CN112791654A

CN112791654A - High-efficient saturated face dry mixing device that gathers materials

Info

Publication number: CN112791654A
Application number: CN202110040736.1A
Authority: CN
Inventors: 徐志灵; 金晓煜; 贾燕丽; 楼志君
Original assignee: Zhejiang Lizhou Traffic Engineering Testing Co ltd
Current assignee: Zhejiang Lizhou Traffic Engineering Testing Co ltd
Priority date: 2021-01-13
Filing date: 2021-01-13
Publication date: 2021-05-14

Abstract

The invention discloses a high-efficiency aggregate saturated dough drying stirring device, which comprises a bottom plate, a plurality of supporting columns, a base, a stirring device, a material placing device, a heating assembly and a moving device, wherein the material placing device comprises a first rotating rod and a second rotating rod, a placing groove is formed in the upper surface of the base, a stirring barrel is arranged in the placing groove in a sliding manner, one end of the first rotating rod is hinged to one side of the inner wall of the placing groove, one end of the second rotating rod is hinged to the other side of the inner wall of the placing groove, a first T-shaped sliding groove and a second T-shaped sliding groove are formed in the lower surface of the stirring barrel, a first sliding rod fixed with one end of the rotating rod is arranged in the first T-shaped sliding groove in a sliding manner, a square through groove is formed in one side wall of the first T-shaped sliding groove, a square driving rod is arranged in the square, one end of the first spring is fixed with the triangular clamping block, so that the advantage of conveniently and completely taking out the stirred raw materials is achieved.

Description

High-efficient saturated face dry mixing device that gathers materials

Technical Field

The invention relates to the technical field of stirring equipment, in particular to a high-efficiency aggregate saturated surface drying stirring device.

Background

Aggregates are also known as aggregates. The aggregate is divided into coarse aggregate and fine aggregate. One of the main constituent materials of concrete. Mainly acts as a framework and reduces the volume change caused by the shrinkage and swelling of the gelled material during setting and hardening, and simultaneously acts as an inexpensive filler for the gelled material. The aggregate is divided into natural aggregate and artificial aggregate, wherein the natural aggregate is crushed stone, pebble, pumice, natural sand and the like; the latter is such as cinder, slag, ceramsite, expanded perlite and the like. The aggregate with the apparent density of particles less than 1700 kg/cubic meter is called lightweight aggregate and is used for manufacturing common concrete; particularly heavy aggregate, for the manufacture of heavy concrete, such as radiation-resistant concrete. The aggregates are classified into coarse aggregates and fine aggregates according to their particle size, and coarse aggregates such as crushed stones and pebbles are generally specified for those having a particle size of more than 4.75 mm, and fine aggregates such as natural sands are specified for those having a particle size of less than 4.75 mm.

At present, after the stirring is finished, the raw materials after the stirring are difficult to take out completely, and the raw materials are remained in the stirring cylinder and can cause influence on the subsequent stirring.

Disclosure of Invention

The invention aims to provide an efficient aggregate saturated dough drying stirring device which has the advantage of being convenient for completely taking out and stirring raw materials.

The technical purpose of the invention is realized by the following technical scheme:

a high-efficiency aggregate saturated noodle dry stirring device comprises a bottom plate, a plurality of supporting columns fixed on the bottom plate, a base arranged on the supporting columns in a sliding manner, and a stirring device arranged on the supporting columns, and is characterized by further comprising a material placing device arranged on the base, a heating component arranged on one side of a stirring cylinder, and a moving device arranged on the supporting columns and used for moving the base, wherein the material placing device comprises a first rotating rod and a second rotating rod, the upper surface of the base is provided with a placing groove, the stirring cylinder is arranged in the placing groove in a sliding manner, one end of the first rotating rod is hinged to one side of the inner wall of the placing groove, one end of the second rotating rod is hinged to the other side of the inner wall of the placing groove, a driving component for driving the first rotating rod and the second rotating rod to rotate is arranged in the placing groove, the lower surface of the stirring cylinder is provided with a first T-, the utility model discloses a material mixing device, including a T shape spout, square driving rod, spring I, the shrinkage pool, the one end of square driving rod, the shrinkage pool is provided with the spring-back subassembly, the one end of square driving rod is provided with and is used for driving square driving rod pivoted start-up subassembly, it is provided with square actuating lever to slide in the square groove, the inclined plane is seted up to square actuating lever one end, square actuating lever one side is provided with the resilience subassembly, the one end of square actuating lever is provided with and is used for driving square actuating lever pivoted start-up subassembly, it is provided with slide bar two to slide in the T shape spout two, the shrinkage pool has all been seted up at slide bar two ends, all be fixed with spring I in the shrinkage.

