CN116753711A - Mesh belt type food drying device - Google Patents

Abstract

The invention discloses a mesh belt type food drying device, which belongs to the technical field of mesh belt type food drying and comprises a shell, wherein a feed inlet is formed in the upper surface of one end of the shell, a plurality of foot pads are fixedly connected to the lower surface of the shell, a thermal circulation mechanism is fixedly connected to one side of the shell, a material homogenizing lifting mechanism is fixedly connected to one side of the shell, which is close to the feed inlet, a first driving mechanism is fixedly connected to the side surface of one end, which is far away from the feed inlet, of the shell, and a second driving mechanism is fixedly connected to the side surface of one end, which is close to the material homogenizing lifting mechanism, of the shell. According to the invention, the length of the conveying net belt can be adjusted through the cooperation of the adjusting mechanism and the telescopic transmission net belt, so that the material drying time is changed, and the material can be dispersed to two sides through the use of the material homogenizing shaft in the material homogenizing lifting mechanism, so that the material can be conveniently and evenly paved, and the drying effect is better.

Description

Mesh belt type food drying device

Technical Field

The invention belongs to the technical field of mesh-belt type food drying, and particularly relates to a mesh-belt type food drying device.

Background

The mesh-belt type food drying device is a special food drying device. The food drying machine consists of a conveyor belt system and a hot air circulation system, wherein the conveyor belt system usually adopts a metal mesh belt, food to be dried is placed on the conveyor belt system, the food is slowly conveyed from a feeding end to a discharging end through the conveyor belt, so that the food can be ensured to stably move in the whole drying process, and the hot air circulation system generates hot air through a heating device and sends the hot air into a drying chamber through a fan. The hot air flows in the drying chamber, contacts with food, takes away moisture in the food, thereby realizing the purpose of drying, and is also provided with devices such as temperature control, humidity adjustment and the like in a hot air circulation system to adjust temperature and humidity parameters in the drying process, so that the drying effect can be optimized, and the mesh belt type food drying device is widely applied to the food processing industry, such as the drying process of vegetables, fruits, marine products, meat and the like.

Different foods need different time when drying, overlength time leads to the food to be burnt black easily to influence the food quality, and the guipure formula food drying device generally changes the stoving time of food through adjusting guipure speed, need improve the rotational speed of guipure when required stoving time is shorter, and too high guipure rotational speed leads to the food to drop easily, influence production, need pass through the equalizer simultaneously before food gets into the stoving case, with piled up material tiling on the conveyer belt through the equalizer, send into the stoving incasement by the conveyer belt again, the laying of material is the effectual with bad important influence factor of stoving, current equalizer makes the material pave through the extrusion often in the use, lead to laying effect relatively poor, also have certain damage to the material simultaneously.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provide equipment which can adjust the material drying time without adjusting the speed of a net belt and can uniformly lay materials.

The technical scheme adopted for solving the technical problems is as follows: the utility model provides a guipure formula food drying device, includes the shell, the feed inlet has been seted up to the one end upper surface of shell, the lower surface fixedly connected with of shell has a plurality of callus on the sole, one side fixedly connected with thermal cycle mechanism of shell, one side fixedly connected with average material elevating system near the feed inlet of shell, one end side fixedly connected with first actuating mechanism that the shell kept away from the feed inlet, one end side fixedly connected with second actuating mechanism that the shell is close to average material elevating system, both sides of shell are all fixedly connected with adjustment mechanism, but fixedly connected with telescopic driving guipure in the shell, fixedly connected with transports guipure mechanism in the shell, it includes second drive roll and third drive roll to transport guipure mechanism;

the material homogenizing lifting mechanism comprises a side plate, a side plate is fixedly connected to one side of the shell, a driving shaft is rotationally connected to one side of the side plate, which is close to the shell, a second motor is fixedly connected to one side of the side plate, an output end of the second motor is fixedly connected with the driving shaft, one end of the driving shaft, which is far away from the second motor, is fixedly connected with a first driving roller, a first belt is sleeved outside the first driving roller, one end of the first belt, which is far away from the first driving roller, is fixedly sleeved with a first driven roller, one side of the first driven roller is fixedly connected with a driven shaft, one end of the driven shaft, which is far away from the first driven roller, is fixedly connected with a material homogenizing shaft, a strip-shaped protrusion is fixedly connected to one side of the driven shaft, the driving shaft is fixedly sleeved with a lifting belt, the material homogenizing shaft is fixedly sleeved outside the driving shaft, and the strip-shaped protrusion is in a thread shape;

the telescopic transmission net belt comprises a first driving roller, a first driving roller is rotationally connected to one end of a shell, which is close to the first driving roller, a first guide roller is rotationally connected to one end of the shell, which is far away from the first driving roller, a pair of fixing plates are slidably connected to one end of the shell, which is close to the first driving roller, a second bearing is fixedly connected to one end of the fixing plates, which is close to the first driving roller, a second moving roller is fixedly connected to one end of the fixing plates, which is far away from the first driving roller, a first bearing is fixedly connected to one end of the fixing plates, a first moving roller is fixedly connected to the first bearing, a second guide roller is rotationally connected to the position, which is close to the first moving roller, in the shell, and a first net belt is fixedly sleeved outside the first driving roller, the first guide roller, the second guide roller, the first moving roller and the second moving roller.

