CN112357564A

CN112357564A - Transfer device suitable for flour

Info

Publication number: CN112357564A
Application number: CN202011293419.2A
Authority: CN
Inventors: 边宏达
Original assignee: Anhui Hongwei Milling Co ltd
Current assignee: Anhui Hongwei Milling Co ltd
Priority date: 2020-11-18
Filing date: 2020-11-18
Publication date: 2021-02-12

Abstract

The invention discloses a transfer device suitable for flour, and relates to the technical field of flour transfer devices. The automatic sampling device comprises a conveyor belt, wherein one side of the conveyor belt is fixedly connected with an extension loading plate through a screw, one end of the top end of the extension loading plate is fixedly connected with a transmission feeding and dust removing structure, the other side of the top end of the extension loading plate is fixedly connected with a shaking and collecting box, and one side of the top end of the conveyor belt is fixedly connected with an automatic plugging and sampling structure. According to the invention, through the design of the transmission feeding and dust removing structure, the device is convenient for clamping and feeding the bagged flour to remove the attached flour by shaking the bagged flour through automatic angle adjustment and lifting adjustment, so that the automation in the flour transmission process is greatly improved, the dust flying in the transmission process is avoided, and through the design of the automatic inserting and sampling structure, the device is convenient for rapidly and conveniently sampling the guided flour bag, so that the detection convenience in the transfer process is greatly improved.

Description

Transfer device suitable for flour

Technical Field

The invention relates to the technical field of flour conveying devices, in particular to a transfer device suitable for flour.

Background

The wheat flour is divided into special flour (such as bread flour, dumpling flour, biscuit flour and the like), general flour (such as standard flour, strong flour), nutrition-enriched flour and the like according to performance and application, a corresponding transfer device is needed for facilitating the conduction of the processed flour, however, the existing device lacks a structure which is convenient for automatically adjusting the rotation angle, the lifting height and shaking for removing dust in the conduction process, and lacks an automatic convenient transmission sampling structure.

SUMMARY OF THE PATENT FOR INVENTION

The invention aims to provide a transfer device suitable for flour, which solves the existing problems: the existing device lacks a structure which is convenient for automatically adjusting the rotating angle, the lifting height and shaking for removing dust in the conduction process.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a transfer device suitable for flour, includes the conveyer belt, one side of conveyer belt is through screw fixedly connected with extension carrying plate, the one end fixedly connected with transmission material loading dust removal structure on extension carrying plate's top, the opposite side fixedly connected with shake-off centralized box on extension carrying plate top, the automatic grafting sampling structure of one side fixedly connected with on conveyer belt top, transmission material loading dust removal structure includes power carrying shell, first motor, first eccentric disc, lift stroke frame, supplementary direction slide rail, second motor, first power screw rod, linkage adjusting block and rocks and press from both sides tight feeding structure, the inboard of power carrying shell is through screw fixedly connected with first motor, the first eccentric disc of output fixedly connected with of first motor, the top welding of first eccentric disc has lift stroke frame, the top of lift stroke frame is through screw fixedly connected with second motor, the output end fixedly connected with first power screw rod of second motor, the bottom of first power screw rod is rotated with the inboard of lift stroke frame and is connected, supplementary direction slide rail has all been welded to the inside both sides of lift stroke frame, the inboard and the linkage adjusting block sliding connection of supplementary direction slide rail, the inside and the first power screw rod of linkage adjusting block pass through threaded connection, the one end fixedly connected with of linkage adjusting block rocks and presss from both sides tight feeding structure.

Preferably, the shaking, clamping and feeding structure comprises a limiting and carrying frame, an internal shaking and developing frame, an internal stable spring column, a two-way motor carrying block, a third motor, a second eccentric disc, a lateral supporting and limiting structure, a power carrying box, a fourth motor, a driving bevel gear, a driven bevel gear, a power extension arm, a second power screw, a matched guide polish rod and a linkage clamping jaw, wherein the bottom end inside the limiting and carrying frame is slidably connected with the internal shaking and developing frame, both sides of the internal shaking and developing frame are welded with the lateral supporting and limiting structure, the internal shaking and developing frame is fixedly connected with the two-way motor carrying block through the internal stable spring column, both ends inside the two-way motor carrying block are fixedly connected with the third motor through screws, the output end of the third motor is fixedly connected with the second eccentric disc, and the bottom end of the internal shaking and developing frame is fixedly connected with the power carrying box, one side of power carrying box is through screw fixedly connected with fourth motor, the output fixedly connected with drive bevel gear of fourth motor, the both sides of drive bevel gear one end all mesh and are connected with driven bevel gear, the both sides and the power extension arm welded connection of power carrying box, driven bevel gear's inside fixedly connected with second power screw rod, the other end and the power extension arm of second power screw rod rotate to be connected, the inboard of power extension arm and the one end of power carrying box still with join in marriage light guide rod fixed connection, the outside of second power screw rod and the equal sliding connection in the outside of joining in marriage the light guide rod have the linkage jack catch.

