CN112304057A

CN112304057A - Utilize drying device for bioengineering of air cycle principle

Info

Publication number: CN112304057A
Application number: CN202011159464.9A
Authority: CN
Inventors: 李鲜艳
Original assignee: Guangzhou Aibang Construction Technology Co ltd
Current assignee: Guangzhou Aibang Construction Technology Co ltd
Priority date: 2020-10-26
Filing date: 2020-10-26
Publication date: 2021-02-02

Abstract

The invention relates to a drying device, in particular to a drying device for bioengineering by utilizing an air circulation principle. The invention provides a drying device for bioengineering, which can stir granular materials and thoroughly dry the granular materials by utilizing the air circulation principle. A drying apparatus for bioengineering using air circulation principle, comprising: the base is provided with a drying mechanism; the base is provided with an air blowing mechanism. The granular materials are placed through the airing mechanism, and then are quickly dried through the cooperation of the air blowing mechanism; through being equipped with unloading mechanism, realize the transportation to the graininess thing after the drying, and then be convenient for people to the collection of the graininess thing after the drying.

Description

Utilize drying device for bioengineering of air cycle principle

Technical Field

The invention relates to a drying device, in particular to a drying device for bioengineering by utilizing an air circulation principle.

Background

Drying is a relatively common processing mode, and drying device often is applied to processes such as drying, baking because of its characteristics that handling capacity is big, it is convenient to use, is applied to research application fields such as biochemistry in a large number at present stage.

However, when the existing drying device is used for drying the granular materials, the granular materials are tightly arranged due to the pressure action when the existing drying device is used for drying the granular materials, so that the air circulation inside the drying device is not smooth, the air circulation inside the materials is influenced in the material drying process, and the drying efficiency and the drying effect are reduced. The product inside the material is not easy to dry, the drying speed is low, the product on the surface of the material is different from the drying speed of the product inside, the quality of the dried product is further influenced, and the bottommost granular drying is not thorough easily during drying.

Therefore, in view of the above disadvantages, there is a need to develop a drying apparatus for bioengineering using air circulation principle, which can stir the pellets and thoroughly dry the pellets.

Disclosure of Invention

In order to overcome the defects that the drying efficiency and the drying effect of the existing device are lower and the bottommost granular drying is not complete easily, the technical problem to be solved is as follows: provided is a drying device for bioengineering using the air circulation principle, which can stir granular materials and thoroughly dry the granular materials.

The technical scheme of the invention is as follows: a drying apparatus for bioengineering using air circulation principle, comprising: the base is provided with a drying mechanism; the base is provided with an air blowing mechanism.

Preferably, the airing mechanism includes: the base is provided with an installation plate; the tank body is arranged on the mounting plate; the cover is installed on the jar body.

Preferably, the air blowing mechanism includes: the base is provided with a first servo motor; the base is provided with a filtering bin; the air extraction box is arranged between the base and the filter bin; the first belt transmission component is connected between the output shaft of the first servo motor and the air extraction box, and a ventilation opening is formed in the tank body; and a second connecting pipe is connected between the tank cover and the air extraction tank.

Preferably, still include unloading mechanism, unloading mechanism includes: the base is provided with a second servo motor; a first straight gear is arranged on an output shaft of the second servo motor; the first sliding rails are symmetrically arranged between the mounting plate and the tank body; the first sliding block is arranged between the first sliding rails in a sliding manner, and round holes are formed in the lower part of the first sliding block and the base; the first sliding block is provided with a first rack; the second sliding block is arranged at the bottom of the first sliding block in a sliding manner; the first spring is connected between the second sliding block and the mounting plate; the bottom of the first sliding block is symmetrically provided with first connecting blocks; the first sliding rods are arranged on the first connecting blocks in a sliding mode and matched with the second sliding blocks; the second spring is connected between the first sliding rod and the first connecting block; the mounting plate is symmetrically provided with the line limiting blocks, and the line limiting blocks are matched with the first sliding rod.

