阅读说明：本技术 一种高强度玻璃制作用速冷装置 (Fast cold charge is used in high strength glass preparation ) 是由 任红兵 于 2020-07-21 设计创作，主要内容包括：本发明涉及一种高强度玻璃制作用速冷装置,包括保温外壳、上端速冷板、下端速冷板、液氮制备系统、传送辊、驱动箱。上端速冷板、传送辊、下端速冷板布置于保温外壳内部,驱动箱设置于保温外壳外部。保温外壳前后两端分别设有玻璃入口以及玻璃出口,传送辊两端设有转轴,其中转轴一端固定有设于驱动箱内的从动皮带轮。驱动箱内部设有与从动皮带轮通过皮带转动连接的主动皮带轮,驱动箱上设有至少一个升降装置,升降装置固定在保温外壳外壁上。上端速冷板、下端速冷板连接有液氮供给管以及氮气回收管,液氮供给管以及氮气回收管与液氮制备系统连接。本发明采用液氮气化制冷,玻璃表面温度下降块,降温幅度大,且降温均匀。(The invention relates to a quick cooling device for manufacturing high-strength glass, which comprises a heat-insulating shell, an upper quick cooling plate, a lower quick cooling plate, a liquid nitrogen preparation system, a conveying roller and a driving box. The upper-end quick cooling plate, the conveying roller and the lower-end quick cooling plate are arranged inside the heat preservation shell, and the driving box is arranged outside the heat preservation shell. The front end and the rear end of the heat preservation shell are respectively provided with a glass inlet and a glass outlet, the two ends of the conveying roller are provided with rotating shafts, and one end of each rotating shaft is fixed with a driven belt pulley arranged in the driving box. The driving box is internally provided with a driving belt pulley which is rotatably connected with the driven belt pulley through a belt, the driving box is provided with at least one lifting device, and the lifting device is fixed on the outer wall of the heat insulation shell. The upper end rapid cooling plate and the lower end rapid cooling plate are connected with a liquid nitrogen supply pipe and a nitrogen recovery pipe, and the liquid nitrogen supply pipe and the nitrogen recovery pipe are connected with a liquid nitrogen preparation system. The invention adopts liquid nitrogen gasification refrigeration, the temperature of the glass surface is reduced, the cooling amplitude is large, and the cooling is uniform.)

1. The utility model provides a high strength glass preparation is with quick cold charge is put which characterized in that:

comprises a heat-insulating shell (1), an upper end rapid cooling plate (4), a lower end rapid cooling plate (5), a liquid nitrogen preparation system (6), a conveying roller (7) and a driving box (8),

the upper end rapid cooling plate (4), a plurality of conveying rollers (7) and the lower end rapid cooling plate (5) are sequentially arranged inside the heat preservation shell (1) from top to bottom, the driving box (8) is arranged outside the heat preservation shell (1),

the front end and the rear end of the heat preservation shell (1) are respectively provided with a glass inlet (103) and a glass outlet (104), the top surface of the upper end rapid cooling plate (4) is fixedly connected with the top surface of the heat preservation shell (1), the bottom surface of the lower end rapid cooling plate (5) is fixedly connected with the bottom surface of the heat preservation shell (1), two ends of the conveying roller (7) are provided with rotating shafts (701), the side walls of the left side and the right side of the heat preservation shell (1) are provided with waist-shaped holes, the rotating shafts (701) are inserted into the waist-shaped holes, one end of each rotating shaft (701) is fixedly provided with a driven belt pulley,

a driving belt pulley (8021) rotationally connected with the driven belt pulley (702) through a belt (804) is arranged in the driving box (8), the driving belt pulley (8021) is connected with an output shaft of the driving device (802), at least one lifting device (801) is arranged above or below the driving box (8), the lifting device (801) is fixed on the outer wall of the heat-insulating shell (1), the tail end of a piston rod of the lifting device (801) is fixedly connected with the driving box (8),

the inner cavities of the upper end rapid cooling plate (4) and the lower end rapid cooling plate (5) are connected with a liquid nitrogen supply pipe (601) and a nitrogen recovery pipe (602) in a through mode, and the liquid nitrogen supply pipe (601) and the nitrogen recovery pipe (602) are connected with a liquid nitrogen preparation system (6).

2. The rapid cooling device for manufacturing high-strength glass according to claim 1, wherein:

a rotating shaft (701) at one end of the conveying roller (7) departing from the driving box (8) penetrates through the outer part of the heat-insulating shell (1) and is commonly connected with a connecting plate (9),

both sides that insulating casing (1) outer wall is located drive case (8) and connecting plate (9) all are equipped with stopper (102), stopper (102) on be equipped with waist type slide opening, drive case (8) both ends are equipped with first slide bar (803), connecting plate (9) both ends are equipped with second slide bar (901), inside the waist type slide opening of stopper (102) was located in first slide bar (803), second slide bar (901) all slided from top to bottom.

3. The rapid cooling device for manufacturing high-strength glass according to claim 1, wherein:

the lower end of the upper-end quick cooling plate (4) is provided with a plurality of upper-end radiating strips (401), and the inner cavity of each upper-end radiating strip (401) is communicated with the inner cavity of the upper-end quick cooling plate (4);

the upper end of the lower-end quick cooling plate (5) is provided with a plurality of lower-end radiating strips (501), and the inner cavity of each lower-end radiating strip (501) is communicated with the inner cavity of the lower-end quick cooling plate (5);

the conveying roller (7) is positioned between the lower end radiating strips (501), the top surface of the conveying roller (7) is higher than that of the lower end radiating strips (501) when the conveying roller moves up to the highest point, and the top surface of the conveying roller (7) is lower than that of the lower end radiating strips (501) when the conveying roller moves down to the lowest point.