By adopting the technical scheme, the raw materials are poured into the mixing drum, the base and the mixing drum are driven to ascend through the moving device, then the raw materials in the mixing drum are stirred by the stirring device, after the stirring is finished, the heating component is started while stirring, the wall of the mixing drum is heated, the moisture on the surface of the aggregate is evaporated through heating, the driving component is started, the driving component drives the first rotating rod and the second rotating rod to rotate, the first rotating rod and the second rotating rod drive the mixing drum to move upwards, the first rotating rod drives the first sliding rod to slide along the first T-shaped sliding groove, the second rotating rod drives the second sliding rod to slide along the second T-shaped sliding groove, when the bottom end of the mixing drum moves to be level with the base, the first sliding rod moves to the square driving rod, one end of the first sliding rod, which drives the square driving rod, moves into the starting component, the pushing component is started, the triangular clamping block is, at the moment, the second sliding rod can move out of the second T-shaped sliding groove, the starting assembly is started, the starting assembly drives the square driving rod to rotate, the square driving rod drives the stirring cylinder to rotate until the stirring cylinder rotates for 90 degrees, the discharging assembly is started, the discharging assembly pushes materials in the stirring cylinder out, the starting assembly is started reversely after the materials are all pushed out of the stirring cylinder, the starting assembly drives the square driving rod to rotate reversely, the square driving rod drives the stirring cylinder to rotate back, the stirring cylinder rotates back to enable the triangular clamping block to move back into the concave hole, the triangular clamping block drives the first spring to compress to generate elastic force, when the second sliding rod moves into the second T-shaped sliding groove, the elastic force of the first spring drives the triangular clamping block to move out, the driving assembly is started reversely, the driving assembly drives the first rotating rod and the second rotating rod to rotate back, the first rotating rod and the second rotating rod drive the first sliding rod and the second sliding rod respectively, the square driving rod moves out of the square through groove under the action of the rebounding assembly, and the rotating rod I and the rotating rod II drive the stirring cylinder to move downwards.

Preferably, the driving assembly comprises a first motor, a first bevel gear, a second bevel gear and a third bevel gear, the first motor is fixed on the inner wall of the placing groove, an output shaft of the first motor is fixed with the first bevel gear, two sides of the first motor are respectively fixed with a first support plate and a second support plate, the first support plate is rotatably provided with a first threaded rod, the second support plate is rotatably provided with a second threaded rod, one end of the first threaded rod is fixed with the second bevel gear, one end of the second threaded rod is fixed with the third bevel gear, the first bevel gear is meshed with the second bevel gear, the first bevel gear is meshed with the third bevel gear, the side wall of the placing groove is provided with a limiting groove, the limiting groove is internally provided with a first pushing rod and a second pushing rod in a sliding manner, the first threaded rod and the second threaded rod are respectively in threaded fit with the first pushing rod and the second pushing rod, one ends of the first push rod and the second push rod are respectively arranged in the first sliding groove and the second sliding groove in a sliding mode.

By adopting the technical scheme, the first motor is started, the first bevel gear is driven to rotate by rotation of the output shaft of the first motor, the second bevel gear and the third bevel gear are driven to rotate by rotation of the first bevel gear, the first threaded rod drives the first push rod to move by rotation of the first bevel gear, the first push rod drives the first rotating rod to rotate by rotation of the third bevel gear, the second threaded rod drives the second push rod to move by rotation of the second bevel gear, the second push rod drives the second rotating rod to rotate by movement of the second push rod, the limit groove limits the moving direction of the first push rod and the second push rod, the first push rod and the second push rod can respectively slide in the first sliding groove and the second sliding groove while moving along the limit groove, and the effect of driving the first rotating rod and the second rotating rod to rotate is achieved.

Preferably, the starting assembly comprises a second motor and a connecting rod, a support is fixed on the base on one side of the placing groove, the second motor is fixed on the support, an output shaft of the second motor is fixed with the connecting rod, a square connecting hole is formed in one end, far away from the second motor, of the connecting rod, and the square connecting hole is matched with the square driving rod.

By adopting the technical scheme, when the square driving rod moves into the square connecting hole, the second motor is started, the output shaft of the second motor rotates to drive the connecting rod to rotate, the connecting rod rotates to drive the square driving rod to rotate, and the square driving rod rotates to drive the mixing drum to rotate, so that the effect of driving the mixing drum to rotate is achieved.

Preferably, the pushing assembly comprises a first air cylinder and a flat plate, a second groove is formed in the lower surface of the mixing drum, the first air cylinder is fixed in the second groove, a piston rod of the first air cylinder is fixed with the flat plate, and pushing blocks are symmetrically fixed on the flat plate.

By adopting the technical scheme, the first air cylinder is started, the piston rod of the first air cylinder extends out to drive the flat plate to move, the flat plate moves to drive the push block to move towards the triangular clamping block, and the push block drives the triangular clamping block to move towards the concave hole, so that the effect of driving the triangular clamping block to move into the concave hole is achieved.

