CN214546864U - Flour mixing machine for producing fine dried noodles - Google Patents

Abstract

The utility model relates to a vermicelli production technical field discloses flour-mixing machine is used in vermicelli production, including organism and the unloader of setting on the organism, unloader is used for carrying the flour raw materials to the organism in. The blanking device comprises a blanking hopper, a first material guide plate, a second material guide plate and a driving assembly, wherein the first material guide plate and the second material guide plate are sequentially arranged in the blanking hopper from top to bottom. And a first slag discharge port and a second slag discharge port are respectively arranged at two sides of the blanking hopper, and the first slag discharge port is positioned above the second slag discharge port. One end of the first material guide plate inclines downwards and extends to the first slag discharge port. One end of the second material guide plate inclines downwards and extends to the second slag discharge port. And a first screen and a second screen are respectively arranged on the plate bodies of the first material guide plate and the second material guide plate. Through the unloader that sets up on the organism, can effectively screen the solid powder piece that adulterates in the flour raw materials, avoid the stirring rake to take place to damage when the dough is kneaded and is stirred, improve life to guarantee the vermicelli product quality who produces.

Description

Flour mixing machine for producing fine dried noodles

Technical Field

The utility model relates to a vermicelli production technical field especially relates to flour-mixing machine is used in vermicelli production.

Background

The dough mixer is one of the main components of complete equipment for producing wheaten food such as bread, biscuits, cakes and the like. The basic process of dough mixer modulation is as follows: firstly, raw materials such as flour, water, food additives and the like are poured into a hopper, a motor is started to enable a stirring paddle to rotate, flour particles are uniformly combined with water under the stirring of the stirring paddle, irregular small aggregates in a colloid state are formed firstly, then the small aggregates are bonded with each other, a plurality of scattered large blocks are formed gradually, and the blocks are expanded and kneaded into a whole block of dough along with the continuous pushing of the stirring paddle.

However, in the prior art, when flour raw materials are conveyed to a flour mixing machine, solid powder blocks doped in the flour raw materials cannot be effectively screened, so that the stirring paddle is easy to damage when the flour is mixed and stirred, the service life is shortened, and the quality of produced fine dried noodle products is also influenced.

SUMMERY OF THE UTILITY MODEL

For having solved among the prior art when carrying flour raw materials to the flour-mixing machine, the technical problem of the solid powder piece of doping in the unable effective screening flour raw materials, the utility model provides a flour-mixing machine is used in vermicelli production.

The utility model discloses a following technical scheme realizes: the dough mixer for producing the fine dried noodles comprises a machine body and a discharging device arranged on the machine body, wherein the discharging device is used for conveying a flour raw material into the machine body;

the blanking device comprises a blanking hopper, a first material guide plate, a second material guide plate and a driving assembly, wherein the first material guide plate and the second material guide plate are sequentially arranged in the blanking hopper from top to bottom; a first slag discharge port and a second slag discharge port are respectively arranged on two sides of the blanking hopper, and the first slag discharge port is positioned above the second slag discharge port; one end of the first material guide plate inclines downwards and extends to the first slag discharge port; one end of the second material guide plate inclines downwards and extends to the second slag discharge port; a first screen and a second screen are respectively arranged on the plate bodies of the first material guide plate and the second material guide plate, and the mesh number of the first screen is smaller than that of the second screen;

and the inclination of the first material guide plate and the second material guide plate is continuously and synchronously adjusted through a driving assembly.

As a further improvement of the scheme, the corresponding connection part of the first guide plate and the first slag discharge port is rotatably connected through a pin shaft, and the corresponding connection part of the second guide plate and the second slag discharge port is rotatably connected through a pin shaft.

As a further improvement of the above scheme, the driving assembly comprises a chute vertically arranged in the blanking hopper, and the chute is positioned between the first material guide plate and the second material guide plate; the sliding block is connected in the sliding groove in a sliding mode, a first connecting rod and a second connecting rod are arranged at the top and the bottom of the sliding block respectively, and the other ends of the first connecting rod and the second connecting rod are rotatably connected with the first material guide plate and the second material guide plate respectively through hinge pins.

As a further improvement of the scheme, a second motor is installed in the blanking hopper, a rotating rod perpendicular to the second motor is fixedly inserted into an output shaft of the second motor in a penetrating mode, the other end of the rotating rod is rotatably connected with a swinging rod, and the other end of the swinging rod is rotatably connected with the block body of the sliding block.