4. The rapid cooling device for manufacturing high-strength glass according to claim 3, wherein:

the tail end of the liquid nitrogen supply pipe (601) is provided with an upper end liquid nitrogen branch pipe (6011) and a lower end liquid nitrogen branch pipe (6012), the upper end liquid nitrogen branch pipe (6011) and the lower end liquid nitrogen branch pipe (6012) respectively penetrate through the upper end rapid cooling plate (4) and the lower end rapid cooling plate (5),

a plurality of spray pipes (60111) are connected on an upper end liquid nitrogen branch pipe (6011) positioned in the upper end quick cooling plate (4) in a penetrating way, spray holes of the spray pipes (60111) are arranged downwards,

the tail end of the nitrogen recovery pipe (602) is provided with an upper-end nitrogen recovery branch pipe (6021) and a lower-end nitrogen recovery branch pipe (6022), the upper-end nitrogen recovery branch pipe (6021) and the lower-end nitrogen recovery branch pipe (6022) respectively penetrate through the upper-end rapid cooling plate (4) and the lower-end rapid cooling plate (5), and the nitrogen recovery pipe (602) is provided with a first pipeline air pump (603).

5. The rapid cooling device for manufacturing high-strength glass according to claim 4, wherein:

the liquid nitrogen preparation system (6) comprises a gaseous nitrogen recovery box (6a), a nitrogen liquefaction device (6b) and a liquid nitrogen storage device (6c), wherein the gaseous nitrogen recovery box (6a), the nitrogen liquefaction device (6b) and the liquid nitrogen storage device (6c) are sequentially connected through a pipeline,

the gaseous nitrogen recovery tank (6a) is connected with the nitrogen recovery pipe (602) in a penetrating way, and the liquid nitrogen storage device (6c) is connected with the liquid nitrogen supply pipe (601) through a high-pressure pump.

6. The rapid cooling device for manufacturing high-strength glass according to claim 4, wherein:

the front end of the heat-insulating shell (1) is provided with a feeding top plate (2), a feeding channel (201) is arranged below the feeding top plate (2), the feeding channel (201) is communicated with the glass inlet (103),

a feeding end upper air curtain strip (204) is arranged above the junction of the feeding channel (201) and the glass inlet (103), a feeding end lower air curtain strip (205) is arranged below the junction, a feeding end upper air curtain channel (2041) is concavely arranged on the bottom surface of the feeding end upper air curtain strip (204), a feeding end lower air curtain air collecting channel (2051) is concavely arranged on the top surface of the feeding end lower air curtain strip (205),

the rear end of the heat preservation shell (1) is provided with a discharging supporting plate (3), the top surface of the discharging supporting plate (3) is flush with the bottom surface of the glass outlet (104), a discharging end upper air curtain strip (301) is arranged above the junction of the discharging supporting plate (3) and the glass outlet (104), a discharging end lower air curtain strip (302) is arranged below the junction, a discharging end upper air curtain channel (3011) is concavely arranged on the bottom surface of the discharging end upper air curtain strip (301), a discharging end lower air curtain air collecting channel (3021) is concavely arranged on the top surface of the discharging end lower air curtain strip (302),

the air curtain air inlet main pipe (10) is respectively communicated with the air curtain channel (2041) at the upper part of the feeding end and the air curtain channel (3011) at the upper part of the discharging end through two air curtain air inlet branch pipes (1001), a second pipeline air pump (1002) is arranged on the air curtain air inlet main pipe (10),

the air curtain air outlet header pipe (11) is respectively communicated with the feed end lower air curtain air collecting channel (2051) and the discharge end lower air curtain air collecting channel (3021) through the two air curtain air outlet branch pipes (1101).

7. The rapid cooling device for manufacturing high-strength glass according to claim 5, wherein:

the inner walls of the left side and the right side of the heat preservation shell (1) are respectively provided with a cold air inlet (105) and a cold air outlet (106) in a concave manner, a cold air inlet pipe (12) outside the heat preservation shell (1) is communicated with the cold air inlet (105), a cold air outlet pipe (13) outside the heat preservation shell (1) is communicated with the cold air outlet (106),

the tail end of the cold air inlet pipe (12) is provided with at least two spiral pipes (1202), the two adjacent spiral pipes (1202) are communicated and connected through a detection temperature adjusting pipe (1203), the spiral pipe (1202) at the tail end is communicated and connected with an air outlet of a fan (1206) in the air box (14) through the detection temperature adjusting pipe (1203),

a temperature sensor (1204) and a liquid nitrogen adding pipe (1205) are sequentially arranged on the detection temperature adjusting pipe (1203) along the airflow direction, the liquid nitrogen adding pipe (1205) is communicated with a liquid nitrogen storage device (6c),

the tail end of the cold air outlet pipe (13) is communicated with the air box (14), and a third pipeline air suction pump (1301) is arranged on the cold air outlet pipe (13).

8. The rapid cooling device for manufacturing high-strength glass according to claim 7, wherein:

the through connection part of the cold air inlet pipe (12) and the cold air inlet (105) and the through connection part of the cold air outlet pipe (13) and the cold air outlet (106) are both positioned above the heat preservation shell (1),

a conical air guide cover (1201) is arranged at the through connection position of the cold air outlet pipe (13) and the cold air outlet (106), and a conical air collecting cover (1302) is arranged at the through connection position of the cold air outlet pipe (13) and the cold air outlet (106).