Preferably, the rebound assembly comprises a rebound block and a second spring, the inner wall of the square through groove is provided with a rebound groove, the rebound block is arranged in the rebound groove in a sliding manner, the rebound block is fixed with the square driving rod, and two ends of the second spring are fixed with the rebound block and the side wall of the rebound groove respectively.

By adopting the technical scheme, the square driving rod moves to drive the rebound block to move in the rebound groove, the rebound block moves to drive the second spring to compress, the second spring compresses to generate elastic force, when the square driving rod is not under pressure, the elastic force of the second spring drives the rebound block to move back along the rebound groove, and the rebound block moves back to drive the square driving rod to move back, so that the effect of automatically moving back the square driving rod is achieved.

Preferably, the discharging assembly comprises a second cylinder and a material pushing plate, the second cylinder is fixed in the mixing drum, the material pushing plate is arranged in the mixing drum in a sliding mode, and a piston rod of the second cylinder is fixed with the material pushing plate.

By adopting the technical scheme, the second air cylinder is started, the piston rod of the second air cylinder extends out to drive the material pushing plate to move, and the material pushing plate drives the material to move out of the mixing drum, so that the effect of pushing the material out is achieved.

Preferably, the stirring device comprises a third motor, a fourth bevel gear and a fifth bevel gear, the third motor is fixed on the support, a shell is fixed on the support, an output shaft of the third motor penetrates through the side wall of the shell and is fixed with the fourth bevel gear, the lower wall of the shell penetrates through and rotates to be provided with a rotating column, the upper end of the rotating column is fixed with the fifth bevel gear, the fourth bevel gear is meshed with the fifth bevel gear, a fixed block is fixed on the inner wall of the shell, an inner toothed ring is fixed at the lower end of the fixed block, a driving rod penetrates through and rotates on the rotating column, a sixth gear meshed with the inner toothed ring is fixed at the upper end of the driving rod, and a stirring blade is fixed at one end, away from.

By adopting the technical scheme, the motor III is started, the output shaft of the motor III rotates to drive the bevel gear to rotate four times, the bevel gear rotates four times to drive the bevel gear to rotate five times, the bevel gear rotates five times to drive the rotating column to rotate, the driving rod moves along with the rotating column, the rotating column moves to drive the gear to rotate six times, the gear rotates six times to drive the driving rod to rotate, the driving rod rotates to drive the stirring blades to rotate, and the stirring blades stir the raw materials, so that the raw materials are stirred.

As preferred, the intensification subassembly is including setting up heating chamber and the fan on the base, bottom plate one side is provided with the heating cabinet, the fan is fixed in the one end of heating cabinet, the heating cabinet internal fixation has a plurality of heating wires, be connected with flexible air-supply line one and air-supply line two on the heating cabinet, the one end that the heating cabinet was kept away from to flexible air-supply line one communicates with each other with the heating chamber, the heating chamber is kept away from the one end of flexible air-supply line one and has been seted up the air outlet, the one end that the heating cabinet was kept away from to air-supply line two is fixed with the casing lower extreme.

Adopt above-mentioned technical scheme, a plurality of heating wires heat, start the fan, and the fan is bloied, and wind is when the heating wire, and the heating wire heats wind, and hot-blast process is flexible air-supply line one and is entered into the heating intracavity, and in hot-blast heat transfer to the churn, discharge from the air outlet at last, open the valve, hot-blast air through the air-supply line two to the inside of churn is bloied, carries out fast drying to the raw materials.

Preferably, the mobile device includes seventh gear and rack, the drive groove has been seted up to the pillar lateral wall, it is provided with the dwang to run through and rotate on the drive groove lateral wall, the one end of dwang is fixed with the handspike, dwang and seventh gear are fixed, the rack is fixed in on the base lateral wall, seventh and rack toothing of gear, be provided with the tightening bolt on the base.

By adopting the technical scheme, the hand lever is rotated, the hand lever drives the rotating rod to rotate, the rotating rod drives the gear seven to rotate, the gear seven rotates to drive the rack to move, the rack moves to drive the base to move, and when the base moves to a specified position, the tightening bolt is rotated to fix the position of the base.

Preferably, a PLC controller is fixed on the base, and a voice broadcasting machine is fixed on the side wall of the base.

