CN112757769B

CN112757769B - Flexible glass printing drying device

Info

Publication number: CN112757769B
Application number: CN202011604602.XA
Authority: CN
Inventors: 陈双; 张志才; 车友龙; 严小明
Original assignee: Jiangsu Anpu Optical Technology Co ltd
Current assignee: Jiangsu Anpu Optical Technology Co ltd
Priority date: 2020-12-30
Filing date: 2020-12-30
Publication date: 2021-09-24
Anticipated expiration: 2040-12-30
Also published as: CN112757769A

Abstract

The invention discloses a flexible glass printing and drying device, which comprises: a housing; the inlet and the outlet are oppositely arranged at the side end of the shell; the conveying unit is arranged in the shell, and two ends of the conveying unit extend out of the inlet and the outlet; the first-stage drying unit, the cooling unit and the second-stage drying unit are sequentially arranged in the shell along the walking direction of the conveying unit. One-level stoving unit, cooling unit and the integration installation of second grade stoving unit are in the casing, thereby make the stoving, the cooling, the three processes of stoving are all concentrated on same space and are accomplished, remove the link that glass made a round trip to transport from, thereby the possibility of introducing impurity in the transportation process has been avoided, one-level stoving unit, the cooling unit, and the setting of second grade stoving unit accelerates the stoving process, and the efficiency of drying is improved, axial fan still installs on the casing, axial fan can take out the volatile substance that the stoving produced in the casing fast.

Description

Flexible glass printing drying device

Technical Field

The invention relates to the technical field of flexible glass production, in particular to a flexible glass printing and drying device.

Background

The back needs are dried to the printing pattern after flexible glass prints to printing pattern shaping in flexible glass surface with higher speed, current flexible glass stoving line, glass stoving back, need transport to get to the appointed place and go the natural cooling or move and go the cooling on the cooling line and cool off, the process of a plurality of transports in the middle, in the transportation, cause very easily that the floating impurity in the space is stained with and attaches on the glass surface.

Disclosure of Invention

In order to achieve the purpose, the invention discloses a flexible glass printing and drying device, which comprises:

a housing;

the inlet and the outlet are oppositely arranged at the side end of the shell;

the conveying unit is arranged in the shell, and two ends of the conveying unit extend out of the inlet and the outlet;

the drying device comprises a primary drying unit, a cooling unit and a secondary drying unit, wherein the primary drying unit, the cooling unit and the secondary drying unit are sequentially arranged in the shell along the walking direction of the conveying unit.

Preferably, the secondary drying unit is a dryer.

Preferably, the cooling unit is an air cooling machine.

Preferably, the primary drying unit includes:

the air supply ring seat is embedded at the top end of the shell;

the hot air device is positioned above the air supply ring seat;

the air supply device is positioned below the air supply ring seat, and the inner ring end of the air supply ring seat is communicated with the hot air device and the air supply device;

the plywood storage chamber is circumferentially arranged in the air supply ring seat by taking the inner ring end of the air supply ring seat as a center;

the two connecting blocks are symmetrically arranged in the plywood containing chamber by taking the inner ring end of the air supply ring seat as the center;

the two opening plates are spliced into a circle and cover the inner ring end of the air supply ring seat, and the opening plates penetrate through the air supply ring seat inner ring end into the opening plate accommodating chamber and are fixedly connected with the connecting blocks;

one end of the reset spring is connected with the end, far away from the opening and closing plate, of the connecting block, and the other end of the reset spring is connected with the inner wall of the opening and closing plate containing chamber;

the chute is arranged on the connecting block, and the lower end of the chute is close to the opening plate;

the two support rods are symmetrically connected between the hot air device and the air supply device by taking the inner ring end of the air supply ring seat as a center, and the support rods penetrate through the storage chamber of the opening plate;

the sliding block is connected in the chute in a sliding mode and fixedly connected to the supporting rod.

Preferably, the hot air device includes:

the end of the supporting rod, far away from the air supply device, is connected with the fixed plate;

the resistance heating rods are arranged at the bottom end of the fixing plate in parallel;

the air inlet holes are uniformly formed in the fixing plate;

the filter screen is arranged on the top end of the fixing plate in a covering manner;

the hot air box is made of flexible telescopic pipes and is installed between the fixed plate and the air supply ring seat, the resistance heating rod cover is arranged at the top end of the hot air box, and the inner ring end cover of the air supply ring seat is arranged at the bottom end of the hot air box.

Preferably, the outer wall of the hot air box is wrapped with a heat insulation layer.

