CN111264578B

CN111264578B - Dough kneading device for increasing dough stiffness

Info

Publication number: CN111264578B
Application number: CN202010210556.9A
Authority: CN
Inventors: 陈毅强
Original assignee: Longhai Andrew Ma Fu Machinery Co Ltd
Current assignee: Longhai Andrew Ma Fu Machinery Co Ltd
Priority date: 2020-03-24
Filing date: 2020-03-24
Publication date: 2022-07-15
Anticipated expiration: 2040-03-24
Also published as: CN111264578A

Abstract

The invention discloses a dough kneading device for increasing dough stiffness, which belongs to the field of dough kneading devices and comprises a first dough kneading roller and a second dough kneading roller, wherein one end of each of the first dough kneading roller and the second dough kneading roller is provided with a screw rod to push and extrude dough; the first dough kneading roller and the second dough kneading roller rotate in a differential speed mode, and the rotating speed of the first dough kneading roller is changed for a plurality of times in a period of one rotation of the second dough kneading roller. When two dough kneading rollers rotate and knead dough, the axial acting force can be generated when the two dough kneading rollers act on the dough through the differential, the axial acting force is continuously changed through the change of the rotating speed for a plurality of times, and therefore the force of kneading the dough back and forth by a hand is simulated, and the dough is more chewy.

Description

Dough kneading device for increasing dough strength

Technical Field

The invention relates to the field of dough kneading devices, in particular to a dough kneading device capable of increasing the strength of dough.

Background

Generally, when making flour food, the dough is kneaded into proper tenacity and then made into other flour food products. The traditional method for making wheaten food is mostly manual operation, namely kneading the wheaten food with hands to make the wheaten food have proper toughness. However, as the social demands increase, the demand for the face food products increases day by day, and manually kneading the face material consumes more manpower, and bacteria are easily bred due to insanitation when the food raw materials are directly contacted by hands, and especially, the manual operation is easy to generate sweating, and sweat is easy to fall off and mix into the face material, which is insanitation. At present, most of the existing mechanical kneaders adopt rigid components such as a compression roller, a kneading disc, a stirring disc and the like to repeatedly fold, knead and reverse dough, the kneading force of the rigid components is large, the dough is clean and sanitary, the kneaded dough has good elasticity and large strength, and the labor intensity of workers is greatly reduced.

However, the following disadvantages are also present: the dough made by kneading and rolling by adopting the rigid parts has single kneading force and no change due to the contact of the rigid parts, and the palatability and the additional value of the product are difficult to be compared with the manually kneaded dough in the aspects of orientation, flavor, taste and the like.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention aims to provide a dough kneading device for increasing the strength of dough, which continuously changes the acting force applied to the dough and simulates the acting force of hands kneading the dough back and forth, so that the dough is more strong.

In order to achieve the purpose, the invention adopts the following technical scheme:

the invention provides a dough kneading device for increasing the strength of dough, which comprises a first dough kneading roller and a second dough kneading roller, wherein one ends of the first dough kneading roller and the second dough kneading roller are respectively provided with a screw rod so as to push and extrude the dough; the first dough kneading roller and the second dough kneading roller rotate in a differential speed mode, and the rotating speed of the first dough kneading roller is changed for a plurality of times in a period of one rotation of the second dough kneading roller.

The invention has the preferable technical scheme that the dough kneading machine further comprises a driving shaft which is coaxial with the first dough kneading roller, a power output end of the driving shaft is provided with a first bevel gear, the first dough kneading roller is provided with a second bevel gear, a speed regulating turntable is arranged between the first bevel gear and the second bevel gear, and the speed regulating turntable is rotationally connected with the first dough kneading roller; the speed regulation rotary table is provided with a speed regulation bevel gear, the speed regulation bevel gear is rotatably connected with one end of the speed regulation rotary table, and the speed regulation bevel gear is meshed with the first bevel gear and the second bevel gear simultaneously.

The second dough kneading roller is provided with a speed regulating cam which is abutted against the other end of the speed regulating turntable so as to drive the speed regulating turntable to rotate around the axis of the first dough kneading roller.

The invention has the preferable technical scheme that one side of the speed regulation turntable, which is close to the speed regulation cam, is provided with an inclined groove, and the depth of the inclined groove is gradually deepened from one end, which is close to the first kneading roller, to the other end.