Preferably, the side direction supports limit structure and includes that atress push rod, assembly support frame, side direction push away the baffle, unload power connecting rod, component catch bar, built-in carrying shell and first spring, one side and the spacing carrying frame of assembly support frame pass through screw fixed connection, the inboard one end of assembly support frame with unload power connecting rod and rotate and be connected, the other end and the side direction of unloading the power connecting rod push away the baffle and rotate and be connected, the one end and the atress push rod welded connection of side direction push away the baffle, atress push rod and assembly support frame sliding connection, the top and the bottom of unloading the power connecting rod all with component catch bar sliding connection, the one end of component catch bar with and first spring are located the inboard of built-in carrying shell.

Preferably, the bottom end of the first spring is welded to the bottom end of the interior of the built-in carrying shell, the top end of the first spring is attached to the bottom end of the component force pushing rod, and the component force pushing rod is connected with the built-in carrying shell in a sliding mode.

Preferably, the inside at linkage jack catch top is seted up power connect the through-hole and is led spacing through-hole, lead spacing through-hole and join in marriage and lead the polished rod for clearance fit, power connect the through-hole and pass through threaded connection with the second power screw rod.

Preferably, joint sliding chutes have all been seted up to the both sides of linkage adjusting block, joint sliding chutes and supplementary direction slide rail are clearance fit.

Preferably, the automatic splicing sampling structure comprises a guide assembling box, a fifth motor, a torque output rod, a toggle gear, a linkage rack column, an internally-installed reset stroke pipe, a stressed piston block, a second spring and a material-taking sampling pipe, wherein one side of the guide assembling box is fixedly connected with the fifth motor through a screw, the output end of the fifth motor is fixedly connected with the torque output rod, the toggle gear is clamped and connected to the outer side of the torque output rod, the bottom end of the toggle gear is meshed and connected with the linkage rack column, the outer side of the linkage rack column is slidably connected with the guide assembling box, one end of the linkage rack column is welded and connected with the internally-installed reset stroke pipe, the inside of the internally-installed reset stroke pipe is slidably connected with the stressed piston block, the second spring is fixed to one end of the inner side of the stressed piston block, and the other end of the second spring is fixedly connected with the inner side of the internally-installed reset stroke pipe, one end of the stressed piston block is connected with the material taking sample detecting pipe in a welding mode.

Preferably, square sliding blocks are welded at the top end and the bottom end of the stressed piston block, square guide grooves are formed in the top end and the bottom end of the inner side of the built-in reset stroke pipe, and the square guide grooves are in clearance fit with the square sliding blocks.

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

1. according to the invention, through the design of the transmission feeding and dust removing structure, the device is convenient for clamping and feeding the bagged flour to remove the attached flour by shaking the bagged flour through automatic angle adjustment and lifting adjustment, so that the automation in the flour transmission process is greatly improved, and the dust flying in the transmission process is avoided;

2. according to the automatic inserting and sampling device, due to the design of the automatic inserting and sampling structure, the device can conveniently and quickly sample the flour bag conveyed out, and the detection convenience in the transferring process is greatly improved.

Drawings

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

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

FIG. 2 is a side view of the present invention in its entirety;

FIG. 3 is a schematic view of a partial structure of a transmission feeding dust removing structure according to the present invention;

FIG. 4 is a schematic view of a partial structure of the shaking clamping feeding structure according to the present invention;

FIG. 5 is a partial schematic structural view of the lateral supporting and limiting structure of the present invention;

FIG. 6 is a partial schematic diagram of an automated plugging sampling structure according to the present invention.