Through the technical scheme, when materials are lifted on the lifting belt, the strip-shaped protrusions on the material homogenizing shaft jack up the belt and move outwards gradually along with the rotation of the material homogenizing shaft, so that the protrusions drive the materials to disperse towards two sides, the materials are paved more uniformly, the first net belt is sleeved outside the first moving roller and the second moving roller, the net belt is guided through the first guide roller and the second guide roller, the net belt is driven by the first driving roller, the net belt can be folded under the condition that the motion state is not changed, the length of the upper surface of the net belt is changed, and the drying time of the materials in the shell is changed.

Further, the thermal cycle mechanism includes the intake pipe, the upper surface fixedly connected with intake pipe of shell one end fixedly connected with thermal cycle case that the shell was kept away from to the intake pipe, one side fixedly connected with a plurality of outlet ducts that the thermal cycle case is close to the shell, a plurality of inlet ports have been seted up to one side that the shell is close to the outlet duct, outlet duct and inlet port one-to-one, fixedly connected with mount in the outlet duct, fixedly connected with fan on the mount, fixedly connected with a pair of electric plate in the thermal cycle case.

Through above-mentioned technical scheme, can make the air of electric plate heating blow in the shell bottom through the fan, make the hot air upwards move in the shell, with the material contact of downward movement, make the material carry out abundant stoving heating to afterwards get back to the thermal cycle incasement through the admission line, reduce the heat extravagant.

Further, the one end fixedly connected with baffle of second motor is kept away from to the curb plate, the one end inboard that the curb plate is close to the baffle rotates and is connected with first driven voller, first driven voller external fixation cover is equipped with the promotion belt, the one end side fixedly connected with first motor that the curb plate is close to the baffle, the output fixedly connected with homoenergetic roller of first motor, homoenergetic roller external fixation has a plurality of homoenergetic plates, the position that is close to first driven gyro wheel between the curb plate rotates and is connected with the guide bar, the lower surface fixedly connected with support frame of curb plate.

Through above-mentioned technical scheme, first motor drives the homoenergetic roller and rotates, and the homoenergetic roller drives the homoenergetic plate and rotates, makes the material on the promotion belt separate by the homoenergetic plate, promotes the material batch, avoids the material to promote too much, produces and piles up.

Further, a pair of slide ways have all been seted up to both sides in the shell, a pair of first spout has all been seted up to both sides in the shell, a pair of second spout has all been seted up to both sides in the shell, the fixed plate is close to the first arch that moves the equal fixedly connected with in one end outside of roller, the fixed plate is close to the first protruding equal fixedly connected with third arch in one end outside, the fixed plate is close to the second and moves the equal fixedly connected with second arch in one end outside of roller, the mutual sliding fit of second arch and second spout, the mutual sliding fit of first arch and first spout, adjustment mechanism includes the connecting rod, third arch and connecting rod fixed connection, third arch runs through sliding connection slide way.

Through above-mentioned technical scheme, can make fixed plate in shell sliding motion, and the first movable roller that sets up on the fixed plate and second movable roller can drive first guipure folding, through first bellied, the bellied and bellied setting of third of second, can make the fixed plate follow rectilinear motion, avoid the fixed plate to produce rotatoryly, make the support of first guipure more firm.

Further, one side fixedly connected with hydraulic stem of connecting rod, the both ends sliding connection of connecting rod has the slide rail, slide rail and shell fixed connection, the one end fixedly connected with fixed block of connecting rod is kept away from to the hydraulic stem, fixed block and shell fixed connection.

Through above-mentioned technical scheme, can drive the connecting rod through the hydraulic stem, the connecting rod drives the third arch, and the third is protruding to drive the fixed plate and remove, and the scalable transmission guipure of messenger's upper and lower two-layer is flexible simultaneously, and through the setting of slide rail, can make the connecting rod along rectilinear motion at the in-process of fortune work, can not skew.

Further, the first actuating mechanism includes first protective housing, one side fixedly connected with first protective housing of shell, one side fixedly connected with third motor of shell is kept away from to first protective housing, the output fixedly connected with second initiative gyro wheel of third motor, second initiative gyro wheel external fixation cover is equipped with the second belt, the one end that keeps away from second initiative gyro wheel in the first protective housing rotates and is connected with the second driven gyro wheel, second driven gyro wheel external fixation cover is equipped with the second belt, the one end that the second initiative gyro wheel is close to the shell and second initiative roller fixed connection, the one end that the second driven gyro wheel is close to the shell and third initiative roller fixed connection.