Preferably, the air blowing device includes:

the end, far away from the fixed plate, of the support rod is connected with the lifting plate;

the air inlet is formed in the lifting plate;

the air duct is arranged between the air supply ring seat and the lifting plate, the top end of the air duct is connected with the inner ring end of the air supply ring seat, and the bottom end of the air duct is connected with the air inlet;

the air supply seat is fixedly arranged at the bottom end of the lifting plate;

the air inlet chamber is arranged in the air supply seat, and the air inlet is communicated with the air inlet chamber;

the motor installation chamber, the turntable installation chamber and the fan installation chamber are sequentially arranged in the air supply seat from top to bottom;

the first air channel is arranged in the air supply seat and communicated with the air inlet chamber and the fan installation chamber;

the air outlet is formed in the bottom end of the air supply seat and communicated with the fan installation chamber;

the driving motor is arranged in the motor installation chamber;

the first rotating shaft is arranged at the output end of the driving motor, and the first rotating shaft penetrates through the turntable installation chamber and the fan installation chamber;

the first fan is arranged in the fan installation chamber and is installed on the first rotating shaft;

the rotary disc mounting shell is arranged in the rotary disc mounting chamber and can be rotatably sleeved on the first rotating shaft;

the rotary disc is arranged in the rotary disc mounting shell and fixedly connected to the first rotating shaft;

the telescopic grooves are circumferentially distributed at the side end of the rotating disc by taking the first rotating shaft as a center;

the centrifugal block is arranged at the bottom end of the telescopic groove through a first spring;

the fixed latch is arranged at the end, far away from the first spring, of the centrifugal block;

the rotating ring is rotatably connected in the rotating disc mounting shell through a limiting ring seat, and the rotating disc is positioned at the inner ring end of the rotating ring;

the connecting latch is circumferentially arranged at the inner ring end of the rotating ring and is matched with the fixed latch;

the rotating teeth are circumferentially arranged at the outer ring end of the rotating ring;

the first gears are circumferentially distributed in the rotary disc mounting shell by taking a first rotating shaft as a center, and are meshed with the rotating teeth;

the end, far away from the first gear, of the second rotating shaft penetrates through the turntable mounting shell and the turntable mounting chamber and extends into the fan mounting chamber;

and the second fan is arranged in the fan mounting chamber and is mounted on the second rotating shaft.

Preferably, the method further comprises the following steps:

the belt wheel installation chamber is arranged in the air supply seat, the belt wheel installation chamber is positioned between the motor installation chamber and the turntable installation chamber, and the first rotating shaft penetrates through the belt wheel installation chamber;

the turnover plate adjusting chamber is arranged in the air supply seat and is close to the air outlet;

one end of the third rotating shaft extends into the belt wheel mounting chamber, and the other end of the third rotating shaft extends into the folded plate adjusting chamber;

the two belt wheels are arranged in the belt wheel installation chambers, one belt wheel is installed on the third rotating shaft, and the other belt wheel is installed on the first rotating shaft;

the conveying belt is sleeved on the two belt wheels;

the mounting disc is arranged in the folded plate adjusting chamber and is mounted on the third rotating shaft;

the two shifting blocks are symmetrically distributed on the mounting disc by taking the third rotating shaft as a center, and the shifting blocks are arranged close to the edge end of the mounting disc;

the rotary drum is arranged in the folded plate adjusting chamber through a rotary shaft, the rotary drum and the third rotary shaft are arranged in parallel, and the rotary drum is arranged close to the air outlet;

the shifting rod and the connecting rod are distributed at the side end of the rotary drum in an acute angle, and the shifting rod is matched with the shifting block;

the strip-shaped hole is formed in the connecting rod;

the sliding column is connected in the strip-shaped hole in a sliding manner;

the ejector rod is slidably installed in the folding plate adjusting chamber, one end of the ejector rod penetrates through the folding plate adjusting chamber and extends into the air outlet, and the sliding column is installed on the ejector rod;

the return column is mounted on the ejector rod and is matched with the shifting block;

the wind direction plate is hinged to the bottom end of the air supply seat and is arranged close to the air outlet;

and one end of the turnover arm is hinged with the inner end of the wind direction plate, and the other end of the turnover arm is hinged with the ejector rod.