Adopt above-mentioned technical scheme, the PLC controller has played control motor one, motor two, motor three, cylinder one, cylinder two and cylinder three's effect, simultaneously through PLC controller control double-shaft motor, micro water pump, heating water tank, the running state of voice broadcast machine and air heater, ensure double-shaft motor, micro water pump, heating water tank, voice broadcast machine and air heater are in suitable running state, after the moisture on the surface of gathering materials is accomplished by the evaporation, voice broadcast opportunity sends the prompt tone, thereby remind the staff to take out the collection materials in with the churn.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment;

FIG. 2 is a schematic diagram for showing the structure of the driving assembly;

FIG. 3 is a schematic structural view for showing a stirring device;

FIG. 4 is a schematic diagram for showing a mobile device;

FIG. 5 is a schematic position diagram for showing a first T-shaped chute and a first sliding rod;

FIG. 6 is a schematic diagram for showing the starting assembly;

FIG. 7 is a schematic view for showing the structure of the pushing assembly;

FIG. 8 is a schematic view for showing the structure of the discharging assembly;

FIG. 9 is a schematic view for showing the structure of the temperature raising assembly;

FIG. 10 is a schematic diagram showing the positions of the square through slot, the square driving rod, the rebound block, the second spring, the rebound slot and the inclined plane;

FIG. 11 is a schematic diagram for showing the positions of a T-shaped sliding chute II, a sliding rod II, a concave hole, a spring I and a triangular clamping block;

fig. 12 is a schematic view showing the positions of the base, the heating chamber, the first retractable air inlet pipe and the air outlet.

Reference numerals: 1. a base; 2. a stirring device; 3. a material placing device; 4. a first rotating rod; 5. a second rotating rod; 6. a placement groove; 7. a mixing drum; 8. a drive assembly; 9. a first T-shaped chute; 10. a T-shaped sliding chute II; 11. a first sliding rod; 12. a square through groove; 13. a square drive rod; 14. a rebound assembly; 15. starting the component; 16. a second sliding rod; 17. concave holes; 18. a first spring; 19. a triangular clamping block; 20. a pushing assembly; 21. a discharge assembly; 22. a first motor; 23. a first bevel gear; 24. a second bevel gear; 25. a third bevel gear; 26. a first support plate; 27. a support plate II; 28. a first threaded rod; 29. a second threaded rod; 30. a limiting groove; 31. a first push rod; 32. a second push rod; 33. a first sliding groove; 34. a second sliding groove; 35. a second motor; 36. a connecting rod; 37. a support; 38. a square connecting hole; 39. a first cylinder; 40. a flat plate; 41. a second groove; 42. a push block; 43. a rebound block; 44. a second spring; 45. a rebound groove; 46. a second air cylinder; 47. a material pushing plate; 48. a PLC controller; 49. a third motor; 50. a fourth bevel gear; 51. a fifth bevel gear; 52. a pillar; 55. a bevel; 59. a temperature raising component; 60. a heating cavity; 61. a fan; 62. a heating box; 63. an electric heating wire; 64. a first telescopic air inlet pipe; 65. a second air inlet pipe; 66. a voice announcement machine; 67. a housing; 68. rotating the column; 69. a fixed block; 70. an inner gear ring; 71. driving the rod; 72. a sixth gear; 73. stirring blades; 74. a base plate; 75. a mobile device; 76. a seventh gear; 77. a rack; 78. a drive slot; 79. rotating the rod; 80. a handle; 81. screwing down the bolt; 82. an air outlet; 83. and (4) a valve.

Detailed Description

The following description is only a preferred embodiment of the present invention, and the protection scope is not limited to the embodiment, and any technical solution that falls under the idea of the present invention should fall within the protection scope of the present invention. It should also be noted that modifications and embellishments within the scope of the invention may occur to those skilled in the art without departing from the principle of the invention.

Referring to fig. 1 to 12, a high-efficiency aggregate saturated noodle stirring device comprises a bottom plate 74, a plurality of supporting columns 52 fixed on the bottom plate 74, a base 1 slidably arranged on the supporting columns 52, a stirring device 2 arranged on the supporting columns 52, a material placing device 3 arranged on the base 1, a heating component 59 arranged on one side of a stirring cylinder 7, and a moving device 75 arranged on the supporting columns 52 and used for moving the base 1, wherein the material placing device 3 comprises a first rotating rod 4 and a second rotating rod 5, a placing groove 6 is formed in the upper surface of the base 1, the stirring cylinder 7 is slidably arranged in the placing groove 6, raw materials are poured into the stirring cylinder 7, the moving device 75 comprises a seventh gear 76 and a rack 77, a driving groove 78 is formed in the side wall of the supporting columns 52, a rotating rod 79 is arranged on the side wall of the driving groove 78 in a penetrating and rotating manner, a hand rod 80 is fixed at one end of the rotating rod 79, the, the seventh gear 76 is meshed with the rack 77, the hand lever 80 is rotated, the hand lever 80 drives the rotating lever 79 to rotate, the rotating lever 79 rotates to drive the seventh gear 76 to rotate, the seventh gear 76 rotates to drive the rack 77 to move, the rack 77 moves to drive the base 1 to move until the base 1 moves to a specified position, the tightening bolt 81 is arranged on the base 1, and the tightening bolt 81 is rotated to fix the position of the base 1.