9. The rapid cooling device for manufacturing high-strength glass according to claim 7, wherein:

also comprises a control device (15),

photoelectric correlation sensor groups (101) are arranged at a glass inlet (103) and a glass outlet (104) of the heat-insulating shell (1),

at least one thickness sensor (202) is arranged on the feeding top plate (2),

an electric control regulating valve (12051) is arranged on the liquid nitrogen adding pipe (1205),

the device comprises a photoelectric correlation sensor group (101), a thickness sensor (202), a liquid nitrogen preparation system (6), a first pipeline air pump (603), a lifting device (801), a driving device (802), a second pipeline air pump (1002), a temperature sensor (1204), an electric control adjusting valve (12051), a fan (1206) and a third pipeline air pump (1301) which are respectively electrically connected with a control device (15).

10. A rapid cooling method for producing high-strength glass, which is based on the rapid cooling device for manufacturing the high-strength glass as claimed in claim 9, and is characterized by comprising the following steps:

A. the feeding top plate (2) is covered on a conveying belt at the tail end of a heating furnace for glass production, the tail end of the conveying belt is contacted with the heat-insulating shell (1), the heated glass is conveyed into the heat-insulating shell (1) through a glass inlet (103), and a conveying roller (7) in the heat-insulating shell (1) is in relay to completely move the glass into the heat-insulating shell (1);

when glass just enters the glass inlet (103), signals of the photoelectric correlation sensor group (101) on the glass inlet (103) are shielded, after the glass completely enters the heat-preservation shell (1) through the glass inlet (103), the photoelectric correlation sensor group (101) is in signal communication, and whether the glass completely enters the heat-preservation shell (1) or not can be known through signal conversion of the photoelectric correlation sensor group (101);

B. after the glass completely enters the heat insulation shell (1), the lifting device (801) drives the conveying roller (7) to move downwards through the driving box (8), and the bottom surface of the glass is contacted with the top surface of the lower-end heat dissipation strip (501);

C. high-pressure air is introduced into an air curtain inlet main pipe (10) from the interior of an air curtain channel (2041) at the upper part of a feeding end and an air curtain channel (3011) at the upper part of a discharging end, an air curtain is formed outside a glass inlet (103) and a glass outlet (104), and the interior of the heat-insulating shell (1) is sealed through the air curtain;

D. the liquid nitrogen supply pipe (601) sprays liquid nitrogen into the upper end rapid cooling plate (4) and the lower end rapid cooling plate (5), the liquid nitrogen absorbs heat and is exhausted through the nitrogen recovery pipe (602) after being gasified,

the liquid nitrogen is gasified to take away a large amount of heat, so that the temperature in the heat-insulating shell (1) is rapidly reduced, and the glass is rapidly cooled;

E. the fan (1206) leads the gas in the gas box (14) into the heat-insulating shell (1) through the cold air inlet pipe (12), then the gas flows back to the gas box (14) again through the cold air outlet pipe (13), the temperature sensor (1204) detects the temperature of the gas flow, the liquid nitrogen adding pipe (1205) adds liquid nitrogen into the gas flow to reduce the temperature of the gas flow, and the spiral pipe (1202) is convenient for the liquid nitrogen to be mixed with the gas flow;

F. the time that the glass with different thicknesses needs to be cooled is different, the rear end sensor (202) detects the thickness of the glass, the staying time of the glass in the heat-insulating shell (1) is set according to the thickness of the glass, and after the staying time is reached, the conveying roller (7) is lifted up to convey the glass onto the discharging supporting plate (3).

Technical Field

The invention belongs to the technical field of glass manufacturing, and particularly relates to a quick cooling device for manufacturing high-strength glass.

Background

Glass is an amorphous inorganic non-metallic material, generally made of various inorganic minerals (such as quartz sand, borax, boric acid, barite, barium carbonate, limestone, feldspar, soda ash, etc.) as main raw materials, and a small amount of auxiliary raw materials are added, and its main components are silicon dioxide and other oxides, so that it can be extensively used in buildings and vehicles for insulating wind and transmitting light.

In some special fields, the roof of a sunlight house, household glass tableware and the like are utilized, and high-strength glass is required according to certain requirements on the strength of the glass. In the manufacturing process of the high-strength glass, the glass needs to be heated and then cooled quickly, so that the strength of the glass is improved.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: the invention overcomes the defects of the prior art and provides the quick cooling device for manufacturing the high-strength glass.

The technical scheme adopted by the invention for solving the problems in the prior art is as follows:

a quick cooling device for manufacturing high-strength glass comprises a heat preservation shell, an upper end quick cooling plate, a lower end quick cooling plate, a liquid nitrogen preparation system, a conveying roller and a driving box.

The upper end quick cooling plate, the plurality of conveying rollers and the lower end quick cooling plate are sequentially arranged inside the heat preservation shell from top to bottom, and the driving box is arranged outside the heat preservation shell.

Both ends are equipped with glass entry and glass export respectively around the lagging casing, upper end rapid cooling board top surface and lagging casing top surface fixed connection, lower end rapid cooling board bottom surface and lagging casing bottom surface fixed connection, and the transfer roller both ends are equipped with the pivot, are equipped with waist type hole on the lagging casing left and right sides lateral wall, and the pivot is inserted and is located waist type downthehole portion, and wherein pivot one end is fixed with the driven pulley who locates in the drive box.