Preferably, the method further comprises the following steps:

the rotating rod platform is arranged at the top end of the air supply seat;

the spline shaft is vertically arranged on the rotating rod platform, extends into the belt wheel installation chamber and is connected with one belt wheel, and the spline shaft and the third rotating shaft are coaxially arranged;

the spline sleeve is sleeved at the end, far away from the belt wheel, of the spline shaft, penetrates through the lifting plate and is rotatably connected with the bottom end of the shell through the bearing mounting seat;

the rotating rods are arranged in the rotating rod platform, and the rotating rods are circumferentially hinged on the spline sleeve by taking the spline shaft as a center;

the return torsion spring is sleeved at the hinged end of the rotating rod close to the spline sleeve, one torsion arm of the return torsion spring is fixedly connected with the rotating rod, and the other torsion arm of the return torsion spring is fixedly connected with the spline sleeve;

the steel ball, the steel ball install in on the bull stick, the steel ball supports the lifter plate bottom and sets up.

Preferably, the conveying unit is a mesh belt conveyor.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

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

FIG. 2 is a schematic structural diagram of a primary drying unit;

FIG. 3 is an enlarged view of reference character A in FIG. 2;

fig. 4 is a top view of the inside of the flap adjusting chamber.

In the figure: 1. a housing; 2. a conveying unit; 3. a primary drying unit; 4. a cooling unit; 5. a secondary drying unit; 11. an inlet; 12. an outlet; 31. an air supply ring seat; 32. a hot air device; 33. an air supply device; 34. a plywood storage room; 35. connecting blocks; 36. opening and closing the board; 37. a return spring; 38. a chute; 39. a support bar; 30. a slider; 41. a fixing plate; 42. a resistance heating rod; 43. an air inlet hole; 44. a hot air box; 45. a lifting plate; 46. an air supply seat; 47. an air inlet; 48. an air duct; 49. an air inlet chamber; 40. a turntable installation chamber; 51. a fan installation chamber; 52. a drive motor; 53. a first rotating shaft; 54. a first fan; 55. a first air duct; 56. an air outlet; 57. a turntable; 58. a telescopic groove; 59. a centrifugal block; 50. a first spring; 61. rotating the ring; 62. a first gear; 63. a second rotating shaft; 64. a second fan; 65. a flap plate adjustment chamber; 66. a pulley installation chamber; 67. a third rotating shaft; 68. a pulley; 69. a conveyor belt; 60. mounting a disc; 71. shifting blocks; 72. a rotating drum; 73. a deflector rod; 74. a connecting rod; 75. a strip-shaped hole; 76. a sliding post; 77. a top rod; 78. a return post; 79. a wind vane; 70. a turning arm; 81. a turn bar platform; 82. a spline shaft; 83. a spline housing; 84. a rotating rod; 85. and (5) steel balls.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. 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.

Examples

The invention will be further described with reference to the accompanying drawings.

As shown in fig. 1, the flexible glass printing and drying device provided in this embodiment includes:

a housing 1;

the inlet 11 and the outlet 12 are oppositely arranged at the side end of the shell 1;

the conveying unit 2 is arranged in the shell 1, and two ends of the conveying unit 2 extend out of the inlet 11 and the outlet 12;

the drying device comprises a primary drying unit 3, a cooling unit 4 and a secondary drying unit 5, wherein the primary drying unit 3, the cooling unit 4 and the secondary drying unit 5 are sequentially arranged in the shell 1 along the walking direction of the conveying unit 2.

The working principle and the beneficial effects of the technical scheme are as follows:

the invention discloses a flexible glass printing and drying device, wherein a primary drying unit 3, a cooling unit 4 and a secondary drying unit 5 are integrally arranged in a shell 1, so that three processes of drying, cooling and drying are completed in the same space, and the link of back-and-forth transfer of glass is avoided, so that the possibility of introducing impurities in the transfer process is avoided, the primary drying unit 3, the cooling unit 4 and the secondary drying unit 5 are arranged to accelerate the drying process and improve the drying efficiency, an axial flow fan is also arranged on the shell 1, and when the drying device works, the axial flow fan can quickly extract volatile matters generated by drying from the shell 1.

In one embodiment, the secondary drying unit 5 is a dryer.

In one embodiment, the cooling unit 4 is an air-cooled machine.