Preferably, still include feed mechanism, feed mechanism includes: the base is provided with a first support column; the first support is provided with a first sliding rod in a sliding manner, and the first sliding rod is connected with the first rack; the base is symmetrically provided with second supporting columns; the discharge bin is arranged between the second supports and communicated with the tank body; the base is symmetrically provided with third supporting columns; a second stop block is arranged between the second stop blocks and the third support columns in a sliding manner, and the second stop blocks are matched with the discharging bin in a sliding manner; the first stop block is rotatably arranged on the second stop block and matched with the second slide bar; the second stop block is provided with a second spring which is connected with the second support on one side; the base is provided with a plurality of fourth struts; the fourth strut is rotatably provided with a blade which is positioned at the inner side of the lower part of the discharging bin; a second belt transmission component is rotatably arranged between the two fourth pillars at the edge position of the base and is connected with the blade; the other side of the second belt transmission component is provided with a gear lack; the base is provided with a second sliding rail; the second rack is arranged on the second sliding rail in a sliding mode and meshed with the gear lacking wheel; the second rack is provided with a ratchet in a sliding manner, and an elastic piece is arranged between the ratchet and the second rack; the base is provided with a fifth support; the ratchet wheel is rotatably arranged on the fifth support and meshed with the ratchet teeth, and the ratchet wheel is matched with the second sliding rod.

Preferably, still include the even mechanism of brush, brush even mechanism includes: the first rack is provided with a first rack; the bearing seat is arranged on the base; the bearing seat is provided with a second straight gear; the bearing seat is provided with a first rotating shaft; the first rotating shaft is provided with a first straight gear which is meshed with the first straight gear; the first rotating shaft is symmetrically provided with a first belt transmission component; the tank body is symmetrically and rotatably provided with a fourth straight gear which is connected with a third belt transmission component which is close to the tank body; the third sliding block is arranged on the tank body in a sliding manner; a fourth spring is symmetrically arranged between the third sliding block and the tank body; the bottom of the third sliding block is symmetrically provided with a fourth rack which is meshed with a fourth straight gear; a fifth straight gear is arranged on an output shaft of the first servo motor; the base is rotatably provided with a second rotating shaft; a sixth spur gear is arranged on the second rotating shaft and meshed with the fifth spur gear; the base is rotatably provided with a third rotating shaft; the bevel gear set is arranged between the lower part of the third rotating shaft and the second rotating shaft; the tank cover is rotatably provided with a fourth rotating shaft; the fourth sliding block is arranged on the fourth rotating shaft in a sliding mode and connected with the third sliding block; the bottom of the fourth sliding block is provided with a fifth rotating shaft; the lower part of the fifth rotating shaft is uniformly provided with a second connecting block; the third sliding rods are arranged on the second connecting blocks in a sliding manner; the lower part of the fifth rotating shaft is uniformly and rotatably provided with a fifth rack, the fifth rack is matched with the first sliding block, and the fifth rack is connected with a third adjacent sliding rod; and a fourth belt transmission component is arranged between the fourth rotating shaft and the third rotating shaft.

Preferably, the apparatus further comprises a heating mechanism, the heating mechanism comprising: the third connecting block is arranged in the tank body in a uniformly sliding manner; the turntable is arranged between the third connecting blocks and is connected with the fifth rotating shaft in a sliding manner; the bottom of the rotary table is uniformly provided with light bars; the fifth rotating shaft is uniformly provided with a fourth connecting block; the fifth sliding blocks are arranged on the fourth connecting blocks in a sliding mode and matched with the rotary table; and a fifth spring is connected between the fifth sliding block and the fourth connecting block.

Preferably, the observation mechanism further comprises: a third slide rail is arranged above the feed inlet of the tank body; the sixth sliding block is arranged on the third sliding rail in a sliding manner; the handle is arranged on the sixth sliding block.

The invention has the beneficial effects that: 1. the granular materials are placed through the airing mechanism, and then are quickly dried through the cooperation of the air blowing mechanism.

2. Through being equipped with unloading mechanism, realize the transportation to the graininess thing after the drying, and then be convenient for people to the collection of the graininess thing after the drying.

3. Through being equipped with feed mechanism, under the cooperation of unloading mechanism, realize the intermittent type unloading to the graininess thing, just so can control the graininess thing and carry out dry volume at every turn.

4. Through being equipped with the even mechanism of brush, under the cooperation of blower mechanism, realize the rotation to the even mechanism of brush, and then make the even mechanism of brush with the graininess stirring for the graininess is more even dry of being heated.

5. By providing the heating mechanism, the granular materials are dried more thoroughly.

6. Through being equipped with observation mechanism to people's better dry condition of observing the graininess thing.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

FIG. 2 is a schematic view of a first partial body structure according to the present invention.

FIG. 3 is a schematic view of a second partial body structure according to the present invention.

Fig. 4 is a perspective view of a third embodiment of the present invention.

Fig. 5 is a perspective view of a fourth embodiment of the present invention.

FIG. 6 is a schematic view of a fifth partial body structure according to the present invention.

FIG. 7 is a schematic view of a sixth partial body structure according to the present invention.

FIG. 8 is a schematic view of a seventh partial body structure according to the present invention.