The driving pulley is arranged in the driving box and is rotatably connected with the driven pulley through a belt, the driving pulley is connected with an output shaft of the driving device, at least one lifting device is arranged above or below the driving box and fixed on the outer wall of the heat-insulating shell, and the tail end of a piston rod of the lifting device is fixedly connected with the driving box.

The inner cavities of the upper end quick cooling plate and the lower end quick cooling plate are connected with a liquid nitrogen supply pipe and a nitrogen recovery pipe in a through mode, and the liquid nitrogen supply pipe and the nitrogen recovery pipe are connected with a liquid nitrogen preparation system.

Preferably, the transmission roller deviates from the pivot of drive case one end and wears to establish to the lagging casing outside to be connected with the connecting plate jointly.

The both sides that the lagging casing outer wall is located drive case and connecting plate all are equipped with the stopper, the stopper on be equipped with waist type slide opening, the drive case both ends are equipped with first slide bar, the connecting plate both ends are equipped with the second slide bar, first slide bar, second slide bar all slide from top to bottom and locate inside the waist type slide opening of stopper.

Preferably, the lower end of the upper-end quick cooling plate is provided with a plurality of upper-end radiating strips, and the inner cavity of each upper-end radiating strip is communicated with the inner cavity of the upper-end quick cooling plate;

the upper end of the lower end quick cooling plate is provided with a plurality of lower end heat dissipation strips, and the inner cavity of each lower end heat dissipation strip is communicated with the inner cavity of the lower end quick cooling plate;

the conveying roller is positioned between the lower end radiating strips, the top surface of the conveying roller is higher than that of the lower end radiating strips when the conveying roller moves upwards to the highest point, and the top surface of the conveying roller is lower than that of the lower end radiating strips when the conveying roller moves downwards to the lowest point.

Preferably, the tail end of the liquid nitrogen supply pipe is provided with an upper end liquid nitrogen branch pipe and a lower end liquid nitrogen branch pipe, and the upper end liquid nitrogen branch pipe and the lower end liquid nitrogen branch pipe penetrate through the upper end quick cooling plate and the lower end quick cooling plate respectively.

The upper end liquid nitrogen branch pipe positioned in the upper end quick cooling plate is connected with a plurality of liquid spraying pipes in a penetrating way, and spray holes of the liquid spraying pipes are arranged downwards.

The tail end of the nitrogen recovery pipe is provided with an upper-end nitrogen recovery branch pipe and a lower-end nitrogen recovery branch pipe, the upper-end nitrogen recovery branch pipe and the lower-end nitrogen recovery branch pipe penetrate through the upper-end quick-cooling plate and the lower-end quick-cooling plate respectively, and a first pipeline air pump is arranged on the nitrogen recovery pipe.

Preferably, the liquid nitrogen preparation system comprises a gaseous nitrogen recovery box, a nitrogen liquefaction device and a liquid nitrogen storage device, wherein the gaseous nitrogen recovery box, the nitrogen liquefaction device and the liquid nitrogen storage device are sequentially connected through pipelines.

The gaseous nitrogen recovery box is communicated with the nitrogen recovery pipe, and the liquid nitrogen storage device is connected with the liquid nitrogen supply pipe through the high-pressure pump.

Preferably, the front end of the heat preservation shell is provided with a feeding top plate, a feeding channel is arranged below the feeding top plate, and the feeding channel is communicated with the glass inlet.

Feed channel and glass entry juncture top are equipped with feed end upper portion air curtain strip, and the below is equipped with feed end lower part air curtain strip, and there is feed end upper portion air curtain passageway feed end upper portion air curtain strip bottom surface indent, and there is feed end lower part air curtain air-collecting channel feed end lower part air curtain strip top surface indent.

The lagging casing rear end is equipped with ejection of compact layer board, ejection of compact layer board top surface and glass export bottom surface parallel and level, ejection of compact layer board and glass export juncture top are equipped with discharge end upper portion air curtain strip, and the below is equipped with discharge end lower part air curtain strip, and discharge end upper portion air curtain strip bottom surface indent has discharge end upper portion air curtain passageway, and discharge end lower part air curtain strip top surface indent has discharge end lower part air curtain air collecting channel.

The air curtain air inlet main pipe is respectively communicated with the air curtain channel at the upper part of the feeding end and the air curtain channel at the upper part of the discharging end through two air curtain air inlet branch pipes, and a second pipeline air pump is arranged on the air curtain air inlet main pipe.

The air curtain air outlet header pipe is respectively communicated with the air curtain air collecting channel at the lower part of the feeding end and the air curtain air collecting channel at the lower part of the discharging end through two air curtain air outlet branch pipes.

Preferably, the inner walls of the left side and the right side of the heat preservation shell are respectively provided with a cold air inlet and a cold air outlet in an inwards concave manner, a cold air inlet pipe outside the heat preservation shell is in through connection with the cold air inlet, and a cold air outlet pipe outside the heat preservation shell is in through connection with the cold air outlet.

The tail end of the cold air inlet pipe is provided with at least two spiral pipes, the two adjacent spiral pipes are connected through a detection temperature adjusting pipe in a penetrating manner, and the tail spiral pipes are connected with a fan air outlet inside the air box through a detection temperature adjusting pipe in a penetrating manner.

The temperature detection and regulation pipe is sequentially provided with a temperature sensor and a liquid nitrogen adding pipe along the airflow direction, and the liquid nitrogen adding pipe is communicated with a liquid nitrogen storage device.

The tail end of the cold air outlet pipe is communicated with the air box, and a third pipeline air pump is arranged on the cold air outlet pipe.