As shown in fig. 2 to 4, in one embodiment, the primary drying unit 3 includes:

the air supply ring seat 31 is embedded at the top end of the shell 1;

the hot air device 32, the hot air device 32 is located above the air supply ring seat 31;

the air supply device 33 is positioned below the air supply ring seat 31, and the inner ring end of the air supply ring seat 31 is communicated with the hot air device 32 and the air supply device 33;

a cut-off plate storage chamber 34, wherein the cut-off plate storage chamber 34 is circumferentially arranged in the air supply ring seat 31 by taking the inner ring end of the air supply ring seat 31 as a center;

the two connecting blocks 35 are symmetrically arranged in the plywood accommodating chamber 34 by taking the inner ring end of the air supply ring seat 31 as a center;

the two opening plates 36 are spliced into a circle and cover the inner ring end of the air supply ring seat 31, and the opening plates 36 penetrate through the air supply ring seat 31 from the inner ring end and are arranged in the opening plate accommodating chamber 34 and fixedly connected with the connecting block 35;

one end of the return spring 37 is connected with the end, far away from the opening plate 36, of the connecting block 35, and the other end of the return spring 37 is connected with the inner wall of the opening plate accommodating chamber 34;

the chute 38 is arranged on the connecting block 35, and the lower end of the chute 38 is close to the opening plate 36;

the two support rods 39 are symmetrically connected between the hot air device 32 and the air supply device 33 by taking the inner ring end of the air supply ring seat 31 as a center, and the support rods 39 penetrate through the plywood storage chamber 34;

the sliding block 30 is slidably connected in the inclined groove 38, and the sliding block 30 is fixedly connected to the supporting rod 39.

Wherein, the hot air device 32 includes:

the fixing plate 41 is connected with the end, far away from the air supply device 33, of the supporting rod 39;

a plurality of resistance heating rods 42, the resistance heating rods 42 being installed in parallel at the bottom end of the fixing plate 41;

a plurality of air inlet holes 43, wherein the air inlet holes 43 are uniformly arranged on the fixing plate 41;

the filter screen is arranged at the top end of the fixing plate 41 in a covering manner;

the hot air box 44 is made of a flexible telescopic pipe material, the hot air box 44 is installed between the fixed plate 41 and the air supply ring seat 31, the resistance heating rod 42 is covered at the top end of the hot air box 44, and the inner ring end of the air supply ring seat 31 is covered at the bottom end of the hot air box 44.

Wherein, the outer wall of the hot air box 44 is wrapped with an insulating layer.

Wherein the air blowing device 33 includes:

the end, far away from the fixed plate 41, of the supporting rod 39 is connected with the lifting plate 45;

the air inlet 47 is formed in the lifting plate 45;

the air duct 48 is arranged between the air supply ring seat 31 and the lifting plate 45, the top end of the air duct 48 is connected with the inner ring end of the air supply ring seat 31, and the bottom end of the air duct 48 is connected with the air inlet 47;

the air supply seat 46 is fixedly arranged at the bottom end of the lifting plate 45;

the air inlet chamber 49 is arranged in the air supply seat 46, and the air inlet 47 is communicated with the air inlet chamber 49;

the air supply device comprises a motor installation chamber, a turntable installation chamber 40 and a fan installation chamber 51, wherein the motor installation chamber, the turntable installation chamber 40 and the fan installation chamber 51 are sequentially arranged in the air supply seat 46 from top to bottom;

the first air duct 55 is arranged in the air supply seat 46, and the first air duct 55 is communicated with the air inlet chamber 49 and the fan installation chamber 51;

the air outlet 56 is formed in the bottom end of the air supply seat 46, and the air outlet 56 is communicated with the fan installation chamber 51;

the driving motor 52, the said driving motor 52 is installed in the motor installation chamber;

the first rotating shaft 53 is installed at the output end of the driving motor 52, and the first rotating shaft 53 penetrates through the turntable installation chamber 40 and the fan installation chamber 51;

a first fan 54, the first fan 54 being provided in the fan installation chamber 51, the first fan 54 being installed on the first rotation shaft 53;

the turntable mounting shell is arranged in the turntable mounting chamber 40 and is rotatably sleeved on the first rotating shaft 53;

the turntable 57 is arranged in the turntable mounting shell, and the turntable 57 is fixedly connected to the first rotating shaft 53;

a plurality of telescopic slots 58 circumferentially distributed at the side end of the turntable 57 with the first rotating shaft 53 as the center;

the centrifugal block 59 is mounted at the bottom end of the telescopic groove 58 through a first spring 50;

the fixed latch is arranged at the end, far away from the first spring 50, of the centrifugal block 59;

the rotating ring 61 is rotatably connected into the rotating disc mounting shell through a limiting ring seat, and the rotating disc 57 is positioned at the inner ring end of the rotating ring 61;

the connecting latch is circumferentially arranged at the inner ring end of the rotating ring 61 and is matched with the fixed latch;

the rotating teeth are circumferentially arranged at the outer ring end of the rotating ring 61;

a plurality of first gears 62 circumferentially distributed in the turntable mounting housing around the first rotating shaft 53, wherein the first gears 62 are engaged with the rotating teeth;

the second rotating shaft 63 is connected with the first gear 62, and the end of the second rotating shaft 63, which is far away from the first gear 62, penetrates through the turntable mounting shell and the turntable mounting chamber 40 and extends into the fan mounting chamber 51;

and a second fan 64, wherein the second fan 64 is disposed in the fan installation chamber 51, and the second fan 64 is installed on the second rotating shaft 63.