As shown in fig. 3, the stirring device 2 includes a motor three 49, a bevel gear four 50 and a bevel gear five 51, the motor three 49 is fixed on a pillar 52, a housing 67 is fixed on the pillar 52, an output shaft of the motor three 49 penetrates through a side wall of the housing 67 and is fixed with the bevel gear four 50, the motor three 49 is started, the output shaft of the motor three 49 rotates to drive the bevel gear four 50 to rotate, a rotating column 68 is arranged through and rotates on a lower wall of the housing 67, an upper end of the rotating column 68 is fixed with the bevel gear five 51, the bevel gear four 50 is meshed with the bevel gear five 51, the bevel gear four 50 rotates to drive the bevel gear five 51 to rotate, the bevel gear five 51 rotates to drive the rotating column 68 to rotate, a fixed block 69 is fixed on an inner wall of the housing 67, an inner toothed ring 70 is fixed on a lower end of the fixed with an inner toothed ring 70, a driving rod 71 is arranged through and rotates on the rotating column 68, the driving rod 71 moves along with the rotating column 68, the rotating column 68 moves to drive the gear six 72 to rotate, the gear six 72 rotates to drive the driving rod 71 to rotate, the driving rod 71 rotates to drive the stirring blade 73 to rotate, the stirring blade 73 stirs the raw materials, after the stirring is finished, the screwing bolt 81 is unscrewed, the hand rod 80 is rotated reversely, the hand rod 80 drives the rotating rod 79 to rotate back, the rotating rod 79 drives the gear seven 76 to rotate back, the gear seven 76 drives the rack 77 to move back, the rack 77 drives the base 1 to move back, and the base 1 drives the stirring drum 7 to move back.

As shown in fig. 9, the warming assembly 59 includes a heating chamber 60 and a fan 61 disposed on the base 1, a heating box 62 is disposed on one side of the bottom plate 74, the fan 61 is fixed at one end of the heating box 62, a plurality of heating wires 63 are fixed in the heating box 62, a first retractable air inlet pipe 64 and a second retractable air inlet pipe 65 are connected to the heating box 62, one end of the first retractable air inlet pipe 64, which is away from the heating box 62, is communicated with the heating chamber 60, an air outlet 82 is disposed at one end of the heating chamber 60, which is away from the first retractable air inlet pipe 64, an end of the second retractable air inlet pipe 65, which is away from the heating box 62, is fixed at the lower end of the housing 67, a valve 83 is fixed on the second retractable air inlet pipe 65, when stirring, the plurality of heating wires 63 heat the fan 61, the fan 61 blows air, when the air passes through the heating wires 63, the heating wires, and finally, discharging from the air outlet 82, opening the valve 83, blowing hot air into the mixing drum 7 through the second air inlet pipe 65, and quickly drying the raw materials.

As shown in fig. 2, one end of a first rotating rod 4 is hinged to one side of the inner wall of a placing groove 6, one end of a second rotating rod 5 is hinged to the other side of the inner wall of the placing groove 6, a driving component 8 for driving the first rotating rod 4 and the second rotating rod 5 to rotate is arranged in the placing groove 6, the driving component 8 comprises a first motor 22, a first bevel gear 23, a second bevel gear 24 and a third bevel gear 25, the first motor 22 is fixed to the inner wall of the placing groove 6, a PLC 48 is pressed to start the first motor 22, an output shaft of the first motor 22 is fixed to the first bevel gear 23, an output shaft of the first motor 22 rotates to drive the first bevel gear 23 to rotate, two sides of the first motor 22 are respectively fixed with a first support plate 26 and a second support plate 27, a first threaded rod 28 is rotatably arranged on the first support plate 26, one end of the first threaded rod 28 is fixed to the second bevel gear, the second bevel gear 24 rotates to drive the first threaded rod 28 to rotate, the second support plate 27 is rotatably provided with a second threaded rod 29, one end of the second threaded rod 29 is fixed with the third bevel gear 25, the first bevel gear 23 is meshed with the third bevel gear 25, the third bevel gear 25 rotates to drive the second threaded rod 29 to rotate, the side wall of the placement groove 6 is provided with a limiting groove 30, a first push rod 31 and a second push rod 32 are arranged in the limiting groove 30 in a sliding manner, the first threaded rod 28 and the second threaded rod 29 are respectively in threaded fit with the first push rod 31 and the second push rod 32, the first rotating rod 4 and the second rotating rod 5 are respectively provided with a first sliding groove 33 and a second sliding groove 34, one ends of the first push rod 31 and the second push rod 32 are respectively arranged in the first sliding groove 33 and the second sliding groove 34 in a sliding manner, the first threaded rod 28 rotates to drive the first push rod 31 to move, the first push rod, the second push rod 32 moves to drive the second rotating rod 5 to rotate, the limiting groove 30 limits the moving directions of the first push rod 31 and the second push rod 32, and the first push rod 31 and the second push rod 32 can respectively slide in the first sliding groove 33 and the second sliding groove 34 while moving along the limiting groove 30.