Preferably, the through connection part of the cold air inlet pipe and the cold air inlet and the through connection part of the cold air outlet pipe and the cold air outlet are both positioned above the heat preservation shell.

A conical air guide cover is arranged at the through connection position of the cold air outlet pipe and the cold air outlet, and a conical air collecting cover is arranged at the through connection position of the cold air outlet pipe and the cold air outlet.

Preferably, the device further comprises a control device. The glass inlet and the glass outlet of the heat preservation shell are respectively provided with a photoelectric correlation sensor group, the feeding top plate is provided with at least one thickness sensor, and the liquid nitrogen adding pipe is provided with an electric control regulating valve. The photoelectric correlation sensor group, the thickness sensor, the liquid nitrogen preparation system, the first pipeline air pump, the lifting device, the driving device, the second pipeline air pump, the temperature sensor, the electric control adjusting valve, the fan and the third pipeline air pump are respectively and electrically connected with the control device.

A quick cooling method for producing high-strength glass comprises the following steps:

A. the feeding top plate is covered on a conveying belt at the tail end of a heating furnace for glass production, the tail end of the conveying belt is in contact with the heat-insulating shell, the heated glass is conveyed into the heat-insulating shell through a glass inlet, and the conveying roller in the heat-insulating shell is in relay connection to completely move the glass into the heat-insulating shell;

when glass just enters a glass inlet, signals of the photoelectric correlation sensor group on the glass inlet are shielded, after the glass completely enters the heat-insulation shell through the glass inlet, the signals of the photoelectric correlation sensor group are communicated, and whether the glass completely enters the heat-insulation shell or not can be known through signal conversion of the photoelectric correlation sensor group;

B. after the glass completely enters the heat insulation shell, the lifting device drives the conveying roller to move downwards through the driving box, and the bottom surface of the glass is contacted with the top surface of the lower end heat dissipation strip;

C. the air curtain air inlet header pipe introduces high-pressure air into the air curtain channel at the upper part of the feeding end and the air curtain channel at the upper part of the discharging end, air curtains are formed at the glass inlet and the outer part of the glass outlet, and the interior of the heat-insulating shell is sealed by the air curtains;

D. the liquid nitrogen supply pipe sprays liquid nitrogen to the upper end quick cooling plate and the lower end quick cooling plate, the liquid nitrogen absorbs heat and is discharged through the nitrogen recovery pipe after being gasified,

the liquid nitrogen is gasified to take away a large amount of heat, so that the temperature in the heat-insulating shell is rapidly reduced, and the glass is rapidly cooled;

E. the fan leads the gas in the gas box into the heat-insulating shell through the cold gas inlet pipe, then the gas flows back to the gas box again through the cold gas outlet pipe, the temperature sensor detects the temperature of the gas flow, the liquid nitrogen adding pipe adds liquid nitrogen into the gas flow to reduce the temperature of the gas flow, and the spiral pipe is convenient for the mixing of the liquid nitrogen and the gas flow;

F. the time that the glass of different thickness needs the cooling is different, and rear end sensor detects glass thickness, sets for the dwell time of glass in the heat preservation shell inside according to glass's thickness, reaches the dwell time after, and the transfer roller lifts up, conveys glass to on the ejection of compact layer board.

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

(1) the temperature inside the heat preservation shell is reduced through liquid nitrogen gasification, the cooling speed is high, the lowest temperature can be reached is lower, and meanwhile, the consistency of the temperature field inside the heat preservation shell is higher.

(2) The glass inlet and the glass outlet of the heat-insulating shell can be sealed by the air curtain, so that the temperature inside the heat-insulating shell is stable.

(3) The gasified liquid nitrogen can be recycled for liquefaction and utilization through a liquid nitrogen preparation device.

(4) The thickness of the glass to be cooled can be detected, and the control device can automatically adjust the cooling temperature and the cooling time of the glass according to the thickness of the glass.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a system diagram of a rapid cooling device for manufacturing high-strength glass according to the present invention,

figure 2 is a first profile view of the present invention,

figure 3 is a second profile view of the present invention,

figure 4 is a transverse center sectional view of the present invention,

figure 5 is a cross-sectional view at the web of the present invention,

figure 6 is a longitudinal center sectional view of the present invention,

figure 7 is a partial cross-sectional view of the instant cooling plate,

figure 8 is a block diagram of the glass movement system of the present invention,

figure 9 is a view of the gas box end of the present invention,

figure 10 is a partial cross-sectional view of the gas cabinet of the present invention,

FIG. 11 is an enlarged view of a portion of the spiral tube of the present invention,

FIG. 12 is a partial enlarged view of the present invention at A.

In the figure: 1-a heat preservation shell, 101-a photoelectric correlation sensor group, 102-a limiting block, 103-a glass inlet, 104-a glass outlet, 105-a cold air inlet and 106-a cold air outlet;

2-feeding top plate, 201-feeding channel, 202-thickness sensor, 203-guide roller, 2031-support bar, 204-feeding end upper air curtain strip, 2041-feeding end upper air curtain channel, 205-feeding end lower air curtain strip, 2051-feeding end lower air curtain air collecting channel;

3-a discharge supporting plate, 301-a discharge end upper air curtain strip, 3011-a discharge end upper air curtain channel, 302-a discharge end lower air curtain strip and 3021-a discharge end lower air curtain air collecting channel;

4-upper end rapid cooling plate, 401-upper end heat dissipation strip;

5-lower end rapid cooling plate, 501-lower end heat dissipation strip;