Through the technical scheme, the third motor can drive the second driving roller and the third driving roller to rotate, so that the second driving roller and the third driving roller rotate in the same direction.

Further, the second driving mechanism comprises a second protective shell, one side of the shell is fixedly connected with the second protective shell, one side of the second protective shell, which is far away from the shell, is fixedly connected with a fourth motor, the output end of the fourth motor is fixedly connected with a third driving roller, a third belt is fixedly sleeved on the outer surface of the third driving roller, a third driven roller is fixedly sleeved on one end, which is far away from the third driving roller, of the third belt, and one ends, which are close to the shell, of the third driving roller and the third driven roller are fixedly connected with the first driving roller.

Through the technical scheme, the fourth motor can drive the third driving roller and the third driven roller to rotate, so that the third driving roller and the third driven roller simultaneously drive the first driving roller to rotate, and the first mesh belt synchronously rotates in the same direction.

Further, the one end internal rotation that the feed inlet was kept away from to the shell is connected with the second drive roll, second drive roll external fixation cover is equipped with the second guipure, the one end internal fixation cover that the second drive roll was kept away from to the second guipure is equipped with the second driven voller, the one end rotation that is close to the second drive roll in the shell is connected with the third drive roll, third drive roll external fixation cover is equipped with the third guipure, the one end internal fixation cover that the third drive roll was kept away from to the third guipure is equipped with the third driven voller, the both sides of third driven voller all rotate and are connected with the backup pad, backup pad and shell fixed connection, third guipure runs through sliding connection discharge gate, the one end lower surface fixedly connected with supporting legs that the shell was kept away from to the backup pad.

Through the technical scheme, the second driving roller can drive the second mesh belt to rotate, materials falling from the upper layer are reversely moved and transferred to the lower layer through the second mesh belt, and the third driving roller drives the third mesh belt to rotate, so that the materials falling from the upper layer are discharged through the discharge hole.

The beneficial effects of the invention are as follows: (1) According to the invention, the telescopic transmission net belt is arranged in the shell, the third driving roller is driven by the fourth motor in the second driving mechanism, and the third driven roller is driven by the third driving roller through the third belt, so that the third driving roller and the third driven roller simultaneously drive the first driving roller to rotate, the upper and lower first net belts in the shell synchronously move, when the drying time needs to be shortened, the shortening hydraulic rod is started, the connecting rod moves along the slide rail, the third bulge is driven to move along the slide way, the third bulge drives the fixing plate to move, the distance between the first movable roller and the second movable roller is shortened, the length of the surface of the first net belt is shortened, the drying time can be adjusted under the condition that the rotation speed of the net belt is not changed, and the material dropping caused by the too high rotation speed of the net belt is avoided; (2) According to the invention, a material is firstly laid flatly and uniformly by arranging the material homogenizing lifting mechanism beside the shell, then enters the drying mechanism through the feeding port, the material homogenizing roller is driven to rotate by the first motor, the material homogenizing plate is driven to rotate by the material homogenizing roller, the material homogenizing plate is driven to rotate by the second motor, the material is separated and lifted by the material homogenizing plate through mutual matching of the lifting belt and the material homogenizing plate, the first driving roller is driven by the driving shaft to drive the first driven roller through the first belt, the material homogenizing shaft is driven by the first driven roller to rotate by the driven shaft, the strip-shaped protrusions are arranged on the material homogenizing shaft, the lifting belt can be jacked up, and the positions of the strip-shaped protrusions jacking the belt gradually move to two sides along with the rotation of the material homogenizing shaft, so that the material is driven to move and disperse to two sides, the material is well laid uniformly, the material is not required to be uniform through extrusion, and the material is effectively prevented from being extruded and damaged; (3) According to the invention, the telescopic transmission net belt and the transfer net belt mechanism are arranged in the shell, and the telescopic transmission net belt and the transfer net belt move oppositely, so that materials can fall layer by layer, and hot air in the heat circulation mechanism blows upwards from the lower part of the shell, so that the materials can be sufficiently dried.

Drawings

FIG. 1 is an overall construction diagram of a mesh belt type food drying device of the present invention;

FIG. 2 is a diagram showing the construction of a driving mechanism of a mesh belt type food drying device according to the present invention;

FIG. 3 is a view showing the construction of the inside of a thermal cycle box of the mesh-belt type food drying device of the present invention;

fig. 4 is an enlarged view at a in fig. 1;

FIG. 5 is a block diagram of an adjusting mechanism of a mesh-belt type food drying device according to the present invention;

FIG. 6 is a view showing the construction of the inside of a thermal cycle box of the mesh-belt type food drying apparatus of the present invention;

fig. 7 is an enlarged view at B in fig. 6;

fig. 8 is an internal construction view of a mesh belt type food drying apparatus according to the present invention;

fig. 9 is an internal cross-sectional view of a mesh-belt type food drying apparatus of the present invention;

fig. 10 is an enlarged view at C in fig. 9;

fig. 11 is an enlarged view at D in fig. 9;

FIG. 12 is a diagram showing a structure of a homogenizing shaft of a mesh belt type food drying apparatus of the present invention;

fig. 13 is a perspective view of a homogenizing shaft of a mesh belt type food drying apparatus of the present invention.