In the figure: 1. a conveyor belt; 2. extending the carrying plate; 3. shaking off the concentration box; 4. a transmission feeding dust removing structure; 5. an automatic plugging sampling structure; 6. a power carrying case; 7. a first motor; 8. a first eccentric disc; 9. a lifting stroke frame; 10. an auxiliary guide slide rail; 11. a second motor; 12. a first power screw; 13. a linkage adjusting slide block; 14. shaking the clamping feeding structure; 15. a limiting and carrying frame; 16. an internal shaking development frame; 17. an internal stability spring post; 18. a bidirectional motor carrying block; 19. a third motor; 20. a second eccentric disc; 21. a lateral support limit structure; 22. a power carrying case; 23. a fourth motor; 24. a drive bevel gear; 25. a driven bevel gear; 26. a powered extension arm; 27. a second power screw; 28. a guide polish rod is matched; 29. a linkage claw; 30. a stressed push rod; 31. assembling a support frame; 32. laterally pushing the guide plate; 33. a force-releasing connecting rod; 34. a component force pushing rod; 35. a carrying shell is arranged in the shell; 36. a first spring; 37. guiding to match the box; 38. a fifth motor; 39. a torque output rod; 40. shifting a gear; 41. a linkage rack post; 42. a reset stroke pipe is arranged in the shell; 43. a stressed piston block; 44. a second spring; 45. taking a material and detecting a sample pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-6, a transfer device for flour comprises a conveyor belt 1, one side of the conveyor belt 1 is fixedly connected with an extension carrying plate 2 through screws, one end of the top end of the extension carrying plate 2 is fixedly connected with a transmission feeding and dust removing structure 4, the other side of the top end of the extension carrying plate 2 is fixedly connected with a shake-off concentration box 3, and one side of the top end of the conveyor belt 1 is fixedly connected with an automatic plugging and sampling structure 5;

the transmission feeding and dust removing structure 4 comprises a power carrying shell 6, a first motor 7, a first eccentric disc 8, a lifting stroke frame 9, an auxiliary guide slide rail 10, a second motor 11, a first power screw rod 12, a linkage adjusting slide block 13 and a shaking and clamping feeding structure 14, wherein the inner side of the power carrying shell 6 is fixedly connected with the first motor 7 through screws, the output end of the first motor 7 is fixedly connected with the first eccentric disc 8, the top end of the first eccentric disc 8 is welded with the lifting stroke frame 9, the top end of the lifting stroke frame 9 is fixedly connected with the second motor 11 through screws, the output end of the second motor 11 is fixedly connected with the first power screw rod 12, the bottom end of the first power screw rod 12 is rotatably connected with the inner side of the lifting stroke frame 9, the two sides inside the lifting stroke frame 9 are both welded with the auxiliary guide slide rails 10, and the inner side of the auxiliary guide slide rail 10 is slidably connected with the linkage adjusting slide block, the interior of the linkage adjusting slide block 13 is connected with the first power screw 12 through threads, and one end of the linkage adjusting slide block 13 is fixedly connected with a shaking clamping feeding structure 14;

through the eccentric circle design of the first eccentric disc 8, under the drive of the torque of the output end of the first motor 7, the angular rotation direction of the shaking clamping feeding structure 14 is driven to be completed by utilizing the eccentric rotation of the first eccentric disc 8, so that the flour bag is driven to adjust the feeding angle, clamping sliding grooves are formed in the two sides of the linkage adjusting slider 13 and are in clearance fit with the auxiliary guide sliding rails 10, and the torque of the second motor 11 transmitted by the first power screw 12 and received by the linkage adjusting slider 13 is limited to form derivation power through the guidance of sliding limitation, so that the lifting of the linkage adjusting slider 13 is derived and driven, and the feeding height of the shaking clamping feeding structure 14 is changed;