Fig. 9 is a schematic structural view of a ninth partial body according to the present invention.

FIG. 10 is a schematic view of a tenth partial body structure according to the present invention.

FIG. 11 is a schematic view of an eleventh partial body structure according to the present invention.

FIG. 12 is a schematic view of a twelfth partial body structure according to the present invention.

FIG. 13 is a schematic view of a thirteenth partial body according to the present invention.

FIG. 14 is a schematic view of a fourteenth partially separated body structure according to the present invention.

Fig. 15 is a schematic perspective view of a fifteenth embodiment of the present invention.

Fig. 16 is a schematic view of a sixteenth partial body structure according to the present invention.

Reference numerals: 1_ base, 2_ airing mechanism, 20_ mounting plate, 21_ can, 22_ can, 3_ blower mechanism, 30_ first servomotor, 31_ filter bin, 32_ suction box, 33_ first belt transmission component, 34_ ventilation opening, 35_ second connecting pipe, 4_ blanking mechanism, 40_ second servomotor, 41_ first straight gear, 42_ first rack, 43_ first slide rail, 44_ first slide block, 45_ second slide block, 46_ first spring, 47_ first connecting block, 48_ first slide bar, 49_ second spring, 410_ limit block, 5_ feeding mechanism, 50_ first support, 51_ second slide bar, 52_ second support, 53_ discharge bin, 54_ third support, 55_ first stop, 56_ second stop, 57_ third spring, 58_ fourth support, 59_ blade, 510_ second belt transmission component, 511_ second belt transmission component, 57_ third spring, 512_ second slide rail, 513_ second rack, 514_ ratchet, 515_ fifth support, 516_ ratchet, 6_ smoothing mechanism, 60_ third rack, 61_ bearing block, 62_ second spur gear, 63_ first rotating shaft, 64_ third spur gear, 65_ third belt drive assembly, 66_ fourth spur gear, 67_ third slider, 68_ fourth spring, 69_ fourth rack, 610_ fifth spur gear, 611_ second rotating shaft, 612_ sixth spur gear, 613_ third rotating shaft, 614_ bevel gear set, 615_ fourth rotating shaft, 616_ fourth slider, 617_ fifth rotating shaft, 618_ second connecting block, 619_ third sliding rod, 620_ fifth rack, 621_ fourth belt drive assembly, 7_ heating mechanism, 70_ third connecting block, 71_ rotary disk, 72_ light bar, 73_ fourth connecting block, 74_ fifth slider, 75_ fifth spring, 8_ observation mechanism, 80_ third slide rail, 81_ sixth slide block, 82_ handle.

Detailed Description

The invention is further described below with reference to the figures and examples.

Example 1

A drying device for bioengineering using air circulation principle is shown in figures 1-5 and comprises a base 1, an airing mechanism 2 and an air blowing mechanism 3, wherein the airing mechanism 2 is arranged on the base 1, and the air blowing mechanism 3 is arranged on the base 1.

When people need use this device, at first people will carry out the graininess thing of drying and place in airing mechanism 2, just can start blower mechanism 3 after that, and blower mechanism 3 operates and then dries mechanism 2 with the steam suction in to carry out the drying to the graininess thing in airing mechanism 2, treat that the drying is accomplished, people just can close blower mechanism 3, so just so can dry graininess thing fast, when people need not use this device, close blower mechanism 3 can.

Airing mechanism 2 is equipped with mounting panel 20 including mounting panel 20, jar body 21 and cover 22, and the right rear side in base 1 top is equipped with mounting panel 20, is equipped with jar body 21 on the mounting panel 20, installs cover 22 on jar body 21.

The blower mechanism 3 comprises a first servo motor 30, a filter bin 31, an air extraction box 32, a first belt transmission assembly 33, a vent 34 and a second connecting pipe 35, the right front side of the top of the base 1 is provided with the first servo motor 30, the right side of the top of the base 1 is provided with the filter bin 31, the air extraction box 32 is installed between the base 1 and the filter bin 31, the first belt transmission assembly 33 is connected between the output shaft of the first servo motor 30 and the air extraction box 32, the tank body 21 is provided with the vent 34, and the second connecting pipe 35 is connected between the tank cover 22 and the air extraction box 32.

Firstly, people pour the granular materials to be dried into the tank body 21 from the feeding hole, then the filtering bin 31 is connected with a hot air source, then people can block the feeding hole of the tank body 21, the first servo motor 30 is started, the output shaft of the first servo motor 30 drives the air extraction box 32 to operate through the first belt transmission component 33, the air extraction box 32 sucks the hot air into the tank body 21 through the filtering bin 31 by the second connecting pipe 35, so that the granular materials in the tank body 21 can be dried, wherein in the drying process, the hot air can be discharged from the ventilation opening 34, then people can close the first servo motor 30 after the drying is completed, and therefore the granular materials can be dried quickly.