6-liquid nitrogen preparation system, 6 a-gaseous nitrogen recovery tank, 6 b-nitrogen liquefaction device, 6 c-liquid nitrogen storage device, 601-liquid nitrogen supply pipe, 6011-upper end liquid nitrogen branch pipe, 60111-liquid spray pipe, 6012-lower end liquid nitrogen branch pipe, 602-nitrogen recovery pipe, 6021-upper end nitrogen recovery branch pipe, 6022-lower end nitrogen recovery branch pipe and 603-first pipeline air pump;

7-conveying roller, 701-rotating shaft, 702-driven belt pulley;

8-driving box, 801-lifting device, 802-driving device, 8021-driving belt pulley, 803-first sliding rod, 804-belt, 805-expansion wheel;

9-connecting plate, 901-second slide bar;

10-an air curtain air inlet main pipe, 1001-an air curtain air inlet branch pipe and 1002-a second pipeline air pump;

11-an air curtain air outlet header pipe and 1101-an air curtain air outlet branch pipe;

12-a cold air inlet pipe, 1201-an air guide cover, 1202-a spiral pipe, 1203-a detection temperature adjusting pipe, 1204-a temperature sensor, 1205-a liquid nitrogen adding pipe, 12051-an electric control adjusting valve and 1206-a fan;

13-a cold air outlet pipe, 1301-a third pipeline air pump and 1302-a gas collecting hood;

14-a gas tank;

15-control means.

Detailed Description

The attached drawings are the best embodiments of the quick cooling device for manufacturing the high-strength glass, and the invention is further described in detail by combining the attached drawings.

As shown in the attached drawings 1 to 6, the rapid cooling device for manufacturing the high-strength glass comprises a heat preservation shell 1, an upper end rapid cooling plate 4, a lower end rapid cooling plate 5, a liquid nitrogen preparation system 6, a conveying roller 7, a driving box 8 and a control device 15.

The upper end rapid cooling plate 4, a plurality of conveying rollers 7 and the lower end rapid cooling plate 5 are arranged inside the heat preservation shell 1 from top to bottom in sequence,

the lower end of the upper end quick cooling plate 4 is provided with a plurality of upper end heat dissipation strips 401, and the inner cavity of each upper end heat dissipation strip 401 is communicated with the inner cavity of the upper end quick cooling plate 4. The upper end of the lower end quick cooling plate 5 is provided with a plurality of lower end heat dissipation strips 501, and the inner cavity of the lower end heat dissipation strips 501 is communicated with the inner cavity of the lower end quick cooling plate 5. The upper end heat dissipation strip 401 and the lower end heat dissipation strip 501 have the same working principle, and both increase the heat exchange area, so that the inside of the heat preservation shell 1 is rapidly cooled.

The conveying roller 7 is positioned between the lower end heat dissipation strips 501, the top surface of the conveying roller 7 is higher than that of the lower end heat dissipation strips 501 when the conveying roller moves upwards to the highest point, and the top surface of the conveying roller 7 is lower than that of the lower end heat dissipation strips 501 when the conveying roller moves downwards to the lowest point.

The drive box 8 is arranged outside the heat-insulating shell 1, and heat-insulating materials can be filled between the inner wall and the outer wall of the heat-insulating shell 1, so that the stability of a temperature field inside the heat-insulating shell 1 is facilitated.

The front end and the rear end of the heat preservation shell 1 are respectively provided with a glass inlet 103 and a glass outlet 104, and the glass inlet 103 and the glass outlet 104 of the heat preservation shell 1 are respectively provided with a photoelectric correlation sensor group 101. The photoelectric correlation sensor group 101 can detect whether glass completely enters the heat preservation shell 1 or completely moves out of the heat preservation shell 1.

The top surface of the upper quick cooling plate 4 is fixedly connected with the top surface of the heat preservation shell 1, and the bottom surface of the lower quick cooling plate 5 is fixedly connected with the bottom surface of the heat preservation shell 1. The two ends of the conveying roller 7 are provided with rotating shafts 701, the side walls of the left side and the right side of the heat preservation shell 1 are provided with waist-shaped holes, the rotating shafts 701 are inserted into the waist-shaped holes, and the rotating shafts 701 can move up and down in the waist-shaped holes.

As shown in fig. 8, a driven pulley 702 disposed in a driving box 8 is fixed at one end of a rotating shaft 701, a driving pulley 8021 rotatably connected to the driven pulley 702 through a belt 804 is disposed in the driving box 8, the driving pulley 8021 is connected to an output shaft of a driving device 802, the driving device 802 is disposed in or outside the driving box 8, the driving device 802 uses a servo motor with a reduction box or directly uses a reduction motor, and the driving device 802 drives the driving pulley 8021 to rotate. In order that the driving pulley 8021 can drive the driven pulley 702 to rotate through the belt 804, the belt 804 is further sleeved with an expansion wheel 805, and the driving pulley 8021, the driven pulley 702 and the expansion wheel 805 together expand the belt 804.

At least one lifting device 801 is arranged above or below the driving box 8, and the lifting device 801 is arranged above the driving box 8 in the embodiment. The lifting device 801 is fixed on the outer wall of the heat preservation shell 1, the tail end of a piston rod of the lifting device 801 is fixedly connected with the driving box 8, and the lifting device 8 adopts an electric cylinder and controls the driving box 8 to move up and down by driving the piston rod to stretch and retract.

As shown in fig. 5 and 12, the rotating shaft 701 of the conveying roller 7 at the end departing from the driving box 8 penetrates through the heat-insulating housing 1, and is connected with the connecting plate 9.