As shown in fig. 2, 6 and 10, a first T-shaped chute 9 and a second T-shaped chute 10 are formed in the lower surface of the mixing drum 7, a first slide bar 11 fixed to one end of a first rotating bar 4 is slidably disposed in the first T-shaped chute 9, a second slide bar 16 is slidably disposed in the second T-shaped chute 10, concave holes 17 are formed in two ends of the second slide bar 16, a first spring 18 is fixed in each concave hole 17, a triangular clamping block 19 is slidably disposed in each concave hole 17, one end of the first spring 18 is fixed to the triangular clamping block 19, the first rotating bar 4 and the second rotating bar 5 drive the mixing drum 7 to move upwards, the first rotating bar 4 rotates to drive the first slide bar 11 to slide along the first T-shaped chute 9, the second rotating bar 5 rotates to drive the second slide bar 16 to slide along the second T-shaped chute 10, a square through groove 12 is formed in the side wall of the first T-shaped chute 9, a square driving rod 13 is slidably disposed in the square through, the slide bar I11 moves to the square driving rod 13, a starting assembly 15 for driving the square driving rod 13 to rotate is arranged at one end of the square driving rod 13, the starting assembly 15 comprises a motor II 35 and a connecting rod 36, a support 37 is fixed on the base 1 on one side of the placing groove 6, the motor II 35 is fixed on the support 37, an output shaft of the motor II 35 is fixed with the connecting rod 36, one end, away from the motor II 35, of the connecting rod 36 is provided with a square connecting hole 38, the square connecting hole 38 is matched with the square driving rod 13 until the square driving rod 13 moves into the square connecting hole 38, one side of the square driving rod 13 is provided with a rebound assembly 14, the rebound assembly 14 comprises a rebound block 43 and a spring II 44, the inner wall of the square through groove 12 is provided with a rebound groove 45, the rebound block 43 is slidably arranged in the rebound groove 45, the rebound block 43 is fixed with the square driving rod 13, the square driving rod 13 moves to drive the rebound block 43 to move in the rebound groove 45, the rebound block 43 moves to drive the second spring 44 to compress, and the second spring 44 compresses to generate elastic force.

As shown in fig. 2 to 8, at this time, the triangular clamping block 19 needs to be moved into the concave hole 17, the lower end of the mixing drum 7 is provided with a pushing assembly 20 for driving the triangular clamping block 19 to move into the concave hole 17, the pushing assembly 20 comprises a first air cylinder 39 and a flat plate 40, the lower surface of the mixing drum 7 is provided with a second groove 41, the first air cylinder 39 is fixed in the second groove 41, a piston rod of the first air cylinder 39 is fixed with the flat plate 40, push blocks 42 are symmetrically fixed on the flat plate 40, a PLC controller 48 is pressed to start the first air cylinder 39, the piston rod of the first air cylinder 39 extends out to drive the flat plate 40 to move, the flat plate 40 moves to drive the push block 42 to move towards the triangular clamping block 19, the push block 42 drives the triangular clamping block 19 to move towards the concave hole 17, when the triangular clamping block 19 is completely moved into the concave hole 17, the second sliding rod 16 can be moved out of the T-shaped, the connecting rod 36 rotates to drive the square driving rod 13 to rotate, the square driving rod 13 rotates to drive the stirring drum 7 to rotate until the stirring drum 7 rotates by 90 degrees, a discharging assembly 21 for pushing out finished materials is arranged in the stirring drum 7, the discharging assembly 21 comprises a second air cylinder 46 and a pushing plate 47, the second air cylinder 46 is fixed in the stirring drum 7, the pushing plate 47 is arranged in the stirring drum 7 in a sliding mode, a piston rod of the second air cylinder 46 is fixed with the pushing plate 47, a PLC 48 is pressed to start the second air cylinder 46, a piston rod of the second air cylinder 46 extends out to drive the pushing plate 47 to move, the pushing plate 47 drives the materials to move out of the stirring drum 7, after all the materials are pushed out from the stirring drum 7, the second motor 35 is started in a reverse mode, an output shaft of the second motor 35 rotates to drive the connecting rod 36 to rotate, the connecting rod 36 rotates to drive the square driving rod 13 to rotate, the square driving rod 13 rotates to drive, the triangular clamping block 19 drives the first spring 18 to compress, the first spring 18 compresses to generate elastic force, and when the second sliding rod 16 moves into the second T-shaped sliding groove 10, the elastic force of the first spring 18 drives the triangular clamping block 19 to move out.