The invention preferably adopts the technical scheme that the device also comprises a powder sprinkling device; the powder spraying device comprises a powder spraying screw rod, a third bevel gear is coaxially arranged at the other end of the speed regulating bevel gear, a fourth bevel gear is arranged on the powder spraying screw rod, and the third bevel gear is meshed with the fourth bevel gear; the powder spraying screw is provided with a T-shaped sleeve, the T-shaped sleeve is rotationally connected with the powder spraying screw, the tip of the third bevel gear is provided with a connecting rotating shaft, and the connecting rotating shaft is rotationally connected with the T-shaped sleeve.

The powder spraying device comprises a powder spraying device body, a limiting shell, a guide rail, a spring and a limiting shell, wherein the powder spraying device body is provided with a plurality of installing slide blocks, the limiting shell is arranged on the outer side of each installing slide block, the installing slide blocks can slide up, down, left and right, the bottom end of each installing slide block is provided with the guide rail, the installing slide blocks are connected with the guide rails in a sliding mode, the guide rails are connected with the limiting shell in a sliding mode, the guide rails can slide up and down, the spring is arranged on the lower side of each guide rail, and the spring abuts against the inner bottom wall of the limiting shell.

The invention preferably adopts the technical scheme that the powder sprinkling device further comprises a powder sprinkling barrel, the powder sprinkling barrel is sleeved outside the powder sprinkling screw, a powder inlet bin is arranged at the upper side of the powder sprinkling barrel, a powder outlet is arranged at the lower side of the powder sprinkling barrel and positioned above the first kneading roller, and flour at the powder inlet bin is conveyed to the powder outlet by the powder sprinkling screw.

The invention preferably adopts the technical scheme that a powder spraying plate is arranged at the powder outlet, the powder spraying plate is detachably connected to the powder outlet of the powder spraying barrel, and a plurality of powder outlet holes are formed in the powder spraying plate.

The invention has the preferable technical scheme that one end of the driving shaft is provided with a speed reducing motor, a driving gear is arranged on the driving shaft, a driven gear is arranged on the second kneading roller, and the driving gear is meshed with the driven gear.

The beneficial effects of the invention are as follows:

the invention provides a dough kneading device for increasing the strength of dough, which comprises a first dough kneading roller and a second dough kneading roller, wherein one ends of the first dough kneading roller and the second dough kneading roller are respectively provided with a screw rod so as to push and extrude the dough; the first dough kneading roller and the second dough kneading roller rotate in a differential speed mode, and the rotating speed of the first dough kneading roller is changed for a plurality of times in a period of one rotation of the second dough kneading roller. When two dough kneading rollers rotate to knead dough, can produce axial effort when making two dough kneading rollers act on the dough through the differential, make axial effort constantly change through the change of a plurality of times rotational speed to imitate the power that the dough was kneaded to the staff round trip, make the dough more chewy.

Drawings

FIG. 1 is a schematic view of the overall structure of a dough kneading apparatus for increasing the firmness of dough according to an embodiment of the present invention;

FIG. 2 is a schematic view of a kneading apparatus for increasing the firmness of dough provided in an embodiment of the present invention from the bottom;

FIG. 3 is an enlarged schematic view of the circled portion of FIG. 2 provided in an embodiment of the present invention;

FIG. 4 is a schematic diagram of the overall structure of a dough control mechanism for increasing the stiffness of the dough according to an embodiment of the present invention;

FIG. 5 is an enlarged schematic view of portion A of FIG. 4 provided in accordance with an embodiment of the present invention;

FIG. 6 is a schematic view of a door control mechanism provided in an embodiment of the present invention;

in the figure:

1. a reduction motor; 2. a second kneading roller; 3. a speed regulating bevel gear; 4. a speed regulation rotary table; 5. a first kneading roller; 6. a powder sprinkling device; 11. a drive shaft; 12. a driving gear; 13. a first bevel gear; 21. a screw rod; 22. a speed regulating cam; 23. a driven gear; 31. a third bevel gear; 32. a T-shaped sleeve; 33. a fourth bevel gear; 41. an inclined groove; 51. a second bevel gear; 61. a powder spraying screw rod; 62. feeding into a powder bin; 63. a powder sprinkling cylinder; 64. a powder outlet; 641. a powder sprinkling plate; 71. a limiting shell; 72. installing a sliding block; 73. a guide rail; 74. a spring. 10. Kneading a flour bin; 25. kneading dough rollers; 8. a dough pushing mechanism; 81. a push surface cylinder; 82. an optical axis; 83. a sliding sleeve; 84. a noodle pushing frame; 9. a bin gate control mechanism; 91. a telescopic cylinder; 92. connecting a sliding sleeve; 93. a transmission rod; 94. a sliding mechanism; 95. mounting a column; 941. a slider; 942. a slide rail; 943. and a limiting block.