Example 2

On the basis of embodiment 1, as shown in fig. 1 and fig. 5 to fig. 16, the blanking device further includes a blanking mechanism 4, the blanking mechanism 4 includes a second servo motor 40, a first straight gear 41, a first rack 42, a first slide rail 43, a first slide block 44, a second slide block 45, a first spring 46, a first connecting block 47, a first slide bar 48, a second spring 49 and a limiting block 410, the second servo motor 40 is disposed on the rear side of the top of the base 1, the first straight gear 41 is disposed on the output shaft of the second servo motor 40, the first slide rail 43 is symmetrically disposed between the mounting plate 20 and the tank body 21, the first slide block 44 is slidably disposed between the first slide rails 43, circular holes are formed on the lower portion of the first slide block 44 and the base 1, the first rack 42 is disposed on the left side of the first slide block 44, the second slide block 45 is slidably disposed on the bottom of the first slide block 44, the first spring 46 is connected between the second slide block 45 and the, first connecting blocks 47 are symmetrically arranged at the bottoms of the first sliding blocks 44, first sliding rods 48 are arranged on the first connecting blocks 47 in a sliding mode, the first sliding rods 48 are matched with the second sliding blocks 45, second springs 49 are connected between the first sliding rods 48 and the first connecting blocks 47, limiting blocks 410 are symmetrically arranged on the mounting plate 20, and the limiting blocks 410 are matched with the first sliding rods 48.

When the first sliding block 44 is located at the inner side of the tank body 21 in an initial state, then after people put particulate matters into the tank body 21, the particulate matters fall onto the first sliding block 44, then after drying is completed, people can start the second servo motor 40, an output shaft of the second servo motor 40 drives the first rack 42 and the first sliding block 44 to move leftwards through the first straight gear 41, the first sliding block 44 drives the particulate matters and all parts thereon to move leftwards, so that the first sliding rod 48 drives the second sliding block 45 to move leftwards, the first spring 46 is stretched, then when the first sliding rod 48 moves to be in contact with the limiting block 410, the first sliding rod 48 is extruded to be separated from the second sliding block 45, at the moment, the second spring 49 is compressed, the first spring 46 drives the second sliding block 45 to move rightwards to reset, so that the second sliding block 45 does not block the particulate matters in the first sliding block 44 any more, and the particulate matters slide down from the first sliding block 44, therefore, people can conveniently collect the granular materials, then when all the granular materials in the first sliding block 44 fall down, people can start the second servo motor 40 to reversely rotate, the second servo motor 40 reversely rotates to drive the first rack 42 and the first sliding block 44 to move rightwards through the first straight gear 41, the first sliding block 44 drives all the components on the first sliding block 44 to move rightwards, when the first sliding rod 48 is separated from the limiting block 410, the second spring 49 drives the first sliding rod 48 to reset, then when the first sliding rod 48 moves rightwards to be in contact with the second sliding block 45, the first sliding rod 48 moves outwards again, when the first sliding rod 48 crosses the second sliding block 45, the second spring 49 drives the first sliding rod 48 to reset, at the moment, the first sliding rod 48 is positioned on the right side of the second sliding block 45, the second sliding block 45 blocks the first sliding block 44 again, and when people do not need to use the device, the second servo motor 40 is closed.