Reference numerals: 1. a housing; 2. a feed inlet; 3. a thermal cycling mechanism; 31. an air inlet pipe; 32. a thermal circulation tank; 33. an air outlet pipe; 34. an electric heating plate; 35. a fixing frame; 36. a fan; 4. a material homogenizing and lifting mechanism; 41. a support frame; 42. a side plate; 43. a baffle; 44. a first motor; 45. a material homogenizing roller; 46. a material homogenizing plate; 47. a second motor; 48. a drive shaft; 49. a first active roller; 410. a first belt; 411. a driven shaft; 412. a first driven roller; 413. a guide rod; 414. a first driven roller; 415. a material homogenizing shaft; 416. strip-shaped bulges; 417. lifting the belt; 5. a first driving mechanism; 51. a first protective case; 52. a second driven roller; 53. a second belt; 54. a second active roller; 55. a third motor; 6. a second driving mechanism; 61. a second protective case; 62. a third driven roller; 63. a third active roller; 64. a third belt; 65. a fourth motor; 7. an adjusting mechanism; 71. a fixed block; 72. a hydraulic rod; 73. a connecting rod; 74. a slide rail; 8. a telescopic transmission net belt; 81. a first drive roll; 82. a first guide roller; 83. a second guide roller; 84. a first moving roller; 85. a second moving roller; 86. a fixing plate; 87. a first protrusion; 88. a second protrusion; 89. a third protrusion; 810. a first mesh belt; 811. a first bearing; 812. a second bearing; 9. a transport web mechanism; 91. a second drive roll; 92. a second mesh belt; 93. a second driven roller; 94. a third drive roll; 95. a third mesh belt; 96. a third driven roller; 10. foot pads; 11. a discharge port; 12. an air inlet hole; 13. a slideway; 14. a first chute; 15. a second chute; 16. a support plate; 17. and supporting the feet.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

As shown in fig. 1, a mesh belt type food drying device of this embodiment includes a housing 1, a feed inlet 2 is provided on one end upper surface of the housing 1, a plurality of foot pads 10 are fixedly connected to the lower surface of the housing 1, one side of the housing 1 is fixedly connected with a thermal cycle mechanism 3, one side of the housing 1 close to the feed inlet 2 is fixedly connected with a uniform material lifting mechanism 4, one end side of the housing 1 far away from the feed inlet 2 is fixedly connected with a first driving mechanism 5, one end side of the housing 1 close to the uniform material lifting mechanism 4 is fixedly connected with a second driving mechanism 6, two sides of the housing 1 are fixedly connected with an adjusting mechanism 7, a telescopic transmission mesh belt 8 is fixedly connected in the housing 1, a transfer mesh belt mechanism 9 is fixedly connected in the housing 1, materials are lifted through the uniform material lifting mechanism 4 and enter the housing 1 through the feed inlet 2, the second driving mechanism 6 drives the telescopic transmission mesh belt 8 to operate, the first driving mechanism 5 drives the transfer mesh belt mechanism 9 to operate, the materials fall down in a staggered motion in the housing, and the hot air is dried under the condition provided by the thermal cycle mechanism 3, the length of the telescopic transmission mesh belt 8 can be adjusted through the adjusting mechanism 7, and thus the drying time of the housing 1 can be adjusted.

As shown in fig. 2, the first driving mechanism 5 includes a first protective shell 51, a first protective shell 51 is fixedly connected to one side of the housing 1, a third motor 55 is fixedly connected to one side of the first protective shell 51 away from the housing 1, an output end of the third motor 55 is fixedly connected to a second driving roller 54, a second belt 53 is sleeved on an outer fixing sleeve of the second driving roller 54, a second driven roller 52 is rotatably connected to one end of the first protective shell 51 away from the second driving roller 54, a second belt 53 is sleeved on an outer fixing sleeve of the second driven roller 52, one end of the second driving roller 54 close to the housing 1 is fixedly connected with a second driving roller 91, one end of the second driven roller 52 close to the housing 1 is fixedly connected with a third driving roller 94, the third motor 55 drives the second driving roller 54 to rotate, the second driving roller 54 drives the second driving roller 91 to rotate, meanwhile, the second driving roller 54 drives the second driven roller 52 to rotate through the second belt 53, and the second driven roller 52 drives the third driving roller 94 to rotate.