Detailed Description

The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.

As shown in fig. 1-3, the dough kneading device for increasing the stiffness of dough provided in the present embodiment includes a first dough kneading roller 5 and a second dough kneading roller 2, wherein one end of each of the first dough kneading roller 5 and the second dough kneading roller 2 is provided with a screw 21 to push and extrude the dough; the first kneading roller 5 and the second kneading roller 2 rotate at a differential speed, and the first kneading roller 5 changes in rotation speed several times per one rotation of the second kneading roller 2. The dough is placed in first roller 5 of kneading dough, between second roller 2 of kneading dough, first roller 5 of kneading dough, second roller 2 differential rotates of kneading dough, thereby make the dough be located first roller 5 of kneading dough, and the dough that is arranged in second roller 2 of kneading dough has different speeds along the axial, thereby make the dough produce axial effort, first roller 5 of kneading dough constantly changes the rotational speed when second roller 2 of kneading dough rotates simultaneously, thereby make the effort that first roller 5 of kneading dough acted on the dough also constantly change, thereby the simulation staff uses continuous effort to knead to the dough, thereby make the dough more chewy.

Preferably, the dough kneading device for increasing the dough stiffness further comprises a driving shaft 11 coaxially arranged with the first dough kneading roller 5, a power output end of the driving shaft 11 is provided with a first bevel gear 13, the first dough kneading roller 5 is provided with a second bevel gear 51, a speed regulating turntable 4 is arranged between the first bevel gear 13 and the second bevel gear 51, and the speed regulating turntable 4 is rotatably connected with the first dough kneading roller 5; the speed regulation rotary table 4 is provided with a speed regulation bevel gear 3, the speed regulation bevel gear 3 is rotationally connected with one end of the speed regulation rotary table 4, and the speed regulation bevel gear 3 is meshed with the first bevel gear 13 and the second bevel gear 51 simultaneously. One end of the driving shaft 11 is provided with a speed reducing motor 1, the driving shaft 11 is provided with a driving gear 12, the second kneading roller 2 is provided with a driven gear 23, and the driving gear 12 is meshed with the driven gear 23. The driving shaft 11 is driven by the reduction motor 1 to rotate at a slower speed, meanwhile, the driving shaft 11 drives the first bevel gear 13 to rotate, the first bevel gear 13 drives the speed regulation bevel gear 3 to rotate, then the second bevel gear 51 is driven by the speed regulation bevel gear 3 to rotate, and finally the first dough kneading roller 5 is driven to rotate. When the first bevel gear 13 drives the speed regulation bevel gear 3 to rotate, acting force of the speed regulation bevel gear 3 along the tangential direction of the meshing point is given, so that the speed regulation rotary table 4 connected with the speed regulation bevel gear 3 is pushed to rotate around the axis of the first dough kneading roller 5, and the other end of the speed regulation rotary table 4 is close to the speed regulation cam 22. When the thrust of the first bevel gear 13 to the speed regulation bevel gear 3 is insufficient or the forward and reverse rotation is needed, the back side of the other end of the speed regulation rotary table 4 is provided with the return spring 74, so that the speed regulation rotary table 4 always has a movement trend approaching the speed regulation cam 22, and the speed regulation cam 22 can better control the rotation of the speed regulation rotary table 4.