The outer wall of the heat insulation shell 1 is provided with limiting blocks 102 on two sides of the driving box 8 and the connecting plate 9, the limiting blocks 102 are provided with waist-shaped sliding holes, the two ends of the driving box 8 are provided with first sliding rods 803, the two ends of the connecting plate 9 are provided with second sliding rods 901, and the first sliding rods 803 and the second sliding rods 901 are arranged inside the waist-shaped sliding holes of the limiting blocks 102 in a vertical sliding mode.

As shown in fig. 7, a liquid nitrogen supply pipe 601 and a nitrogen recovery pipe 602 are connected to the cavities inside the upper end rapid cooling plate 4 and the lower end rapid cooling plate 5, and the liquid nitrogen supply pipe 601 and the nitrogen recovery pipe 602 are connected to the liquid nitrogen preparation system 6.

The tail end of the liquid nitrogen supply pipe 601 is provided with an upper end liquid nitrogen branch pipe 6011 and a lower end liquid nitrogen branch pipe 6012, the upper end liquid nitrogen branch pipe 6011 and the lower end liquid nitrogen branch pipe 6012 respectively penetrate through the upper end quick cooling plate 4 and the lower end quick cooling plate 5,

the upper end liquid nitrogen branch pipe 6011 located inside the upper end rapid cooling plate 4 is connected with a plurality of liquid spraying pipes 60111 in a penetrating mode, the spraying holes of the liquid spraying pipes 60111 are arranged downwards, namely the spraying holes can directly spray liquid nitrogen to the upper end heat dissipation strips 401, the liquid nitrogen can conveniently and rapidly absorb heat and then gasify, and the temperature of the inside of the heat preservation shell 1 is reduced.

The lower end liquid nitrogen branch pipe 6012 also has a plurality of liquid spray pipes located inside the lower end rapid cooling plate 5, and the arrangement mode of spray holes of the liquid spray pipes is the same as that of the spray holes of the liquid pipe 60111.

The tail end of the nitrogen recovery pipe 602 is provided with an upper end nitrogen recovery branch pipe 6021 and a lower end nitrogen recovery branch pipe 6022, the upper end nitrogen recovery branch pipe 6021 and the lower end nitrogen recovery branch pipe 6022 respectively penetrate through the upper end rapid cooling plate 4 and the lower end rapid cooling plate 5, and the nitrogen recovery pipe 602 is provided with a first pipeline air pump 603.

The liquid nitrogen preparation system 6 adopts the prior art, and comprises a gaseous nitrogen recovery box 6a, a nitrogen liquefaction device 6b and a liquid nitrogen storage device 6c, wherein the gaseous nitrogen recovery box 6a, the nitrogen liquefaction device 6b and the liquid nitrogen storage device 6c are connected in sequence through pipelines. The gaseous nitrogen recovery tank 6a is connected to a nitrogen recovery pipe 602, and the liquid nitrogen storage device 6c is connected to a liquid nitrogen supply pipe 601 via a high-pressure pump.

The front end of the heat preservation shell 1 is provided with a feeding top plate 2, a feeding channel 201 is arranged below the feeding top plate 2, and the feeding channel 201 is communicated with the glass inlet 103. At least one thickness sensor 202 is arranged on the feeding top plate 2, three thickness sensors 2020 are adopted in the embodiment, the thickness sensors 202 detect the thickness of glass to be fed into the heat-insulating shell 1, detected data are transmitted to the control device 15, and the cooling time and the cooling temperature corresponding to different glass thicknesses are different.

The feeding top plate 2 is covered on the conveying belt of the glass heating furnace, in order to facilitate the glass to enter the feeding channel 201, two sides of the inlet of the feeding channel 201 are respectively provided with a guide roller 203 which is vertically arranged, the guide rollers 203 rotate around a support rod 2031 at the center of the guide rollers, and the support rod 2031 is fixedly connected with the feeding top plate 2.

A feeding end upper air curtain strip 204 is arranged above the junction of the feeding channel 201 and the glass inlet 103, a feeding end lower air curtain strip 205 is arranged below the junction, a feeding end upper air curtain channel 2041 is concavely arranged on the bottom surface of the feeding end upper air curtain strip 204, and a feeding end lower air curtain air collecting channel 2051 is concavely arranged on the top surface of the feeding end lower air curtain strip 205. As shown in fig. 4, in order to facilitate the air discharged from the upper air curtain passage 2041 at the feeding end to be completely blown into the lower air curtain gas collecting passage 2051 at the feeding end, inclined planes are arranged on two sides of the upper port of the lower air curtain gas collecting passage 2051 at the feeding end, so that the opening of the inclined planes is larger than that of the upper air curtain passage 2041 at the feeding end.

The rear end of the heat preservation shell 1 is provided with a discharging supporting plate 3, the top surface of the discharging supporting plate 3 is flush with the bottom surface of the glass outlet 104, a discharging end upper air curtain strip 301 is arranged above the junction of the discharging supporting plate 3 and the glass outlet 104, a discharging end lower air curtain strip 302 is arranged below the junction, a discharging end upper air curtain channel 3011 is arranged in the concave bottom surface of the discharging end upper air curtain strip 301, and a discharging end lower air curtain air collecting channel 3021 is arranged in the concave top surface of the discharging end lower air curtain strip 302. The opening of the air curtain air collecting channel 3021 at the lower part of the discharge end is larger than the opening of the air curtain channel 3011 at the upper part of the discharge end, which is the same as the opening at the feed end.