Wherein, still include:

a pulley installation chamber 66, wherein the pulley installation chamber 66 is arranged in the air supply base 46, the pulley installation chamber 66 is positioned between the motor installation chamber and the turntable installation chamber 40, and the first rotating shaft 53 penetrates through the pulley installation chamber 66;

the folded plate adjusting chamber 65 is arranged in the air supply seat 46, and the folded plate adjusting chamber 65 is arranged close to the air outlet 56;

one end of the third rotating shaft 67 extends into the belt wheel mounting chamber 66, and the other end of the third rotating shaft 67 extends into the turnover plate adjusting chamber 65;

two pulleys 68, wherein one pulley 68 is mounted on the third rotating shaft 67, and the other pulley 68 is mounted on the first rotating shaft 53;

the conveying belt 69 is sleeved on the two belt wheels 68;

the mounting disc 60 is arranged in the folded plate adjusting chamber 65, and the mounting disc 60 is mounted on the third rotating shaft 67;

the two shifting blocks 71 are symmetrically distributed on the mounting disc 60 by taking the third rotating shaft 67 as a center, and the shifting blocks 71 are arranged close to the edge end of the mounting disc 60;

a drum 72, wherein the drum 72 is installed in the flap adjusting chamber 65 through a rotating shaft, the drum 72 is arranged in parallel with the third rotating shaft 67, and the drum 72 is arranged near the air outlet 56;

the shifting rod 73 and the connecting rod 74 are distributed at the side end of the rotary drum 72 in an acute angle, and the shifting rod 73 is matched with the shifting block 71;

the strip-shaped hole 75 is formed in the connecting rod 74;

the sliding column 76 is connected in the strip-shaped hole 75 in a sliding manner;

the ejector rod 77 is slidably mounted in the folded plate adjusting chamber 65, one end of the ejector rod 77 penetrates through the folded plate adjusting chamber 65 and extends into the air outlet 56, and the sliding column 76 is mounted on the ejector rod 77;

the return column 78, the return column 78 is installed on the top rod 77, and the return column 78 is matched with the dial block 71;

the wind direction plate 79 is hinged to the bottom end of the air supply seat 46, and the wind direction plate 79 is arranged close to the air outlet 56;

and one end of the turnover arm 70 is hinged with the inner end of the wind direction plate 79, and the other end of the turnover arm 70 is hinged with the ejector rod 77.

Wherein, still include:

the rotating rod platform 81 is arranged at the top end of the air supply seat 46;

the spline shaft 82 is vertically installed on the rotating rod platform 81, the spline shaft 82 extends into the belt wheel installation chamber 66 and is connected with one belt wheel 68, and the spline shaft 82 and the third rotating shaft 67 are coaxially arranged;

the spline sleeve 83 is sleeved at the end, far away from the belt wheel 68, of the spline shaft 82, and the spline sleeve 83 penetrates through the lifting plate 45 and is rotatably connected with the bottom end of the shell 1 through a bearing mounting seat;

the rotating rods 84 are arranged in the rotating rod platform 81, and the rotating rods 84 are circumferentially hinged on the spline housing 83 by taking the spline shaft 82 as a center;

the return torsion spring is sleeved at the hinged end of the rotating rod 84 close to the spline sleeve 83, one torsion arm of the return torsion spring is fixedly connected with the rotating rod 84, and the other torsion arm of the return torsion spring is fixedly connected with the spline sleeve;

and the steel ball 85 is arranged on the rotating rod 84, and the steel ball 85 is abutted against the bottom end of the lifting plate 45.

