmission rack (1301), the threaded rod (1306) is rotatably connected with the side wall of the left side of the through groove (207), and the left side of the threaded rod (1306) is fixedly connected with the rotary table (1307).

6. The architectural glass homogenizing furnace according to claim 1, wherein the side blowing mechanism (14) comprises a blowing shell (1401), a rotating fan (1402), a driving shaft (1403), a worm wheel (1404) and a supporting block (1405), the supporting block (1405) is provided with a plurality of parts and fixedly connected to the side walls of the front end and the rear end of the homogenizing chamber (101), the top end of the connecting rod (12) penetrates through the supporting block (1405) and is rotatably connected with the supporting block (1405), the blowing shell (1401) is positioned at the top end of the supporting block (1405) and is fixedly connected with the connecting rod (12), the rotating fan (1402) is provided with a plurality of parts and is rotatably connected to one side of the blowing shell (1401) far away from the side wall of the homogenizing chamber (101), a connecting chamber (1406) is arranged in the blowing shell (1401), one side of the rotating fan (1402) close to the blowing shell (1401) penetrates through the side wall of the blowing shell (1401) and extends into the connecting chamber (1406) and is fixedly connected with the worm wheel (1404), the driving shaft (1403) is located in the connecting cavity (1406) and is in rotating connection with the side walls of the left side and the right side of the connecting cavity (1406), the driving shaft (1403) is in meshing connection with the worm wheels (1404), and the meshing connection position of the driving shaft (1403) and the worm wheels (1404) is of a worm structure.

7. The architectural glass homogenizing furnace according to claim 6, wherein the transmission mechanism (15) is composed of a transmission shaft (1501), a wind wheel (1502), a connecting shaft (1503), a first bevel gear (1504), a second bevel gear (1505) and a universal joint (1506), the wind wheel (1502) is arranged inside the driving box body (4), the wind wheel (1502) is rotatably connected inside the driving box body (4) through the transmission shaft (1501), one side of the transmission shaft (1501) close to the furnace body (1) penetrates through the furnace body (1) and extends into the homogenizing cavity (101) to be in transmission connection with the connecting shaft (1503) through the universal joint (1506), one end of the connecting shaft (1503) far away from the universal joint (1506) penetrates through and extends into the connecting cavity (1406) to be fixedly connected with the first bevel gear (1504), and the second bevel gear (1505) is fixedly connected with the driving shaft (1403), the first bevel gear (1504) is in meshed connection with the second bevel gear (1505).

8. The architectural glass homogenizing furnace according to claim 1, wherein a filter cavity (301) is formed in the filter box body (3), a heating rod (302) is fixedly connected in the filter cavity (301), the communicating pipe (5) is communicated with the bottom end of the filter cavity (301), water is contained in the filter cavity (301), a connecting pipe (303) is fixedly connected in the filter cavity (301), the top end of the connecting pipe (303) is positioned above the liquid level, and the bottom end of the connecting pipe (303) penetrates through the bottom wall of the filter cavity (301) and is communicated with the drive box body (4).