The automatic feeding device further comprises a feeding mechanism 5, the feeding mechanism 5 comprises a first support 50, a second slide rod 51, a second support 52, a discharging bin 53, a third support 54, a first stop 55, a second stop 56, a third spring 57, a fourth support 58, a blade 59, a second belt transmission component 510, a missing gear 511, a second slide rail 512, a second rack 513, a ratchet 514, a fifth support 515 and a ratchet 516, the left rear side of the top of the base 1 is provided with the first support 50, the first support 50 is provided with the second slide rod 51 in a sliding manner, the second slide rod 51 is connected with the first rack 42, the front and rear sides of the top of the base 1 are symmetrically provided with the second supports 52, the discharging bin 53 is arranged between the second supports 52, the discharging bin 53 is communicated with the tank 21, the right rear side of the top of the base 1 is symmetrically provided with the third support 54, the second stop 56 is arranged between the third supports 54 in a sliding manner, the second stop 56 is in sliding engagement with the discharging bin 53, a first stop block 55 is rotatably arranged on the left side of a second stop block 56, the first stop block 55 is matched with a second sliding rod 51, a third spring 57 is arranged on the second stop block 56, the third spring 57 is connected with a left third support column 54, a plurality of fourth support columns 58 are arranged on the base 1, a blade 59 is rotatably arranged between two right fourth support columns 58, the blade 59 is positioned on the lower inner side of the discharging bin 53, a second belt transmission component 510 is rotatably arranged between the two fourth support columns 58 at the edge position of the base 1, the second belt transmission component 510 is connected with the blade 59, a gear lacking 511 is arranged on the left side of the second belt transmission component 510, a second sliding rail 512 is arranged on the rear side of the top of the base 1, a second rack 513 is slidably arranged on the second sliding rail 512, the second rack 513 is meshed with the gear lacking 511, a ratchet 514 is slidably arranged on the second rack 513, an elastic element is arranged between the ratchet 514 and the second rack 513, a fifth support column 515 is arranged on, the fifth support 515 is rotatably provided with a ratchet 516, the ratchet 516 is engaged with the ratchet 514, and the ratchet 516 is matched with the second slide bar 51.

Firstly, people pour the granular objects into the discharging bin 53, at the same time, the granular objects are blocked by the second blocking block 56, when the first rack 42 moves rightwards, the first rack 42 drives the second slide bar 51 to move rightwards, then when the second slide bar 51 contacts with the first blocking block 55, the second slide bar 51 pushes the first blocking block 55 rightwards, the first blocking block 55 drives the second blocking block 56 to move rightwards, the third spring 57 is stretched, so that the second blocking block 56 does not block the granular objects in the discharging bin 53, the granular objects fall onto the first sliding block 44 from the discharging bin 53, meanwhile, the second slide bar 51 blocks the ratchet 516, when the granular objects contact with the blade 59, the blade 59 rotates, and the granular objects can be dispersed more, the blade 59 drives the gear wheel 511 to rotate through the second belt transmission component 510, when the gear wheel 511 is meshed with the second rack 513, the second rack 513 moves upwards, when the gear 511 rotates continuously, the second rack 513 can move upwards continuously, the second rack 513 drives the ratchet 514 to move upwards continuously, when the ratchet 514 contacts with the ratchet 516, the ratchet 514 is extruded, the elastic element is compressed, then when the second rack 513 contacts with the first stop block 55, the second rack 513 drives the first stop block 55 to rotate upwards continuously, then when the first stop block 55 is separated from the second slide bar 51, the third spring 57 drives the second stop block 56 to reset, and further blocks the granular materials in the discharging bin 53 again, so that the intermittent discharging of the granular materials can be realized, meanwhile, the blade 59 stops rotating, and further the second rack 513 stops moving upwards, then when the first slide block 44 moves leftwards, the first slide block 44 drives the second slide bar 51 to move leftwards, and when the second slide bar 51 is separated from the ratchet 516 and the first stop block 55, the first stop block 55 and the second rack 513 move downwards to reset, the elastic member drives the ratchet 514 to reset.

The uniform brushing mechanism 6 further comprises a uniform brushing mechanism 6, the uniform brushing mechanism 6 comprises a third rack 60, a bearing seat 61, a second straight gear 62, a first rotating shaft 63, a third straight gear 64, a third belt transmission component 65, a fourth straight gear 66, a third slide block 67, a fourth spring 68, a fourth rack 69, a fifth straight gear 610, a second rotating shaft 611, a sixth straight gear 612, a third rotating shaft 613, a bevel gear set 614, a fourth rotating shaft 615, a fourth slide block 616, a fifth rotating shaft 617, a second connecting block 618, a third slide bar 619, a fifth rack 620 and a fourth belt transmission component 621, the third rack 60 is arranged on the left front side of the first rack 42, the bearing seat 61 is arranged on the left side of the top of the base 1, the second straight gear 62 is arranged on the right side of the bearing seat 61, the first rotating shaft 63 is provided with the third straight gear 64, the third straight gear 64 is meshed with the second straight gear 62, the third belt transmission component 65 is symmetrically arranged on the first rotating shaft 63, a fourth straight gear 66 is symmetrically and rotatably arranged on the tank body 21, the fourth straight gear 66 is connected with a third belt transmission assembly 65 which is close to the fourth straight gear 66, a third slide block 67 is slidably arranged on the tank body 21, a fourth spring 68 is symmetrically arranged between the third slide block 67 and the tank body 21, a fourth rack 69 is symmetrically arranged at the bottom of the third slide block 67, the fourth rack 69 is meshed with the fourth straight gear 66, a fifth straight gear 610 is arranged on an output shaft of the first servo motor 30, a second rotating shaft 611 is rotatably arranged at the right side of the base 1, a sixth straight gear 612 is arranged on the second rotating shaft 611, the sixth straight gear 612 is meshed with the fifth straight gear 610, a third rotating shaft 613 is rotatably arranged at the right side of the top of the base 1, a bevel gear set 614 is arranged between the lower part of the third rotating shaft 613 and the rear part of the second rotating shaft 611, a fourth rotating shaft 615 is rotatably arranged on the tank cover 22, a fourth rotating shaft 615 is slidably, the bottom of the fourth slider 616 is provided with a fifth rotating shaft 617, the lower portion of the fifth rotating shaft 617 is uniformly provided with a second connecting block 618, the second connecting block 618 is provided with a third sliding rod 619 in a sliding manner, the lower portion of the fifth rotating shaft 617 is uniformly and rotatably provided with a fifth rack 620, the fifth rack 620 is matched with the first slider 44, the fifth rack 620 is connected with the adjacent third sliding rod 619, and a fourth belt transmission component 621 is arranged between the fourth rotating shaft 615 and the third rotating shaft 613.