The second driving mechanism 6 comprises a second protective shell 61, one side of the outer shell 1 is fixedly connected with the second protective shell 61, one side of the second protective shell 61 away from the outer shell 1 is fixedly connected with a fourth motor 65, the output end of the fourth motor 65 is fixedly connected with a third driving roller 63, a third belt 64 is fixedly sleeved outside the third driving roller 63, a third driven roller 62 is fixedly sleeved in one end, far away from the third driving roller 63, of the third belt 64, one ends, close to the outer shell 1, of the third driving roller 63 and the third driven roller 62 are fixedly connected with the first driving roller 81, the fourth motor 65 drives the third driving roller 63 to rotate, the third driving roller 63 drives the third driven roller 62 to rotate through the third belt 64, and the third driving roller 63 and the second driven roller 62 respectively drive the first driving roller 81 to rotate.

As shown in fig. 2, 6 and 7, the thermal cycle mechanism 3 comprises an air inlet pipe 31, the upper surface of the housing 1 is fixedly connected with the air inlet pipe 31, one end of the air inlet pipe 31 far away from the housing 1 is fixedly connected with a thermal cycle box 32, one side of the thermal cycle box 32 close to the housing 1 is fixedly connected with a plurality of air outlet pipes 33, one side of the housing 1 close to the air outlet pipes 33 is provided with a plurality of air inlet holes 12, the air outlet pipes 33 are in one-to-one correspondence with the air inlet holes 12, a fixing frame 35 is fixedly connected with a fan 36 on the fixing frame 35, a pair of electric heating plates 34 are fixedly connected in the thermal cycle box 32, the electric heating plates 34 heat air, the fan 36 blows the hot air into the bottom of the housing 1 through the air outlet pipes 33, so that the hot air flows from bottom to top, fully contacts with materials in the housing 1, dries the materials, and then returns into the thermal cycle box 32 through the air inlet pipe 31, and heat waste is avoided.

As shown in fig. 1, fig. 3, fig. 5, fig. 12 and fig. 13, the average lifting mechanism 4 includes the curb plate 42, one side fixedly connected with curb plate 42 of shell 1, one side internal rotation that curb plate 42 is close to shell 1 is connected with drive shaft 48, one side fixedly connected with second motor 47 of curb plate 42, the output and the drive shaft 48 fixed connection of second motor 47, the one end fixedly connected with first initiative gyro wheel 49 of drive shaft 48 keep away from second motor 47, first initiative gyro wheel 49 external fixation cover is equipped with first belt 410, the one end internal fixation cover that first belt 410 kept away from first initiative gyro wheel 49 is equipped with first driven gyro wheel 412, one side fixedly connected with driven shaft 411 of first driven gyro wheel 412, one end fixedly connected with equal material axle 415 of driven shaft 411, equal material axle 415 external fixation is connected with strip protruding 416, the fixed cover is equipped with the elevating belt 417 outside the equal material axle 415 fixed cover, strip protruding 416 is the screw thread form, the second motor 47 drives drive shaft 48 and rotates, elevating belt is driven by the drive shaft 48, first initiative gyro wheel 49 drives first initiative gyro wheel 49, the first material is driven by the elevating belt to rotate, first initiative gyro wheel 412 is driven by first, the material is evenly distributed to the outside the elevating belt 415 through the first driven axle 412, and the outside the first driven axle 415 is driven by the equal material to evenly moves the strip-out material 415 through the first driven axle 416, and evenly moves the equal material to evenly moves the strip material to the strip-out axle 415 through the strip-out and evenly moves the strip-out axle 416.

The one end fixedly connected with baffle 43 that second motor 47 was kept away from to curb plate 42, the one end inboard that curb plate 42 is close to baffle 43 rotates and is connected with first driven voller 414, first driven voller 414 external fixation cover is equipped with lifting belt 417, the one end side fixedly connected with first motor 44 that curb plate 42 is close to baffle 43, the output fixedly connected with homogenizing roller 45 of first motor 44, homogenizing roller 45 external fixation has a plurality of homogenizing plates 46, the position rotation that is close to first driven gyro wheel 412 between curb plate 42 is connected with guide bar 413, guide bar 13 can provide the support for lifting belt 417 in corner, the lower surface fixedly connected with support frame 41 of curb plate 42, first motor 44 drives homogenizing roller 45 rotation, homogenizing roller 45 drives homogenizing plate 46 rotation, make homogenizing plate 46 and lifting belt 417 mutually support, separate the material and promote.

As shown in fig. 4 and 5, a hydraulic rod 72 is fixedly connected to one side of the connecting rod 73, sliding rails 74 are slidably connected to two ends of the connecting rod 73, the sliding rails 74 are fixedly connected with the housing 1, a fixed block 71 is fixedly connected to one end, away from the connecting rod 73, of the hydraulic rod 72, the fixed block 71 is fixedly connected with the housing 1, and the hydraulic rod 72 drives the connecting rod 73 to move along the sliding rails 74, so that a third protrusion 89 is driven to move along the sliding rail 13.