As shown in fig. 2, the first motor 22 is started in a reverse direction, the output shaft of the first motor 22 rotates to drive the first bevel gear 23 to rotate back, the first bevel gear 23 rotates to drive the second bevel gear 24 and the third bevel gear 25 to rotate back, the second bevel gear 24 rotates to drive the first threaded rod 28 to rotate back, the first threaded rod 28 rotates to drive the first push rod 31 to move back, the first push rod 31 moves to drive the first rotary rod 4 to rotate back, the third bevel gear 25 rotates to drive the second threaded rod 29 to rotate back, the second threaded rod 29 rotates to drive the second push rod 32 to move back, the second push rod 32 moves to drive the second rotary rod 5 to rotate back, the first rotary rod 4 and the second rotary rod 5 drive the first rotary rod 4 and the second rotary rod 5 to rotate back, the first rotary rod 4 and the second rotary rod 5 drive the first slide rod 11 and the second slide rod 16 to move back respectively, after the first slide rod 11, the square drive rod 13 is not subjected to pressure any more, the resilient block 43 is driven by, the first rotating rod 4 and the second rotating rod 5 drive the stirring cylinder 7 to move back to the placing groove 6. Be fixed with pronunciation broadcast machine 66 on the lateral wall of base 1, after the moisture on the surface of gathering materials is accomplished by the evaporation, pronunciation broadcast machine 66 can send the prompt tone to remind the staff to take out the collection materials in the churn 7.

Claims

1. A high-efficiency aggregate saturated surface dry stirring device comprises a bottom plate (74), a plurality of pillars (52) fixed on the bottom plate (74), a base (1) arranged on the pillars (52) in a sliding manner, and a stirring device (2) arranged on the pillars (52), and is characterized by further comprising a material placing device (3) arranged on the base (1), a heating assembly (59) arranged on one side of a stirring cylinder (7), and a moving device (75) arranged on the pillars (52) and used for moving the base (1), wherein the material placing device (3) comprises a first rotating rod (4) and a second rotating rod (5), a placing groove (6) is formed in the upper surface of the base (1), the stirring cylinder (7) is arranged in the placing groove (6) in a sliding manner, one end of the first rotating rod (4) is hinged on one side of the inner wall of the placing groove (6), one end of the second rotating rod (5) is hinged on the other side of the inner wall of the, a driving assembly (8) for driving the first rotating rod (4) and the second rotating rod (5) to rotate is arranged in the placing groove (6), a T-shaped sliding groove I (9) and a T-shaped sliding groove II (10) are formed in the lower surface of the stirring barrel (7), a sliding rod I (11) fixed to one end of the first rotating rod (4) is arranged in the T-shaped sliding groove I (9) in a sliding mode, a square through groove (12) is formed in the side wall of the T-shaped sliding groove I (9), a square driving rod (13) is arranged in the square through groove (12) in a sliding mode, an inclined plane (55) is formed in one end of the square driving rod (13), a rebounding assembly (14) is arranged on one side of the square driving rod (13), a starting assembly (15) used for driving the square driving rod (13) to rotate is arranged at one end of the square driving rod (, shrinkage pool (17) have all been seted up at slide bar two (16) both ends, all be fixed with spring one (18) in shrinkage pool (17), it is provided with triangle fixture block (19) to slide in shrinkage pool (17), the one end and the triangle fixture block (19) of spring one (18) are fixed, churn (7) lower extreme is provided with promotion subassembly (20) that drive triangle fixture block (19) immigration shrinkage pool (17), be provided with ejection of compact subassembly (21) that will expect the release in churn (7).

2. The efficient aggregate saturated surface dry stirring device according to claim 1, wherein the driving component (8) comprises a first motor (22), a first bevel gear (23), a second bevel gear (24) and a third bevel gear (25), the first motor (22) is fixed on the inner wall of the placing groove (6), the output shaft of the first motor (22) is fixed with the first bevel gear (23), two sides of the first motor (22) are respectively fixed with a first support plate (26) and a second support plate (27), a first threaded rod (28) is rotatably arranged on the first support plate (26), a second threaded rod (29) is rotatably arranged on the second support plate (27), one end of the first threaded rod (28) is fixed with the second bevel gear (24), one end of the second threaded rod (29) is fixed with the third bevel gear (25), and the first bevel gear (23) is meshed with the second bevel gear (24), the bevel gear I (23) is meshed with the bevel gear III (25), a limiting groove (30) is formed in the side wall of the placing groove (6), a first push rod (31) and a second push rod (32) are arranged in the limiting groove (30) in a sliding mode, a first threaded rod (28) and a second threaded rod (29) are in threaded fit with the first push rod (31) and the second push rod (32) respectively, a first sliding groove (33) and a second sliding groove (34) are formed in the first rotating rod (4) and the second rotating rod (5) respectively, and one end of the first push rod (31) and one end of the second push rod (32) are arranged in the first sliding groove (33) and the second sliding groove (34) in a sliding mode respectively.