As a further improvement of the above scheme, a third material guide plate located above the first material guide plate is obliquely arranged in the blanking hopper, the inclination direction of the third material guide plate is opposite to that of the first material guide plate, and a material passing groove is formed in the third material guide plate.

As a further improvement of the above scheme, the organism includes that the top has the agitator tank of water filling port, motor one and with the pan feeding mouth that hopper material export is linked together down are installed to the top of agitator tank, the bottom of agitator tank has the discharge gate, the internally mounted of agitator tank has the stirring rake, the output shaft of motor one penetrates in the agitator tank, and connect the stirring rake is located the stirring rake below be provided with the slope on the agitator tank inner wall and direct the guide holder of discharge gate.

As a further improvement of the scheme, a material conveying groove is formed in the lower portion of the stirring box, an input port of the material conveying groove is connected with a discharge port of the stirring box through a guide pipe, an auger is arranged in the material conveying groove, a third motor is installed on the material conveying groove, and an output shaft of the third motor penetrates into the material conveying groove and is connected with the auger.

As a further improvement of the scheme, a discharge valve is installed on the conduit.

The utility model has the advantages that:

the utility model discloses a flour-mixing machine is used in vermicelli production, through the unloader that sets up on the organism, can effectively screen out the solid powder piece of adulteration in the flour raw materials, avoid the stirring rake to take place to damage when the dough is stirred, improve life to the vermicelli product quality who guarantees to produce.

The utility model discloses a flour-mixing machine is used in vermicelli production, stock guide one and stock guide two can carry out continuous luffing motion under drive assembly's effect, can improve the screening efficiency of flour raw materials on screen cloth one and screen cloth two greatly.

Drawings

Fig. 1 is a schematic sectional structure view of a dough mixer for producing fine dried noodles according to an embodiment of the present invention;

fig. 2 is a schematic sectional structure view of the discharging hopper in fig. 1.

Description of the main symbols:

1. a stirring box; 2. a first motor; 3. a stirring paddle; 4. a water injection port; 5. a feeding port; 6. a discharge port; 7. a guide seat; 8. feeding a hopper; 9. a first slag discharge port; 10. a second slag discharge port; 11. a first material guide plate; 12. a second material guide plate; 13. a first screen mesh; 14. a second screen; 15. a chute; 16. a slider; 17. a first connecting rod; 18. a second connecting rod; 19. a second motor; 20. a rotating rod; 21. a swing rod; 22. a third material guide plate; 23. a material passing groove; 24. a discharge valve; 25. a material conveying groove; 26. a packing auger; 27. and a third motor.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

Referring to fig. 1 to 2, the dough mixer for producing fine dried noodles comprises a machine body and a feeding device arranged on the machine body, wherein the feeding device is used for conveying flour raw materials into the machine body so as to subsequently knead the flour raw materials.

The blanking device comprises a blanking hopper 8, a first guide plate 11, a second guide plate 12 and a driving assembly, wherein the first guide plate 11 and the second guide plate 12 are sequentially arranged in the blanking hopper 8 from top to bottom. Two sides of the blanking hopper 8 are respectively provided with a first slag discharge port 9 and a second slag discharge port 10, and the first slag discharge port 9 is positioned above the second slag discharge port 10. One end of the first material guide plate 11 inclines downwards and extends to the first slag discharge opening 9. One end of the second material guide plate 12 inclines downwards and extends to the second slag discharge port 10. The first screen 13 and the second screen 14 are respectively arranged on the plate bodies of the first guide plate 11 and the second guide plate 12, the mesh number of the first screen 13 is smaller than that of the second screen 14, and the second screen 14 can screen particle impurities with smaller particle sizes in the flour raw material relative to the first screen 13. The mesh number of the first screen 13 and the second screen 14 can be selected and designed according to actual production requirements.

The inclination of the first guide plate 11 and the inclination of the second guide plate 12 are continuously and synchronously adjusted through the driving assembly, so that the first guide plate 11 and the second guide plate 12 can swing up and down in a reciprocating mode, and the screening efficiency of flour raw materials on the first guide plate 11 and the second guide plate 12 is improved.

The corresponding connection part of the first guide plate 11 and the first slag discharge hole 9 is rotatably connected through a pin shaft, and the corresponding connection part of the second guide plate 12 and the second slag discharge hole 10 is rotatably connected through a pin shaft.