Further, a speed regulating cam 22 is arranged on the second dough kneading roller 2, and the speed regulating cam abuts against the other end of the speed regulating rotary table 4 to drive the speed regulating rotary table 4 to rotate around the axis of the first dough kneading roller 5. One side of the speed regulation rotary table 4 close to the speed regulation cam 22 is provided with an inclined groove 41, and the depth of the inclined groove 41 gradually deepens from one end close to the first kneading roller 5 to the other end. The timing cam 22 is provided with one or more projecting points on the outside so that the timing turntable 4 can be pushed to rotate a plurality of times in one cycle. When the speed regulation turntable 4 is pushed to rotate, so that the speed regulation bevel gear 3 moves towards the same direction of the rotation direction of the second bevel gear 51, the displacement distance of the speed regulation bevel gear 3 is offset with the rotation path thereof, so that the relative rotation angle generated by acting on the second bevel gear 51 is reduced, and the rotation speed of the first dough kneading roller 5 is reduced, when the rotation speed difference between the first dough kneading roller 5 and the second dough kneading roller 2 is not large, and the rotation speed of the first dough kneading roller 5 is greater than that of the second dough kneading roller 2, the rotation speed of the first dough kneading roller 5 can be adjusted to be less than that of the second dough kneading roller 2 by adjusting the rotation speed, so that the acting force acting on the dough along the axial direction can change direction. When a large axial acting force is needed, the difference between the rotating speeds of the first dough kneading roller 5 and the second dough kneading roller 2 is large, the acting force direction cannot be changed and only the acting force can be changed under the action of the speed regulating bevel gear 3, and the speed reducing motor 1 can be controlled to rotate forwards and backwards to change the acting force direction.

Preferably, the device also comprises a powder spraying device 6; the powder sprinkling device 6 comprises a powder sprinkling screw rod 61, a third bevel gear 31 is coaxially arranged at the other end of the speed regulating bevel gear 3, a fourth bevel gear 33 is arranged on the powder sprinkling screw rod, and the third bevel gear 31 is meshed with the fourth bevel gear 33; the powder spraying screw is provided with a T-shaped sleeve 32, the T-shaped sleeve 32 is rotatably connected with the powder spraying screw 61, the tip of the third bevel gear 31 is provided with a connecting rotating shaft, and the connecting rotating shaft is rotatably connected with the T-shaped sleeve 32. The third bevel gear 31 is driven to rotate while the speed regulation bevel gear 3 rotates, and meanwhile when the speed regulation cam 22 pushes the speed regulation rotary table 4 to rotate, the flour sprinkling device 6 is pulled to move together through the T-shaped sleeve 32, so that dynamic flour sprinkling is realized, flour is sprinkled on the dough more uniformly, and the dough is less prone to adhesion on the first dough kneading roller 5 and the second dough kneading roller 2. The flour sprinkling screw is driven by a third bevel gear 31 and synchronously driven with the first dough kneading roller 5 and the second dough kneading roller 2, so that flour is sprinkled while dough kneading is carried out, and the strength of the dough is increased.

Preferably, two ends of the powder sprinkling device 6 are provided with installation sliding blocks 72, the outer side of each installation sliding block 72 is provided with a limit housing 71, a gap exists between the two side walls of each installation sliding block 72 and the two side walls of the limit housing 71, so that the installation sliding blocks 72 can slide up and down, left and right, the bottom ends of the installation sliding blocks 72 are provided with guide rails 73, the installation sliding blocks 72 are in sliding connection with the guide rails 73, the guide rails 73 are in sliding connection with the limit housing 71, so that the guide rails 73 can slide up and down, the lower sides of the guide rails 73 are provided with springs 74, and the springs 74 abut against the inner bottom wall of the limit housing 71. When the speed regulation rotary table 4 is pushed open by the speed regulation cam 22 and rotates, the flour sprinkling device 6 is driven to slide left, namely, moves towards the direction of the speed regulation cam 22 and moves downwards at the same time, and when the speed regulation rotary table 4 returns, the original position is returned, so that the flour sprinkling device 6 continuously vibrates, and flour can better fall off.

Preferably, the powder sprinkling device 6 further comprises a powder sprinkling cylinder 63, the powder sprinkling cylinder 63 is sleeved outside the powder sweeping screw, a powder inlet bin 62 is arranged on the upper side of the powder sprinkling cylinder 63, a powder outlet 64 is arranged on the lower side of the powder sprinkling cylinder 63, the powder outlet 64 is positioned above the first kneading roller 5, and flour in the powder inlet bin 62 is conveyed to the powder outlet 64 by the powder sprinkling screw. Furthermore, a powder spraying plate 641 is arranged at the powder outlet 64, the powder spraying plate 641 is detachably connected to the powder outlet 64 of the powder spraying cylinder 63, and a plurality of powder outlets are arranged on the powder spraying plate 641. Spill whitewashed board 641 through detachable makes more even the following through-hole of flour drop, dismantles simultaneously and spills the clearance of the flour of being convenient for behind the whitewashed board 641.