the shaking clamping feeding structure 14 comprises a limiting carrying frame 15, an internal shaking developing frame 16, an internal stabilizing spring column 17, a two-way motor carrying block 18, a third motor 19, a second eccentric disc 20, a lateral supporting limiting structure 21, a power carrying box 22, a fourth motor 23, a driving bevel gear 24, a driven bevel gear 25, a power extension arm 26, a second power screw 27, a light distribution and guide rod 28 and a linkage clamping jaw 29, wherein the internal shaking developing frame 16 is connected to the bottom end inside the limiting carrying frame 15 in a sliding manner, both sides of the internal shaking developing frame 16 are welded with the lateral supporting limiting structure 21, the internal shaking developing frame 16 is fixedly connected with the two-way motor carrying block 18 through the internal stabilizing spring column 17, both ends inside the two-way motor carrying block 18 are fixedly connected with the third motor 19 through screws, the output end of the third motor 19 is fixedly connected with the second eccentric disc 20, the bottom end of the internal shaking developing frame 16 is fixedly connected with the power carrying box 22, one side of the power carrying box 22 is fixedly connected with a fourth motor 23 through a screw, the output end of the fourth motor 23 is fixedly connected with a driving bevel gear 24, two sides of one end of the driving bevel gear 24 are respectively connected with a driven bevel gear 25 in a meshed manner, two sides of the power carrying box 22 are welded with a power extension arm 26, a second power screw 27 is fixedly connected inside the driven bevel gear 25, the other end of the second power screw 27 is rotatably connected with the power extension arm 26, the inner side of the power extension arm 26 and one end of the power carrying box 22 are also fixedly connected with a light distribution and guide rod 28, and the outer side of the second power screw 27 and the outer side of the light distribution and guide rod 28 are both connected with a linkage clamping jaw 29 in a;

the second eccentric disc 20 is driven to rotate by the output torque of the internal shaking development frame 16, due to the eccentric weight design of one end of the second eccentric disc 20, eccentric lateral derivation power is generated in the rotation process, the internal shaking development frame 16 is driven to complete the extension of shaking stress under the sliding guide of the limiting carrying frame 15, the limit of the lateral supporting limit structure 21 is utilized to avoid shaking overtravel, the shaking derivation is realized through the connection of the internal shaking development frame 16 and the power carrying box 22, the inside of the top end of the linkage clamping jaw 29 is provided with a power connecting through hole and a guiding limit through hole, the guiding limit through hole is in clearance fit with the light distribution guide rod 28, the power connecting through hole is in threaded connection with the second power screw 27, the torque is derived through the matching of the fourth motor 23 and the driving bevel gear 24, and the torque is rapidly derived through the meshing of the driven bevel gear 25 and the driving bevel gear 24, the second power screw 27 is driven to rotate, the torque led out by the second power screw 27 is limited to form synchronous derivation by matching with the connection of the light-distribution and guide rod 28 and the linkage jaw 29, so that the linkage jaw 29 is displaced inwards to complete automatic clamping of the flour bag, the flour bag is shaken by using shaking power at the transmission part, and accordingly flour attached to the outer surface is shaken down to the shaking and falling concentration box 3, and the cleanness and tidiness degree of secondary conduction is ensured;

the side supporting and limiting structure 21 comprises a stressed push rod 30, an assembling support frame 31, a side push-guide plate 32, a force-unloading connecting rod 33, a force-component push rod 34, an inner loading shell 35 and a first spring 36, wherein one side of the assembling support frame 31 is fixedly connected with the limiting loading frame 15 through a screw, one end of the inner side of the assembling support frame 31 is rotatably connected with the force-unloading connecting rod 33, the other end of the force-unloading connecting rod 33 is rotatably connected with the side push-guide plate 32, one end of the side push-guide plate 32 is welded with the stressed push rod 30, the stressed push rod 30 is slidably connected with the assembling support frame 31, the top end and the bottom end of the force-unloading connecting rod 33 are both slidably connected with the force-component push rod 34, one end of the force-component push rod 34 and the first spring 36 are positioned on the inner side of the inner loading shell 35, the bottom end of the first spring 36 is welded with the bottom end, the component force push rod 34 is connected with the built-in carrying shell 35 in a sliding mode, so that the stress limiting is convenient to complete;