When the first rack 42 moves rightwards, the first rack 42 drives the third rack 60 to move rightwards, when the third rack 60 moves to be meshed with the second spur gear 62, the second spur gear 62 drives the first rotating shaft 63 to rotate through the third spur gear 64, the first rotating shaft 63 drives the fourth spur gear 66 to rotate through the third belt transmission assembly 65, the fourth spur gear 66 drives the third slider 67 to move downwards through the fourth rack 69, the fourth spring 68 is stretched, the third slider 67 drives the fifth rotating shaft 617 to move downwards through the fourth slider 616, the fifth rotating shaft 617 drives all the components on the fifth rotating shaft to move downwards, meanwhile, the first servo motor 30 drives the second rotating shaft 611 to rotate through the fifth spur gear 610 and the sixth spur gear 612, the second rotating shaft 611 drives the third rotating shaft 613 to rotate through the bevel gear set 614, the third rotating shaft 613 drives the fourth rotating shaft 615 to rotate through the fourth belt transmission assembly 621, the fourth rotating shaft 615 drives all the components thereon to rotate, when the fifth rack 620 contacts with the particulate matter, the fifth rack 620 stirs the particulate matter, so that the particulate matter is dried more thoroughly, meanwhile, the fifth rack 620 is extruded to move upwards, when the third rack 60 moves leftwards to be separated from the second straight gear 62, the first rotating shaft 63 stops rotating, so that the third sliding block 67 stops moving downwards, at the moment, the fourth spring 68 drives the third sliding block 67 to move upwards to reset, meanwhile, people close the first servo motor 30, so that the fifth rotating shaft 617 and the fifth rack 620 stop rotating, the third sliding block 67 drives the fifth rotating shaft 617 through the fourth sliding block 616 to move upwards to reset, and the fifth rotating shaft 617 drives the fifth rack 620 to move upwards to reset.

Still include heating mechanism 7, heating mechanism 7 is including third connecting block 70, carousel 71, lamp strip 72, fourth connecting block 73, fifth slider 74 and fifth spring 75, jar body 21 is interior evenly to be slided type and is equipped with third connecting block 70, be equipped with carousel 71 between the third connecting block 70, carousel 71 and fifth pivot 617 sliding type connection, carousel 71 bottom evenly is equipped with lamp strip 72, evenly be equipped with fourth connecting block 73 on the fifth pivot 617, evenly be slided type on the fourth connecting block 73 and be equipped with fifth slider 74, fifth slider 74 and carousel 71 cooperation, all be connected with fifth spring 75 between fifth slider 74 and the fourth connecting block 73.

Firstly, people open the light bar 72 to heat and dry the granular objects by the light bar 72, then when the fifth rotating shaft 617 moves downwards, the fifth rotating shaft 617 drives all the components on the fifth rotating shaft 617 to move downwards, when the fifth sliding block 74 moves to be clamped with the rotating disc 71, the fifth rotating shaft 617 drives the rotating disc 71, the light bar 72 and the third connecting block 70 to rotate through the fifth sliding block 74, then the fifth rotating shaft 617 drives the fourth connecting block 73 to continue to move downwards, the fifth spring 75 is compressed, so that the granular objects can be dried more uniformly, when the fifth rotating shaft 617 drives the fifth sliding block 74 to move upwards to be separated from the rotating disc 71, the rotating disc 71 stops rotating, the fifth spring 75 resets, and when people do not need to use the device, the light bar 72 is closed.