The driving assembly comprises a chute 15 vertically arranged in the blanking hopper 8, and the chute 15 is positioned between the first material guide plate 11 and the second material guide plate 12. The sliding chute 15 is connected with a sliding block 16 in a sliding mode, the top and the bottom of the sliding block 16 are respectively provided with a first connecting rod 17 and a second connecting rod 18, and the other ends of the first connecting rod 17 and the second connecting rod 18 are respectively connected with the first material guide plate 11 and the second material guide plate 12 in a rotating mode through pin shafts. In this embodiment, the first material guiding plate 11 and the second material guiding plate 12 are both provided with a circular groove (not labeled), and the end portions of the first connecting rod 17 and the second connecting rod 18 are respectively inserted into the corresponding circular grooves in a rotating manner. The first material guide plate 11 and the second material guide plate 12 are driven to swing synchronously through adjusting the position of the sliding block 16 in the sliding chute 15 and through the first connecting rod 17 and the second connecting rod 18.

A second motor 19 is installed in the blanking hopper 8, a rotating rod 20 perpendicular to the second motor 19 is fixedly inserted into an output shaft of the second motor 19, the other end of the rotating rod 20 is rotatably connected with a swinging rod 21, and the other end of the swinging rod 21 is rotatably connected with the block body of the sliding block 16. The second motor 19 may be a reduction motor.

A third guide plate 22 positioned above the first guide plate 11 is obliquely arranged in the blanking hopper 8, the third guide plate 22 is opposite to the first guide plate 11 in the oblique direction, and a material passing groove 23 is arranged on the third guide plate 22. The flour material on the third guide plate 22 can directly fall to the higher part of the first guide plate 11 through the material passing groove 23.

The organism includes that the top has agitator tank 1 of water filling port 4, and motor 2 and the pan feeding mouth 5 that is linked together with 8 material exports of lower hopper are installed to the top of agitator tank 1, and motor 2 can be gear motor. The bottom of agitator tank 1 has discharge gate 6, and the bore specification of discharge gate 6 can select or design according to actual conditions in this embodiment to guarantee the smooth of stirring back dough and pass through.

The internally mounted of agitator tank 1 has stirring rake 3, and the output shaft of motor 2 penetrates in agitator tank 1 and connect stirring rake 3, is provided with the guide holder 7 of the directional discharge gate 6 of slope on the 1 inner wall of agitator tank that is located the stirring rake 3 below. The cross-section of guide holder 7 is the trapezium structure, can lead the dough after the stirring of piling up in agitator tank 1 bottom to discharge in discharge gate 6 department.

A material conveying groove 25 is arranged below the stirring box 1, an input port of the material conveying groove 25 is connected with the material outlet 6 of the stirring box 1 through a guide pipe (not marked), an auger 26 is arranged in the material conveying groove 25, a third motor 27 is arranged on the material conveying groove 25, and an output shaft of the third motor 27 penetrates into the material conveying groove 25 and is connected with the auger 26. Motor three 27 may be a reduction motor.

The guide pipe is provided with a discharge valve 24, and the discharge valve 24 can be an electric control valve or a manual valve so as to conveniently control the on-off of the guide pipe.

The utility model discloses a theory of operation specifically does, during the use, on the three 22 guide plates of hopper 8 drop into with the flour raw materials down, the flour raw materials falls to the higher department of guide plate 11 behind silo 23 along the inclined plane way of guide plate three 22 under the action of gravity, and move to screen cloth 13 along guide plate 11 under the action of gravity, the great powder piece of conglomeration can't see through screen cloth 13 and can continue to remove to arrange cinder notch one 9 and discharge hopper 8 down in the flour raw materials, and the flour raw materials that can pass through screen cloth 13 then fall to the higher department of guide plate two 12, and move to screen cloth two 14 along guide plate two 12 under the action of gravity, the less powder piece of conglomeration can't see through screen cloth two 14 can continue to move to arrange cinder notch two 10 and discharge hopper 8 down, and the flour that can pass through screen cloth two 14 then gets into agitator tank 1 through the pan feeding mouth of agitator tank 1. Inject suitable amount of water into the agitator tank 1 through water filling port 4, the output shaft of motor 2 drives stirring rake 3, along with the continuous promotion of stirring rake 3, the monoblock dough is kneaded into in the lump extension. Due to a series of actions of continuous overturning, kneading, stretching, extruding, convection and the like of the dough by the stirring paddle, the flour raw materials are mixed more homogenously, so that the dough with smooth surface, certain elasticity, toughness and extensibility is prepared.