the driving motor 52 installed in the motor installation chamber operates to drive the first rotating shaft 53 installed at the output end of the driving motor 52 to rotate, and further drive the belt wheel 68, the rotating disc 57, and the first fan 54 coaxially installed on the first rotating shaft 53 to rotate, a negative pressure is formed in the fan installation chamber 51, external air is sent into the hot air box 44 through the air inlet hole 43, and is sent into the fan installation chamber 51 from the inner ring end of the air supply ring seat 31, the air duct 48, the air inlet 47, the air inlet chamber 49, and the first air duct 55, and is blown out from the air outlet 56, at this time, the resistance heating rod 42 operates to heat the air sent into the hot air box 44 from the air inlet hole 43, and further to blow out hot air from the air outlet 56, when the belt wheel 68 rotates, the third rotating shaft 67 and the spline shaft 82 installed on the other belt wheel 68 are driven to rotate by the conveyor belt 69, the third rotating shaft 67 drives the installation disc 60 installed thereon to rotate in the plate turnover adjustment chamber 65, when the mounting plate 60 rotates counterclockwise, the dial block 71 drives the rotary drum 72 and the connecting rod 74 connected with the rotary drum 72 to rotate clockwise through the dial rod 73, under the action of the strip-shaped hole 75 and the sliding column 76, the ejector rod 77 connected with the sliding column 76 is driven to extend into the air outlet 56, the turning arm 70 drives the wind direction plate 79 to turn downwards by taking the hinged end thereof as the center, when the dial block 71 rotates to the position of the turning column 78, the ejector rod 77 returns to the turning plate adjusting chamber 65 to drive the wind direction plate 79 to open and close regularly, so that the hot wind discharged from the air outlet 56 is controlled to move towards the direction close to the outlet 12 along the inlet 11, when the hot wind direction is close to the inlet 11, the external ash can be prevented from entering the housing 1, when the rotating speed of the driving motor 52 is increased, the first rotating shaft 53 is increased, under the centrifugal force, the centrifugal block 59 moves in the telescopic slot 58 towards the direction far away from the bottom end of the telescopic slot 58, and the first spring 50 is stretched, the fixed latch blocks the connecting latch at the inner ring end of the rotating ring 61 to drive the rotating ring 61 to rotate, the rotating latch drives the first gear 62 to rotate in the turntable mounting shell, and further drives the second rotating shaft 63 connected with the first gear 62 and the second fan 64 connected with the second rotating shaft 63 to rotate in the fan mounting chamber 51, so that the rotating speed of the spline shaft 82 is increased while the heat intake is increased, and the spline housing 83 connected with the spline shaft is driven to rotate, when the rotating speed of the spline housing 83 is increased, under the centrifugal force action of the steel ball 85, the included angle between the rotating rod 84 and the spline housing 83 in the rotating rod platform 81 is increased, the lifting plate 45 descends, and the air supply seat 46 is driven to descend, the support rod 39 descends, so as to drive the sliding block 30 to slide downwards in the chute 38, the sliding block 30 moves to the lower end of the chute 38, the return spring 37 contracts under the force, the connecting block 35 drives the open close board 36 to retract into the open close board receiving chamber 34, the two opening plates 36 are opened to open the inner ring end of the air supply ring seat 31, so that the air inlet volume is increased, and synchronously, the fixing plate 41 descends, the hot air box 44 contracts, the fixing plate 41 moves close to the air supply ring seat 31, so that the heating rate is increased, the air supply seat 46 descends close to the conveying unit 2, high-temperature hot air is discharged from the air outlet 56, and the drying efficiency of the primary drying unit 3 is improved.

In one embodiment, the conveying unit 2 is a mesh belt conveyor.

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications therefrom are within the scope of the invention.

Claims

1. The utility model provides a flexible glass printing drying device which characterized in that includes:

a housing (1);

the inlet (11) and the outlet (12) are oppositely arranged at the side end of the shell (1);

the conveying unit (2) is arranged in the shell (1), and two ends of the conveying unit (2) extend out of the inlet (11) and the outlet (12);

the drying device comprises a primary drying unit (3), a cooling unit (4) and a secondary drying unit (5), wherein the primary drying unit (3), the cooling unit (4) and the secondary drying unit (5) are sequentially arranged in a shell (1) along the traveling direction of a conveying unit (2);

the primary drying unit (3) includes:

the air supply ring seat (31), the air supply ring seat (31) is embedded in the top end of the shell (1);

the hot air device (32), the hot air device (32) is positioned above the air supply ring seat (31);

the air supply device (33), the air supply device (33) is positioned below the air supply ring seat (31), and the inner ring end of the air supply ring seat (31) is communicated with the hot air device (32) and the air supply device (33);

the plywood storage chamber (34) is circumferentially arranged in the air supply ring seat (31) by taking the inner ring end of the air supply ring seat (31) as the center;

the two connecting blocks (35) are symmetrically arranged in the plywood containing chamber (34) by taking the inner ring end of the air supply ring seat (31) as the center;

the two opening plates (36) are spliced into a circle and cover the inner ring end of the air supply ring seat (31), and the opening plates (36) penetrate through the inner ring end of the air supply ring seat (31) in the opening plate accommodating chamber (34) and are fixedly connected with the connecting block (35);