As shown in fig. 8, 9, 10 and 11, the telescopic transmission net belt 8 comprises a first driving roller 81, a first driving roller 81 is rotatably connected in the casing 1, one end, close to the first driving roller 81, of the casing 1 is rotatably connected with a first guide roller 82, one end, far away from the first driving roller 81, of the casing 1 is slidably connected with a pair of fixing plates 86, one end, close to the first driving roller 81, of the fixing plates 86 is fixedly connected with a second bearing 812, a second moving roller 85 is fixedly connected in the second bearing 812, one end, far away from the first driving roller 81, of the fixing plates 86 is fixedly connected with a first bearing 811, a first moving roller 84 is fixedly connected in the first bearing 811, a second guide roller 83 is rotatably connected in the position, close to the first moving roller 84, a first net belt 810 is fixedly sleeved outside the first driving roller 81, the second guide roller 83, the first moving roller 84 and the second moving roller 85, and when the fixing plates 86 move, the first moving roller 84 and the second moving roller 85 are fixedly connected with a first bearing 811, and the first net belt 810 is simultaneously rotated by the first moving roller 810, and the first net belt 810 is simultaneously, and the first net belt 810 is driven by the first moving synchronously, and the first net belt 810 is folded.

A pair of slide ways 13 have all been seted up to both sides in shell 1, a pair of first spout 14 has all been seted up to both sides in shell 1, a pair of second spout 15 has all been seted up to both sides in showing shell 1, fixed plate 86 is close to the first protruding 87 of all fixedly connected with in one end outside of first removal roller 84, fixed plate 86 is close to the first protruding 87 in one end outside all fixedly connected with third protruding 89, fixed plate 86 is close to the second removal 85 in one end outside all fixedly connected with second protruding 88, second protruding 88 and the mutual sliding fit of second spout 15, first protruding 87 and first spout 14 each other sliding fit, adjustment mechanism 7 includes connecting rod 73, third protruding 89 and connecting rod 73 fixed connection, third protruding 89 runs through sliding connection slide way 13, first protruding 87, second protruding 88 and third protruding 89 are in first spout 14 respectively, second spout 15 and slide way 13 sliding movement, can make fixed plate 86 follow rectilinear motion, improve the stability of first guipure 810 in the motion process.

As shown in fig. 9, the transferring mesh belt mechanism 9 comprises a second driving roller 91 and a third driving roller 94, the second driving roller 91 is rotationally connected to one end of the casing 1 far away from the feeding hole 2, a second mesh belt 92 is fixedly sleeved outside the second driving roller 91, a second driven roller 93 is fixedly sleeved inside one end of the second mesh belt 92 far away from the second driving roller 91, a third driving roller 94 is rotationally connected to one end of the casing 1 close to the second driving roller 91, a third driven roller 96 is fixedly sleeved outside the third driving roller 94, a third driven roller 96 is rotationally connected to two sides of the third driven roller 96, a supporting plate 16 is fixedly connected with the casing 1, the third mesh belt 95 penetrates through the sliding connection discharging hole 11, a supporting foot 17 is fixedly connected to the lower surface of one end of the supporting plate 16 far away from the casing 1, the second driving roller 91 drives the second mesh belt 92 to rotate, materials falling on an upper layer are transferred to a lower layer, the third mesh belt 95 is driven by the third roller 94 to rotate, and materials falling on the lower layer are discharged through the discharging hole 11.

The working principle of this embodiment is as follows, put the material into the space surrounded by baffle 43 and side plate 42, at this moment, the second motor 47 drives the driving shaft 48 to rotate, the driving shaft 48 drives the lifting belt 417 to rotate, meanwhile, the first motor 44 drives the homogenizing roller 45 to rotate, the homogenizing roller 45 drives the homogenizing plate 46 to rotate, the material is split and lifted by the lifting action of the lifting belt 417 and the separation action of the homogenizing plate 46, the driving shaft 48 drives the first driving roller 49 to rotate, the first driving roller 49 drives the first driven roller 412 to rotate by the first belt 410, the first driven roller 412 drives the homogenizing shaft 415 to rotate by the driven shaft 411, the strip-shaped protrusions 416 on the homogenizing shaft 415 push out the lifting belt to lift the protrusions, and along with the rotation of the homogenizing shaft 415, the protrusions pushed up by the strip-shaped protrusions 416 gradually move to two sides to disperse the material to two sides, so that the material is more uniform, then enters the shell 1 through the feed inlet 2 under the action of the lifting belt 417, at the moment, the third motor 55 drives the second driving roller 54 to rotate, the second driving roller 54 drives the second driven roller 52 to rotate through the second belt 53, the second driving roller 54 drives the second driving roller 91 to rotate, the second driven roller 52 drives the third driving roller 94 to rotate, the fourth motor 65 drives the third driving roller 63 to rotate, the third driving roller 63 drives the third driven roller 62 to rotate through the third belt 64, the third driving roller 63 and the third driven roller 62 both drive the first driving roller 81 to rotate, the first driving roller 81 drives the first net belt 810 to rotate, the second driving roller 91 and the third driving roller 94 drive the second net belt 92 and the third net belt 95 to rotate respectively, so that materials are transported by the first net belt 810 and fall onto the second net belt 92, then, the materials are transported and dropped onto the first mesh belt 810 at the lower side under the driving of the second mesh belt 92, finally, the materials are transported and dropped onto the third mesh belt 95, and transported and discharged through the third mesh belt 95, when the materials are in the shell 1, the electric heating plate 34 heats air, the fan 36 blows the hot air into the bottom of the shell 1, the hot air moves upwards from below, the materials are dried, the materials return to the thermal circulation box 32 through the air inlet pipe 31, if the drying time needs to be regulated, the connecting rod 73 is driven by the hydraulic rod 72 to move along the sliding rail 74, the connecting rod 73 drives the third protrusion 89 to move along the sliding rail 13, and the third protrusion 89 drives the fixed plate 86 to move, so that the first moving roller 84 and the second moving roller 85 on the fixed plate 86 are moved, the first mesh belt 810 is folded and shortened, and the time of the materials on the conveying belt is shortened.