After the dough is made, the discharge valve 24 is opened, the dough enters the conveying chute 25 through the discharge port 6 and the guide pipe, and the output shaft of the control motor III 27 drives the auger 26 to rotate so as to convey the dough for subsequent production and processing.

It is worth mentioning that when flour raw materials pass through the first material guide plate 11 and the second material guide plate 12, the output shaft of the second control motor 19 drives the rotating rod 20 to rotate, the rotating rod 20 drives the oscillating rod 21 to oscillate, the oscillating rod 21 drives the sliding block 16 to slide in the sliding groove 15 in a reciprocating manner, so that the sliding block 16 respectively drives the first material guide plate 11 and the second material guide plate 12 to oscillate in a reciprocating manner around the rotating connection part corresponding to the inner wall of the stirring box 1 through the first connecting rod 17 and the second connecting rod 18, the inclination of the first material guide plate 11 and the second material guide plate 12 is changed continuously, and the screening efficiency of the flour raw materials is improved.

The above description is only exemplary of the present invention and should not be construed as limiting the present invention, and any modifications, equivalents and improvements made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (8)

1. The flour mixing machine for producing fine dried noodles is characterized by comprising a machine body and a blanking device arranged on the machine body, wherein the blanking device is used for conveying flour raw materials into the machine body;

the blanking device comprises a blanking hopper, a first material guide plate, a second material guide plate and a driving assembly, wherein the first material guide plate and the second material guide plate are sequentially arranged in the blanking hopper from top to bottom; a first slag discharge port and a second slag discharge port are respectively arranged on two sides of the blanking hopper, and the first slag discharge port is positioned above the second slag discharge port; one end of the first material guide plate inclines downwards and extends to the first slag discharge port; one end of the second material guide plate inclines downwards and extends to the second slag discharge port; a first screen and a second screen are respectively arranged on the plate bodies of the first material guide plate and the second material guide plate, and the mesh number of the first screen is smaller than that of the second screen;

and the inclination of the first material guide plate and the second material guide plate is continuously and synchronously adjusted through a driving assembly.

2. The noodle maker for producing fine dried noodles according to claim 1, wherein the corresponding connection part of the first guide plate and the first slag discharge port is rotatably connected through a pin shaft, and the corresponding connection part of the second guide plate and the second slag discharge port is rotatably connected through a pin shaft.

3. The noodle maker according to claim 1, wherein the driving assembly comprises a chute vertically disposed in the discharge hopper, the chute being located between the first guide plate and the second guide plate; the sliding block is connected in the sliding groove in a sliding mode, a first connecting rod and a second connecting rod are arranged at the top and the bottom of the sliding block respectively, and the other ends of the first connecting rod and the second connecting rod are rotatably connected with the first material guide plate and the second material guide plate respectively through hinge pins.

4. The fine dried noodle production dough mixing machine according to claim 3, wherein a second motor is installed in the discharging hopper, a rotating rod perpendicular to the second motor is fixedly inserted into an output shaft of the second motor, the other end of the rotating rod is rotatably connected with a swinging rod, and the other end of the swinging rod is rotatably connected with the block body of the sliding block.

5. The fine dried noodle production dough mixing machine as claimed in claim 1, wherein a third material guide plate is obliquely arranged in the blanking hopper and is positioned above the first material guide plate, the third material guide plate is opposite to the first material guide plate in the inclination direction, and a material passing groove is arranged on the third material guide plate.

6. The fine dried noodle production dough mixing machine according to claim 1, wherein the machine body comprises a stirring box with a water injection port at the top, a first motor and a feeding port communicated with the discharging hopper material outlet are mounted at the top of the stirring box, a discharging port is formed at the bottom of the stirring box, a stirring paddle is mounted inside the stirring box, an output shaft of the first motor penetrates into the stirring box and is connected with the stirring paddle, and a guide seat which is obliquely directed to the discharging port is arranged on the inner wall of the stirring box below the stirring paddle.

7. The fine dried noodle production dough mixing machine according to claim 6, wherein a material conveying groove is arranged below the stirring box, an input port of the material conveying groove is connected with a material outlet of the stirring box through a guide pipe, an auger is arranged in the material conveying groove, a third motor is arranged on the material conveying groove, and an output shaft of the third motor penetrates into the material conveying groove and is connected with the auger.

8. A dough mixer for producing fine dried noodles according to claim 7, wherein the duct is provided with a discharge valve.

Images