one end of the return spring (37) is connected with the end, far away from the opening plate (36), of the connecting block (35), and the other end of the return spring (37) is connected with the inner wall of the opening plate accommodating chamber (34);

the chute (38) is arranged on the connecting block (35), and the low-position end of the chute (38) is close to the opening plate (36);

the two support rods (39) are symmetrically connected between the hot air device (32) and the air supply device (33) by taking the inner ring end of the air supply ring seat (31) as a center, and the support rods (39) penetrate through the plywood storage chamber (34);

the sliding block (30) is connected in the inclined groove (38) in a sliding mode, and the sliding block (30) is fixedly connected to the supporting rod (39).

2. A flexible glass printing drying apparatus according to claim 1, characterized in that the secondary drying unit (5) is a dryer.

3. The flexible glass printing and drying device according to claim 1, wherein the cooling unit (4) is an air cooling machine.

4. The flexible glass printing and drying device according to claim 1, wherein the hot air device (32) comprises:

the end, far away from the air supply device (33), of the support rod (39) is connected with the fixing plate (41);

the resistance heating rods (42), a plurality of resistance heating rods (42) are parallelly arranged at the bottom end of the fixing plate (41);

the air inlet holes (43) are uniformly formed in the fixing plate (41);

the filter screen is arranged at the top end of the fixing plate (41) in a covering manner;

the hot air box (44) is made of flexible telescopic pipes, the hot air box (44) is installed between the fixing plate (41) and the air supply ring seat (31), the resistance heating rod (42) is covered at the top end of the hot air box (44), and the inner ring end of the air supply ring seat (31) is covered at the bottom end of the hot air box (44).

5. The flexible glass printing and drying device as claimed in claim 4, wherein the outer wall of the hot air box (44) is wrapped with an insulating layer.

6. The flexible glass printing and drying device according to claim 4, wherein the air supply device (33) comprises:

the end, far away from the fixed plate (41), of the supporting rod (39) is connected with the lifting plate (45);

the air inlet (47), the said air inlet (47) is set up on the said lifting plate (45);

the air duct (48), the air duct (48) is installed between the air supply ring seat (31) and the lifting plate (45), the top end of the air duct (48) is connected with the inner ring end of the air supply ring seat (31), and the bottom end of the air duct (48) is connected with the air inlet (47);

the air supply seat (46), the air supply seat (46) is fixedly arranged at the bottom end of the lifting plate (45);

the air inlet chamber (49) is arranged in the air supply seat (46), and the air inlet (47) is communicated with the air inlet chamber (49);

the air supply device comprises a motor installation chamber, a turntable installation chamber (40) and a fan installation chamber (51), wherein the motor installation chamber, the turntable installation chamber (40) and the fan installation chamber (51) are sequentially arranged in the air supply seat (46) from top to bottom;

the first air duct (55) is arranged in the air supply seat (46), and the first air duct (55) is communicated with the air inlet chamber (49) and the fan installation chamber (51);

the air outlet (56) is formed in the bottom end of the air supply seat (46), and the air outlet (56) is communicated with the fan installation chamber (51);

the driving motor (52), the said driving motor (52) is installed in the motor installation chamber;

the first rotating shaft (53), the first rotating shaft (53) is installed at the output end of the driving motor (52), and the first rotating shaft (53) penetrates through the turntable installation chamber (40) and the fan installation chamber (51);

a first fan (54), wherein the first fan (54) is arranged in the fan installation chamber (51), and the first fan (54) is installed on the first rotating shaft (53);

the rotary disc mounting shell is arranged in the rotary disc mounting chamber (40), and the rotary disc mounting shell is rotatably sleeved on the first rotating shaft (53);

the rotary disc (57) is arranged in the rotary disc mounting shell, and the rotary disc (57) is fixedly connected to the first rotating shaft (53);

the telescopic grooves (58) are circumferentially distributed at the side end of the rotating disc (57) by taking the first rotating shaft (53) as a center;

the centrifugal block (59) is mounted at the bottom end of the telescopic groove (58) through a first spring (50);

the fixed latch is arranged at the end, away from the first spring (50), of the centrifugal block (59);

the rotating ring (61) is rotatably connected into the rotating disc mounting shell through a limiting ring seat, and the rotating disc (57) is positioned at the inner ring end of the rotating ring (61);

the connecting latch is circumferentially arranged at the inner ring end of the rotating ring (61), and the connecting latch is matched with the fixed latch;

the rotating teeth are circumferentially arranged at the outer ring end of the rotating ring (61);

the first gears (62) are circumferentially distributed in the rotary disc mounting shell by taking a first rotating shaft (53) as a center, and the first gears (62) are meshed with the rotating teeth;

the second rotating shaft (63), the second rotating shaft (63) is connected with the first gear (62), and the end of the second rotating shaft (63) far away from the first gear (62) penetrates through the turntable mounting shell and the turntable mounting chamber (40) and extends into the fan mounting chamber (51);

and a second fan (64), wherein the second fan (64) is arranged in the fan installation chamber (51), and the second fan (64) is installed on the second rotating shaft (63).