The foregoing description is only of the preferred embodiments of the present invention, and is not intended to limit the scope of the present invention.

Claims (8)

1. The utility model provides a guipure formula food drying device, includes shell (1), its characterized in that: the automatic feeding device is characterized in that a feeding hole (2) is formed in the upper surface of one end of the shell (1), a plurality of foot pads (10) are fixedly connected to the lower surface of the shell (1), a thermal circulation mechanism (3) is fixedly connected to one side of the shell (1) close to the feeding hole (2), a material homogenizing lifting mechanism (4) is fixedly connected to one side surface of the shell (1) far away from the feeding hole (2), a first driving mechanism (5) is fixedly connected to one side surface of the shell (1) close to the feeding hole (2), a second driving mechanism (6) is fixedly connected to one side surface of the shell (1) close to the material homogenizing lifting mechanism (4), an adjusting mechanism (7) is fixedly connected to two sides of the shell (1), a telescopic transmission net belt (8) is fixedly connected to the inside of the shell (1), and a transferring net belt mechanism (9) is fixedly connected to the inside of the shell (1), and comprises a second driving roller (91) and a third driving roller (94);

the material homogenizing lifting mechanism (4) comprises a side plate (42), one side of the shell (1) is fixedly connected with the side plate (42), one side of the side plate (42) close to the shell (1) is rotationally connected with a driving shaft (48), one side of the side plate (42) is fixedly connected with a second motor (47), the output end of the second motor (47) is fixedly connected with the driving shaft (48), one end of the driving shaft (48) away from the second motor (47) is fixedly connected with a first driving roller (49), a first belt (410) is fixedly sleeved outside the first driving roller (49), one end of the first belt (410) away from the first driving roller (49) is fixedly sleeved with a first driven roller (412), one side of the first driven roller (412) is fixedly connected with a driven shaft (411), one end of the driven shaft (411) away from the first driven roller (412) is fixedly connected with a material homogenizing shaft (415), the material homogenizing shaft (415) is fixedly connected with a strip-shaped protrusion (416), the driving shaft (48) is fixedly sleeved outside the driving shaft (48), a lifting belt (416) is fixedly sleeved outside the driving shaft (48), one end of the driving shaft is fixedly provided with a lifting belt (417), and the strip-shaped protrusion (417) is fixedly sleeved outside the lifting belt (417).

The telescopic transmission net belt (8) comprises a first driving roller (81), the first driving roller (81) is rotationally connected to the inner side of a shell (1), one end, close to the first driving roller (81), of the shell (1) is rotationally connected with a first guide roller (82), one end, far away from the first driving roller (81), of the shell (1) is slidingly connected with a pair of fixing plates (86), one end, close to the first driving roller (81), of the fixing plates (86) is fixedly connected with a second bearing (812), a second moving roller (85) is fixedly connected to the inner side of the second bearing (812), one end, far away from the first driving roller (81), of the fixing plates (86) is fixedly connected with a first bearing (811), the inner side of the first bearing (811) is fixedly connected with a first moving roller (84), the inner side, close to the first moving roller (84), of the shell (1) is rotationally connected with a second guide roller (83), and the first driving roller (81), the second guide roller (82), the second guide roller (83) and the first moving roller (84) are fixedly connected with a first net belt (85).

2. The mesh belt type food drying device according to claim 1, wherein the thermal circulation mechanism (3) comprises an air inlet pipe (31), the upper surface of the shell (1) is fixedly connected with the air inlet pipe (31), one end of the air inlet pipe (31) away from the shell (1) is fixedly connected with a thermal circulation box (32), one side of the thermal circulation box (32) close to the shell (1) is fixedly connected with a plurality of air outlet pipes (33), one side of the shell (1) close to the air outlet pipes (33) is provided with a plurality of air inlet holes (12), the air outlet pipes (33) are in one-to-one correspondence with the air inlet holes (12), a fixing frame (35) is fixedly connected with a fan (36) in the fixing frame (35), and a pair of electric heating plates (34) are fixedly connected in the thermal circulation box (32).