Still include observation mechanism 8, observation mechanism 8 is equipped with third slide rail 80 including third slide rail 80, sixth slider 81 and handle 82 above the feed inlet of jar body 21, and third slide rail 80 is gone up the gliding style and is equipped with sixth slider 81, is equipped with handle 82 on the sixth slider 81.

When people need to observe the drying condition of the granular materials, people can pull the handle 82 to drive the sixth sliding block 81 to move leftwards, and people can reset the sixth sliding block 81 and the handle 82 after observation.

The embodiments described above are provided to enable persons skilled in the art to make or use the invention and that modifications or variations can be made to the embodiments described above by persons skilled in the art without departing from the inventive concept of the present invention, so that the scope of protection of the present invention is not limited by the embodiments described above but should be accorded the widest scope consistent with the innovative features set forth in the claims.

Claims

1. A drying device for bioengineering using air circulation principle, comprising:

the drying machine comprises a base (1), wherein a drying mechanism (2) is arranged on the base (1);

the air blowing mechanism (3) is arranged on the base (1).

2. The drying apparatus for bioengineering using air circulation principle according to claim 1, wherein the airing means (2) comprises:

the mounting plate (20) is arranged on the base (1);

the tank body (21) is arranged on the mounting plate (20);

the tank cover (22) is arranged on the tank body (21).

3. The drying apparatus for bioengineering using air circulation principle according to claim 1, wherein the blowing means (3) comprises:

the base (1) is provided with a first servo motor (30);

a filter bin (31), wherein the base (1) is provided with the filter bin (31);

the air extraction box (32) is arranged between the base (1) and the filter bin (31);

a first belt transmission component (33) is connected between an output shaft of the first servo motor (30) and the air extraction box (32), and a ventilation opening (34) is formed in the tank body (21);

and a second connecting pipe (35) is connected between the tank cover (22) and the air extraction tank (32).

4. The drying apparatus for bioengineering using air circulation principle according to claim 3, further comprising a feeding mechanism (4), wherein the feeding mechanism (4) comprises:

the base (1) is provided with a second servo motor (40);

a first straight gear (41) is arranged on an output shaft of the second servo motor (40);

the first sliding rails (43) are symmetrically arranged between the mounting plate (20) and the tank body (21);

the first sliding block (44) is arranged between the first sliding rails (43) in a sliding manner, and round holes are formed in the lower part of the first sliding block (44) and the base (1);

the first sliding block (44) is provided with a first rack (42);

the second sliding block (45) is arranged at the bottom of the first sliding block (44) in a sliding manner;

the first spring (46) is connected between the second sliding block (45) and the mounting plate (20);

the bottom of the first sliding block (44) is symmetrically provided with first connecting blocks (47);

the first sliding rods (48) are arranged on the first connecting blocks (47) in a sliding mode, and the first sliding rods (48) are matched with the second sliding blocks (45);

the second spring (49) is connected between the first sliding rod (48) and the first connecting block (47);

the limiting block (410) is symmetrically arranged on the mounting plate (20), and the limiting block (410) is matched with the first sliding rod (48).

5. The drying apparatus for bioengineering according to the air circulation principle of claim 4, further comprising a feeding mechanism (5), wherein the feeding mechanism (5) comprises:

the base (1) is provided with a first support column (50);

the second sliding rod (51) is arranged on the first support (50) in a sliding mode, and the second sliding rod (51) is connected with the first rack (42);

the second support column (52), the second support column (52) is symmetrically arranged on the base (1);

the discharge bin (53) is arranged between the second supports (52), and the discharge bin (53) is communicated with the tank body (21);

the third support column (54), the third support column (54) is symmetrically arranged on the base (1);

a second stop block (56) is arranged between the second stop blocks (56) and the third support columns (54) in a sliding manner, and the second stop blocks (56) are matched with the discharging bin (53) in a sliding manner;

the first stop block (55) is rotationally arranged on the second stop block (56), and the first stop block (55) is matched with the second sliding rod (51);

the third spring (57) is arranged on the second stop block (56), and the third spring (57) is connected with the third support (54) on one side;

a plurality of fourth support columns (58) are arranged on the base (1);

the blade (59) is rotatably arranged on the fourth support column (58), and the blade (59) is positioned on the inner side of the lower part of the discharging bin (53);

a second belt transmission component (510) is rotatably arranged between the two fourth supporting columns (58) at the edge position of the base (1), and the second belt transmission component (510) is connected with the blades (59);

the other side of the second belt transmission component (510) is provided with a gear lack (511);

the base (1) is provided with a second sliding rail (512);

the second rack (513) is arranged on the second sliding rail (512) in a sliding mode, and the second rack (513) is meshed with the gear lacking wheel (511);

the ratchet (514) is arranged on the second rack (513) in a sliding mode, and an elastic piece is arranged between the ratchet (514) and the second rack (513);

a fifth support column (515), wherein the base (1) is provided with the fifth support column (515);

the ratchet (516) is rotationally arranged on the fifth support column (515), the ratchet (516) is meshed with the ratchet (514), and the ratchet (516) is matched with the second sliding rod (51).