the automatic splicing sampling structure 5 comprises a guide assembly box 37, a fifth motor 38, a torque output rod 39, a toggle gear 40, a linkage rack column 41, an internally-installed reset stroke pipe 42, a stressed piston block 43, a second spring 44 and a material-taking sample detection pipe 45, wherein one side of the guide assembly box 37 is fixedly connected with the fifth motor 38 through a screw, the output end of the fifth motor 38 is fixedly connected with the torque output rod 39, the toggle gear 40 is clamped on the outer side of the torque output rod 39, the bottom end of the toggle gear 40 is meshed and connected with the linkage rack column 41, the outer side of the linkage rack column 41 is slidably connected with the guide assembly box 37, one end of the linkage rack column 41 is welded and connected with the internally-installed reset stroke pipe 42, the inside of the internally-installed reset stroke pipe 42 is slidably connected with a stressed piston block 43, one end of the inner side of the stressed piston block 43 is fixedly provided with the second spring 44, the other end of the second spring 44 is fixedly connected with the inner side, one end of the stressed piston block 43 is welded with the material taking sample detecting pipe 45, square sliding blocks are welded at the top end and the bottom end of the stressed piston block 43, square guide grooves are formed in the top end and the bottom end of the inner side of the built-in reset stroke pipe 42, and the square guide grooves and the square sliding blocks are in clearance fit;

the torque of the fifth motor 38 is transmitted to the toggle gear 40 by the torque output rod 39 and the toggle gear 40 through the torque output of the fifth motor 38, thereby stirring the linkage rack post 41 to complete conduction, utilizing the limit guide of the guide assembling box 37 to the linkage rack post 41, so that the linkage rack column 41 finishes the displacement sliding derivation of the material taking and sample detecting pipe 45 under the guidance of the shifting gear 40 and the guidance of the guiding assembly box 37 to derive and insert the flour into the flour bag, at the moment, when the material taking and sample detecting pipe 45 passes through the flour bag, the sliding of the force-receiving piston block 43 into the interior of the return stroke tube 42 by resistance forces the second spring 44 to contract inwardly, after the torque is reversely transmitted by the fifth motor 38, the material taking and detecting tube 45 is driven to exit from the flour bag, and at the moment, the second spring 44 elastically resets to push out the material taking and detecting tube 45, so that enough flour can be taken out from the interior of the material taking and detecting tube 45 to be used as a sample for observation.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. A transfer device suitable for flour, includes conveyer belt (1), its characterized in that: the dust removing device is characterized in that one side of the conveying belt (1) is fixedly connected with an extending carrying plate (2) through a screw, one end of the top end of the extending carrying plate (2) is fixedly connected with a transmission feeding dust removing structure (4), the other side of the top end of the extending carrying plate (2) is fixedly connected with a shaking-off centralized box (3), one side of the top end of the conveying belt (1) is fixedly connected with an automatic splicing sampling structure (5), the transmission feeding dust removing structure (4) comprises a power carrying shell (6), a first motor (7), a first eccentric disc (8), a lifting stroke frame (9), an auxiliary guide sliding rail (10), a second motor (11), a first power screw rod (12), a linkage adjusting sliding block (13) and a shaking clamping feeding structure (14), the inner side of the power carrying shell (6) is fixedly connected with a first motor (7) through a screw, and the output end of the first motor (7) is fixedly connected with a first eccentric disc (8), the welding of the top of first eccentric disc (8) has lift stroke frame (9), screw fixedly connected with second motor (11) is passed through on the top of lift stroke frame (9), the first power screw rod (12) of output fixedly connected with of second motor (11), the bottom of first power screw rod (12) is rotated with the inboard of lift stroke frame (9) and is connected, supplementary direction slide rail (10) have all been welded to the both sides of lift stroke frame (9) inside, the inboard and linkage adjusting block (13) sliding connection of supplementary direction slide rail (10), the inside and the first power screw rod (12) of linkage adjusting block (13) pass through threaded connection, the one end fixedly connected with of linkage adjusting block (13) rocks and presss from both sides tight feeding structure (14).