3. The mesh belt type food drying device according to claim 1, wherein one end of the side plate (42) away from the second motor (47) is fixedly connected with a baffle plate (43), one end inner side of the side plate (42) close to the baffle plate (43) is rotationally connected with a first driven roller (414), a lifting belt (417) is fixedly sleeved outside the first driven roller (414), one end side of the side plate (42) close to the baffle plate (43) is fixedly connected with a first motor (44), an output end of the first motor (44) is fixedly connected with a material homogenizing roller (45), a plurality of material homogenizing plates (46) are fixedly connected outside the material homogenizing roller (45), a guide rod (413) is rotationally connected between the side plate (42) close to a position of the first driven roller (412), and a supporting frame (41) is fixedly connected to the lower surface of the side plate (42).

4. The mesh belt type food drying device according to claim 1, wherein a pair of sliding ways (13) are respectively arranged on two sides in the shell (1), a pair of first sliding grooves (14) are respectively arranged on two sides in the shell (1), a pair of second sliding grooves (15) are respectively arranged on two sides in the shell (1), a first protrusion (87) is respectively fixedly connected on one end outer side of a fixing plate (86) close to a first moving roller (84), a third protrusion (89) is respectively fixedly connected on one end outer side of the fixing plate (86) close to the first protrusion (87), a second protrusion (88) is respectively fixedly connected on one end outer side of the fixing plate (86) close to a second moving roller (85), the second protrusions (88) are mutually matched with the second sliding grooves (15), the first protrusions (87) are mutually matched with the first sliding grooves (14), the adjusting mechanism (7) comprises a connecting rod (73), the third protrusions (89) are fixedly connected with the connecting rod (73), and the third protrusions (89) are fixedly connected with the sliding ways (13).

5. The mesh belt type food drying device according to claim 4, wherein one side of the connecting rod (73) is fixedly connected with a hydraulic rod (72), two ends of the connecting rod (73) are slidably connected with sliding rails (74), the sliding rails (74) are fixedly connected with the shell (1), one end, far away from the connecting rod (73), of the hydraulic rod (72) is fixedly connected with a fixing block (71), and the fixing block (71) is fixedly connected with the shell (1).

6. The mesh belt type food drying device according to claim 1, wherein the first driving mechanism (5) comprises a first protective shell (51), one side of the shell (1) is fixedly connected with the first protective shell (51), one side of the first protective shell (51) away from the shell (1) is fixedly connected with a third motor (55), an output end of the third motor (55) is fixedly connected with a second driving roller (54), a second belt (53) is fixedly sleeved outside the second driving roller (54), one end of the first protective shell (51) away from the second driving roller (54) is rotatably connected with a second driven roller (52), one end of the second driving roller (54) close to the shell (1) is fixedly connected with a second driving roller (91), and one end of the second driving roller (52) close to the shell (1) is fixedly connected with a third roller (94).

7. The mesh belt type food drying device according to claim 1, wherein the second driving mechanism (6) comprises a second protective shell (61), one side of the outer shell (1) is fixedly connected with the second protective shell (61), one side of the second protective shell (61) away from the outer shell (1) is fixedly connected with a fourth motor (65), the output end of the fourth motor (65) is fixedly connected with a third driving roller (63), a third belt (64) is fixedly sleeved outside the third driving roller (63), a third driven roller (62) is fixedly sleeved in one end of the third belt (64) away from the third driving roller (63), and one ends of the third driving roller (63) and the third driven roller (62) close to the outer shell (1) are fixedly connected with the first driving roller (81).

8. The mesh belt type food drying device according to claim 1, wherein a second driving roller (91) is connected in an end inner rotation mode, far away from a feeding hole (2), of the outer shell (1), a second mesh belt (92) is arranged on an outer fixed sleeve of the second driving roller (91), a second driven roller (93) is arranged in an end inner fixed sleeve, far away from the second driving roller (91), of the second mesh belt (92), a third driving roller (94) is connected in an end, close to the second driving roller (91), of the outer shell (1), a third mesh belt (95) is arranged on an outer fixed sleeve of the third driving roller (94), a third driven roller (96) is arranged in an inner fixed sleeve, far away from an end, of the third driving roller (94), two sides of the third driven roller (96) are respectively connected with a supporting plate (16) in a rotating mode, the supporting plate (16) is fixedly connected with the outer shell (1), the third mesh belt (95) penetrates through a sliding connection discharging hole (11), and the supporting plate (16) is fixedly connected with a lower surface (17) of a foot of the outer shell (1).