The air curtain air inlet main pipe 10 is respectively communicated with the air curtain passage 2041 at the upper part of the feeding end and the air curtain passage 3011 at the upper part of the discharging end through two air curtain air inlet branch pipes 1001, a second pipeline air pump 1002 is arranged on the air curtain air inlet main pipe 10,

the air curtain air outlet main pipe 11 is respectively communicated with the feed end lower air curtain air collecting channel 2051 and the discharge end lower air curtain air collecting channel 3021 through the two air curtain air outlet branch pipes 1101.

In order to accelerate the cooling speed of the temperature inside the heat preservation shell 1, a cold air inlet 105 and a cold air outlet 106 are respectively arranged on the inner walls of the left side and the right side of the heat preservation shell 1 in a concave mode, a cold air inlet pipe 12 outside the heat preservation shell 1 is communicated with the cold air inlet 105, and a cold air outlet pipe 13 outside the heat preservation shell 1 is communicated with the cold air outlet 106.

The through connection part of the cold air inlet pipe 12 and the cold air inlet 105 and the through connection part of the cold air outlet pipe 13 and the cold air outlet 106 are both positioned above the heat preservation shell 1. A conical air guiding cover 1201 is arranged at the through connection position of the cold air outlet pipe 13 and the cold air outlet 106, and a conical air collecting cover 1302 is arranged at the through connection position of the cold air outlet pipe 13 and the cold air outlet 106. The wind scooper 1201 and the wind collecting cover 1302 are in a truncated cone shape, and wind resistance can be reduced.

Referring to fig. 9 to 11, at least two spiral pipes 1202 are provided at the end of the cool air inlet pipe 12, and three spiral pipes 1202 are used in this embodiment. Two adjacent spiral pipes 1202 are connected in a penetrating way through a detection temperature adjusting pipe 1203, and the tail end spiral pipe 1202 is connected in a penetrating way with an air outlet of a fan 1206 in the air box 14 through the detection temperature adjusting pipe 1203.

Detect temperature regulation pipe 1203 on be equipped with temperature sensor 1204 and liquid nitrogen in proper order along the air current direction and add pipe 1205, liquid nitrogen add pipe 1205 and liquid nitrogen storage device 6c through connection, be equipped with automatically controlled governing valve 12051 on the liquid nitrogen adds the pipe 1205, liquid nitrogen adds the pipe 1205 and is located the inside one end of detection streak pipe 1203 and is equipped with the atomizer.

The tail end of the cold air outlet pipe 13 is communicated with the air box 14, and a third pipeline air suction pump 1301 is arranged on the cold air outlet pipe 13.

The photoelectric correlation sensor group 101, the thickness sensor 202, the liquid nitrogen preparation system 6, the first pipeline air pump 603, the lifting device 801, the driving device 802, the second pipeline air pump 1002, the temperature sensor 1204, the electric control regulating valve 12051, the fan 1206 and the third pipeline air pump 1301 are respectively electrically connected with the control device 15.

A quick cooling method for producing high-strength glass comprises the following steps:

A. the feeding top plate 2 is covered on a conveying belt at the tail end of a heating furnace for glass production, the tail end of the conveying belt is contacted with the heat-insulating shell 1, the heated glass is conveyed into the heat-insulating shell 1 through a glass inlet 103, and the conveying roller 7 in the heat-insulating shell 1 is in relay to completely move the glass into the heat-insulating shell 1;

when glass just enters the glass inlet 103, signals of the photoelectric correlation sensor group 101 on the glass inlet 103 are shielded, after the glass completely enters the heat-insulating shell 1 through the glass inlet 103, the signals of the photoelectric correlation sensor group 101 are communicated, and whether the glass completely enters the heat-insulating shell 1 or not can be known through signal conversion of the photoelectric correlation sensor group 101;

B. after the glass completely enters the heat insulation shell 1, the lifting device 801 drives the conveying roller 7 to move downwards through the driving box 8, and the bottom surface of the glass is contacted with the top surface of the lower-end heat dissipation strip 501;

C. the air curtain air inlet header pipe 10 introduces high-pressure air into the feeding end upper air curtain channel 2041 and the discharging end upper air curtain channel 3011, forms air curtains outside the glass inlet 103 and the glass outlet 104, and seals the interior of the heat preservation shell 1 through the air curtains;

D. the liquid nitrogen supply pipe 601 sprays liquid nitrogen into the upper end quick cooling plate 4 and the lower end quick cooling plate 5, and the liquid nitrogen absorbs heat and is exhausted through the nitrogen recovery pipe 602 after being gasified.

The liquid nitrogen is gasified to take away a large amount of heat, so that the temperature in the heat-insulating shell 1 is rapidly reduced, and the glass is rapidly cooled;

E. the fan 1206 leads the gas in the gas box 14 into the heat-insulating shell 1 through the cold gas inlet pipe 12, then the gas flows back to the gas box 14 again through the cold gas outlet pipe 13, the temperature sensor 1204 detects the temperature of the gas flow, the liquid nitrogen adding pipe 1205 adds liquid nitrogen into the gas flow to reduce the temperature of the gas flow, and the spiral pipe 1202 is convenient for the liquid nitrogen to be mixed with the gas flow;

F. the time that the glass with different thicknesses needs to be cooled is different, the rear end sensor 202 detects the thickness of the glass, the staying time of the glass in the heat preservation shell 1 is set according to the thickness of the glass, and after the staying time is reached, the conveying roller 7 is lifted up, and the glass is conveyed to the discharging supporting plate 3.

The embodiments of the present invention have been described in detail with reference to the drawings, but the present invention is not limited to the above embodiments, and various changes can be made within the knowledge of those skilled in the art without departing from the gist of the present invention.