2. A transfer device suitable for flour as claimed in claim 1 wherein: rock and press from both sides tight feeding structure (14) and include spacing carrier (15), interior rocking development frame (16), steady spring post (17), two-way motor carry on piece (18), third motor (19), second eccentric disc (20), side direction support limit structure (21), power carry on case (22), fourth motor (23), drive bevel gear (24), driven bevel gear (25), power extension arm (26), second power screw (27), join in marriage guide polish rod (28) and linkage jack catch (29), the inside bottom sliding connection of spacing carrier (15) has interior rocking development frame (16), the both sides of interior rocking development frame (16) all with side direction support limit structure (21) welded connection, the inside through steady spring post (17) and two-way motor carry on piece (18) fixed connection of interior rocking development frame (16), the inside both ends of two-way motor carry on piece (18) all through screw fixed connection third motor (19) The output end of the third motor (19) is fixedly connected with a second eccentric disc (20), the bottom end of the internal shaking development frame (16) is fixedly connected with a power carrying box (22), one side of the power carrying box (22) is fixedly connected with a fourth motor (23) through a screw, the output end of the fourth motor (23) is fixedly connected with a driving bevel gear (24), two sides of one end of the driving bevel gear (24) are respectively connected with a driven bevel gear (25) in a meshed manner, two sides of the power carrying box (22) are welded with a power extension arm (26), a second power screw (27) is fixedly connected inside the driven bevel gear (25), the other end of the second power screw (27) is rotatably connected with the power extension arm (26), the inner side of the power extension arm (26) and one end of the power carrying box (22) are also fixedly connected with a matched guide polish rod (28), the outer side of the second power screw rod (27) and the outer side of the light distribution and guide rod (28) are both connected with a linkage claw (29) in a sliding manner.

3. A transfer device suitable for flour as claimed in claim 2 wherein: the lateral supporting and limiting structure (21) comprises a stressed push rod (30), an assembling support frame (31), a lateral push guide plate (32), a force unloading connecting rod (33), a component force push rod (34), an inner mounting shell (35) and a first spring (36), one side of the assembly support frame (31) is fixedly connected with the limiting carrying frame (15) through a screw, one end of the inner side of the assembly support frame (31) is rotationally connected with a force unloading connecting rod (33), the other end of the force unloading connecting rod (33) is rotationally connected with the lateral pushing guide plate (32), one end of the lateral push guide plate (32) is welded and connected with the stressed push rod (30), the stressed push rod (30) is connected with the assembly support frame (31) in a sliding way, the top end and the bottom end of the force unloading connecting rod (33) are connected with the component force push rod (34) in a sliding way, one end of the component force pushing rod (34) and the first spring (36) are positioned on the inner side of the built-in carrying shell (35).

4. A transfer device suitable for flour as claimed in claim 3 wherein: the bottom end of the first spring (36) is connected with the bottom end inside the built-in carrying shell (35) in a welding mode, the top end of the first spring (36) is attached to the bottom end of the component force pushing rod (34), and the component force pushing rod (34) is connected with the built-in carrying shell (35) in a sliding mode.

5. A transfer device suitable for flour as claimed in claim 1 wherein: power connect the through hole and the spacing through-hole of direction have been seted up to the inside on linkage jack catch (29) top, the spacing through-hole of direction is clearance fit with joining in marriage light pole (28), power connect the through hole and pass through threaded connection with second power screw rod (27).

6. A transfer device suitable for flour as claimed in claim 1 wherein: the joint sliding grooves are formed in two sides of the linkage adjusting sliding block (13) and are in clearance fit with the auxiliary guide sliding rail (10).

7. A transfer device suitable for flour as claimed in claim 1 wherein: the automatic splicing sampling structure (5) comprises a guide assembling box (37), a fifth motor (38), a torque output rod (39), a toggle gear (40), a linkage rack column (41), an internally-installed reset stroke pipe (42), a stressed piston block (43), a second spring (44) and a material taking and sampling pipe (45), wherein one side of the guide assembling box (37) is fixedly connected with the fifth motor (38) through a screw, the output end of the fifth motor (38) is fixedly connected with the torque output rod (39), the outer side of the torque output rod (39) is clamped with the toggle gear (40), the bottom end of the toggle gear (40) is meshed with the linkage rack column (41), the outer side of the linkage rack column (41) is connected with the guide assembling box (37) in a sliding manner, one end of the linkage rack column (41) is connected with the internally-installed reset stroke pipe (42) in a welding manner, the inside and atress piston block (43) sliding connection of built-in stroke pipe that resets (42), the inboard one end of atress piston block (43) is fixed with second spring (44), the inboard fixed connection of the other end and built-in stroke pipe that resets (42) of second spring (44), the one end and the material of atress piston block (43) are visited appearance pipe (45) welded connection.

8. A transfer device suitable for flour according to claim 7, wherein: the top and the bottom of atress piston piece (43) all weld have square sliding block, square guide way has all been seted up to the inboard top and the bottom of built-in stroke pipe (42) that resets, square guide way and square sliding block are clearance fit.