6. The drying apparatus for bioengineering using air circulation principle according to claim 5, further comprising a brush-leveling mechanism (6), wherein the brush-leveling mechanism (6) comprises:

the first rack (42) is provided with a third rack (60);

the bearing seat (61) is arranged on the base (1);

the bearing seat (61) is provided with a second straight gear (62);

the bearing seat (61) is provided with a first rotating shaft (63);

a third spur gear (64) is arranged on the first rotating shaft (63), and the third spur gear (64) is meshed with the second spur gear (62);

the third belt transmission component (65) is symmetrically arranged on the first rotating shaft (63);

the tank body (21) is symmetrically and rotatably provided with a fourth straight gear (66), and the fourth straight gear (66) is connected with a third belt transmission component (65) which is close to the fourth straight gear (66);

the third sliding block (67) is arranged on the tank body (21) in a sliding manner;

a fourth spring (68), wherein the fourth spring (68) is symmetrically arranged between the third slide block (67) and the tank body (21);

a fourth rack (69), wherein the bottom of the third sliding block (67) is symmetrically provided with the fourth rack (69), and the fourth rack (69) is meshed with the fourth straight gear (66);

a fifth spur gear (610), wherein a fifth spur gear (610) is arranged on an output shaft of the first servo motor (30);

a second rotating shaft (611), wherein the base (1) is rotatably provided with the second rotating shaft (611);

a sixth spur gear (612) is arranged on the second rotating shaft (611), and the sixth spur gear (612) is meshed with the fifth spur gear (610);

a third rotating shaft (613), the base (1) is rotatably provided with the third rotating shaft (613);

a bevel gear set (614) between the lower part of the third rotating shaft (613) and the second rotating shaft (611);

a fourth rotating shaft (615), wherein the tank cover (22) is rotatably provided with the fourth rotating shaft (615);

the fourth sliding block (616) is arranged on the fourth rotating shaft (615) in a sliding mode, and the fourth sliding block (616) is connected with the third sliding block (67);

a fifth rotating shaft (617), and the bottom of the fourth sliding block (616) is provided with the fifth rotating shaft (617);

the lower parts of the second connecting blocks (618) and the fifth rotating shafts (617) are uniformly provided with the second connecting blocks (618);

the third sliding rod (619) is arranged on the second connecting block (618) in a sliding manner;

the lower part of the fifth rotating shaft (617) is uniformly and rotatably provided with a fifth rack (620), the fifth rack (620) is matched with the first sliding block (44), and the fifth rack (620) is connected with a third adjacent sliding rod (619);

a fourth belt transmission component (621), a fourth belt transmission component (621) is arranged between the fourth rotating shaft (615) and the third rotating shaft (613).

7. The drying apparatus for bioengineering using air circulation principle according to claim 6, further comprising a heating mechanism (7), wherein the heating mechanism (7) comprises:

the third connecting block (70) is arranged in the tank body (21) in a uniformly sliding manner;

the turntable (71) is arranged between the third connecting blocks (70), and the turntable (71) is connected with the fifth rotating shaft (617) in a sliding manner;

the lamp strips (72) are uniformly arranged at the bottom of the rotary disc (71);

the fourth connecting block (73) is uniformly arranged on the fifth rotating shaft (617);

the fifth sliding blocks (74) are arranged on the fourth connecting blocks (73) in a sliding mode, and the fifth sliding blocks (74) are matched with the rotating disc (71);

and a fifth spring (75) is connected between the fifth sliding block (74) and the fourth connecting block (73).

8. The drying apparatus for bioengineering using air circulation principle according to claim 7, further comprising a viewing mechanism (8), wherein the viewing mechanism (8) comprises:

a third slide rail (80), wherein the third slide rail (80) is arranged above the feed inlet of the tank body (21);

the sixth sliding block (81), the third sliding rail (80) is provided with the sixth sliding block (81) in a sliding way;

the handle (82) is arranged on the handle (82) and the sixth sliding block (81).