7. The flexible glass printing and drying device of claim 6, further comprising:

the belt wheel installation chamber (66) is arranged in the air supply seat (46), the belt wheel installation chamber (66) is positioned between the motor installation chamber and the turntable installation chamber (40), and the first rotating shaft (53) penetrates through the belt wheel installation chamber (66);

the flap plate adjusting chamber (65), the flap plate adjusting chamber (65) is arranged in the air supply seat (46), and the flap plate adjusting chamber (65) is arranged close to the air outlet (56);

one end of the third rotating shaft (67) extends into the belt wheel mounting chamber (66), and the other end of the third rotating shaft (67) extends into the folded plate adjusting chamber (65);

two belt wheels (68), wherein the two belt wheels (68) are arranged in the belt wheel installation chamber (66), one belt wheel (68) is installed on the third rotating shaft (67), and the other belt wheel (68) is installed on the first rotating shaft (53);

the conveying belt (69) is sleeved on the two belt wheels (68);

the mounting disc (60) is arranged in the folded plate adjusting chamber (65), and the mounting disc (60) is mounted on the third rotating shaft (67);

the two shifting blocks (71) are symmetrically distributed on the mounting disc (60) by taking the third rotating shaft (67) as a center, and the shifting blocks (71) are arranged close to the edge end of the mounting disc (60);

a rotating drum (72), wherein the rotating drum (72) is installed in the flap plate adjusting chamber (65) through a rotating shaft, the rotating drum (72) and a third rotating shaft (67) are arranged in parallel, and the rotating drum (72) is arranged close to the air outlet (56);

the lifting rod (73) and the connecting rod (74) are distributed at the side end of the rotating cylinder (72) in an acute angle, and the lifting rod (73) is matched with the lifting block (71);

the strip-shaped hole (75) is formed in the connecting rod (74);

the sliding column (76), the sliding column (76) is connected in the strip-shaped hole (75) in a sliding manner;

the ejector rod (77) is slidably mounted in the folded plate adjusting chamber (65), one end of the ejector rod (77) penetrates through the folded plate adjusting chamber (65) and extends into the air outlet (56), and the sliding column (76) is mounted on the ejector rod (77);

the return column (78), the return column (78) is installed on the ejector rod (77), and the return column (78) is matched with the shifting block (71);

the wind direction plate (79) is hinged to the bottom end of the air supply seat (46), and the wind direction plate (79) is arranged close to the air outlet (56);

the wind direction plate is hinged to the inner end of the wind direction plate (79), one end of the turnover arm (70) is hinged to the inner end of the wind direction plate (79), and the other end of the turnover arm (70) is hinged to the ejector rod (77).

8. The flexible glass printing and drying device of claim 7, further comprising:

the rotating rod platform (81), the rotating rod platform (81) is arranged at the top end of the air supply seat (46);

the spline shaft (82) is vertically installed on the rotating rod platform (81), the spline shaft (82) extends into the belt wheel installation chamber (66) and is connected with one belt wheel (68), and the spline shaft (82) and the third rotating shaft (67) are coaxially arranged;

the spline sleeve (83) is sleeved at the end, far away from the belt wheel (68), of the spline shaft (82), and the spline sleeve (83) penetrates through the lifting plate (45) and is rotatably connected with the bottom end of the shell (1) through a bearing mounting seat;

the rotating rods (84) are arranged in the rotating rod platform (81), and the rotating rods (84) are circumferentially hinged to the spline housing (83) by taking the spline shaft (82) as a center;

the return torsion spring is sleeved at the hinged end, close to the spline sleeve (83), of the rotating rod (84), one torsion arm of the return torsion spring is fixedly connected with the rotating rod (84), and the other torsion arm of the return torsion spring is fixedly connected with the spline sleeve;

the steel ball (85) is installed on the rotating rod (84), and the steel ball (85) abuts against the bottom end of the lifting plate (45).

9. The flexible glass printing and drying device according to claim 1, wherein the conveying unit (2) is a mesh belt conveyor.