3. The efficient aggregate saturated noodle stirring device according to claim 2, wherein the starting assembly (15) comprises a second motor (35) and a connecting rod (36), a support (37) is fixed on the base (1) on one side of the placing groove (6), the second motor (35) is fixed on the support (37), an output shaft of the second motor (35) is fixed with the connecting rod (36), a square connecting hole (38) is formed in one end, away from the second motor (35), of the connecting rod (36), and the square connecting hole (38) is matched with the square driving rod (13).

4. The efficient aggregate saturated dough dry stirring device according to claim 3, wherein the pushing assembly (20) comprises a first air cylinder (39) and a flat plate (40), a second groove (41) is formed in the lower surface of the stirring cylinder (7), the first air cylinder (39) is fixed in the second groove (41), a piston rod of the first air cylinder (39) is fixed with the flat plate (40), and pushing blocks (42) are symmetrically fixed on the flat plate (40).

5. The efficient aggregate saturated noodle stirring device according to claim 4, wherein the rebounding assembly (14) comprises a rebounding block (43) and a second spring (44), a rebounding groove (45) is formed in the inner wall of the square through groove (12), the rebounding block (43) is slidably arranged in the rebounding groove (45), the rebounding block (43) is fixed with the square driving rod (13), and two ends of the second spring (44) are respectively fixed with the rebounding block (43) and the rebounding groove (45) side wall.

6. The efficient aggregate saturated surface dry stirring device according to claim 5, wherein the discharging assembly (21) comprises a second cylinder (46) and a material pushing plate (47), the second cylinder (46) is fixed in the stirring cylinder (7), the material pushing plate (47) is slidably arranged in the stirring cylinder (7), and a piston rod of the second cylinder (46) is fixed with the material pushing plate (47).

7. The efficient aggregate saturated surface dry stirring device according to claim 6, wherein the stirring device (2) comprises a motor III (49), a bevel gear IV (50) and a bevel gear V (51), the motor III (49) is fixed on a support column (52), a shell (67) is fixed on the support column (52), an output shaft of the motor III (49) penetrates through the side wall of the shell (67) and is fixed with the bevel gear IV (50), a rotating column (68) is arranged on the lower wall of the shell (67) in a penetrating and rotating mode, the upper end of the rotating column (68) is fixed with the bevel gear V (51), the bevel gear IV (50) is meshed with the bevel gear V (51), a fixed block (69) is fixed on the inner wall of the shell (67), an inner gear ring (70) is fixed on the lower end of the fixed block (69), a driving rod (71) is arranged on the rotating column (68) in a penetrating and rotating mode, the upper end of the driving rod (71) is fixedly provided with a gear six (72) meshed with the inner gear ring (70), and one end, far away from the gear six (72), of the driving rod (71) is fixedly provided with a stirring blade (73).

8. The high-efficiency aggregate saturated surface dry stirring device as claimed in claim 7, the temperature rising assembly (59) comprises a heating cavity (60) and a fan (61) which are arranged on the base (1), a heating box (62) is arranged on one side of the bottom plate (74), the fan (61) is fixed at one end of the heating box (62), a plurality of electric heating wires (63) are fixed in the heating box (62), a first telescopic air inlet pipe (64) and a second telescopic air inlet pipe (65) are connected to the heating box (62), one end of the first telescopic air inlet pipe (64) far away from the heating box (62) is communicated with the heating cavity (60), an air outlet (82) is arranged at one end of the heating cavity (60) far away from the first telescopic air inlet pipe (64), one end, far away from the heating box (62), of the second air inlet pipe (65) is fixed to the lower end of the shell (67), and a valve (83) is fixed to the second air inlet pipe (65).

9. The efficient aggregate saturated noodle stirring device according to claim 8, wherein the moving device (75) comprises a gear seven (76) and a rack (77), the side wall of the pillar (52) is provided with a driving groove (78), the side wall of the driving groove (78) is provided with a rotating rod (79) in a penetrating and rotating manner, one end of the rotating rod (79) is fixed with a hand lever (80), the rotating rod (79) is fixed with the gear seven (76), the rack (77) is fixed on the side wall of the base (1), the gear seven (76) is meshed with the rack (77), and the base (1) is provided with a tightening bolt (81).

10. The efficient aggregate saturated dough dry stirring device according to claim 9, wherein a PLC (48) is fixed on the base (1), and a voice broadcasting machine (66) is fixed on the side wall of the base (1).