As shown in fig. 4-6, the dough kneading control mechanism provided in this embodiment for increasing the stiffness of the dough comprises a dough kneading chamber 10, a dough pushing mechanism 8, and a chamber door control mechanism 9; two dough kneading rollers 25 are arranged in the dough kneading bin 10 side by side to push and extrude dough, a bin gate is arranged at the discharge port of the dough kneading bin 10, and one side of the bin gate is rotatably connected with the dough kneading bin 10; the bin gate control mechanism 9 is connected below the bin gate to control the bin gate to be turned upwards towards the kneading roller 25 and to be turned downwards for opening; the dough pushing mechanism 8 is positioned above the bin gate, and the dough pushing mechanism 8 can slide back and forth along the axial direction of the dough kneading roller 25 to push the extruded dough. Preferably, the bin gate control mechanism 9 comprises a telescopic cylinder 91, a transmission rod 93 and a sliding mechanism 94; the sliding mechanism 94 is fixed on the lower side wall of the bin door, one end of the transmission rod 93 is hinged with the sliding mechanism 94, and the other end of the transmission rod 93 is hinged with the power output end of the telescopic cylinder 91; the lower side of the dough kneading bin 10 is provided with a mounting column 95, the mounting column 95 is rotatably connected with a connecting sliding sleeve 92, the connecting sliding sleeve 92 is sleeved on the transmission rod 93, and the transmission rod 93 is slidably connected with the connecting sliding sleeve 92. Preferably, the sliding mechanism 94 includes a sliding rail 942, a sliding block 941, and a limiting block 943, the sliding rail 942 is fixed on the lower side of the cabin door, the sliding block 941 is slidably connected to the sliding rail 942, the driving rod 93 is hinged to the sliding block 941, the limiting block 943 is detachably fixed to the sliding rail 942, and the limiting block 943 is located on two sides of the sliding block 941 to limit the slidable distance of the sliding block 941. When the control bin gate rotates towards the kneading roller 25, the position of the limiting block 943 on the sliding rail 942 is set in advance. The extension of the telescopic cylinder 91 is controlled, so that the transmission rod 93 is pushed to slide, the slider 941 is further pushed to slide along the sliding rail 942, and when the slider 941 slides to the position of the limit block 943, the telescopic cylinder 91 continues to extend. One end of the transmission rod 93 can only move along the length direction of the telescopic rod of the telescopic cylinder 91, and the other end does not move any more, so that the bin door is pushed open towards the inside when the telescopic rod extends, the dough is pushed towards the dough kneading roller 25, and the connection sliding sleeve 92 continuously rotates in an adaptive manner in the whole pushing process. On the contrary, when the telescopic cylinder 91 is continuously contracted, the sliding block 941 abuts against the other limiting block 943, and the bin door is pulled open downwards when the transmission rod 93 is continuously pulled. The position adjustment of two stopper 943 can conveniently change the degree that the door opened to both sides to make things convenient for not equidimension dough to do the adaptability adjustment.

In order to conveniently push dough, the dough pushing mechanism 8 comprises an optical axis 82, two sliding sleeves 83, a dough pushing frame 84 and two dough pushing cylinders 81, two ends of the optical axis 82 are fixed on the inner side wall of the dough kneading bin 10, the two sliding sleeves 83 are connected to the optical axis 82 in a sliding manner, the dough pushing frame 84 is fixed on the two sliding sleeves 83, the two dough pushing cylinders 81 are fixed on the outer walls of two sides of the dough kneading bin 10, and the power output ends of the dough pushing cylinders 81 extend into the dough kneading bin 10 and abut against the dough pushing frame 84 so as to telescopically push the dough pushing frame 84 to slide along the optical axis 82. Preferably, the optical axis 82 and the rotating shaft of the bin gate are respectively located at two sides of the discharge port, and the rotating shaft of the bin gate is located at one side close to the dough kneading roller 25. The dough pushing frame 84 is located at one end of the dough kneading roller 25, and when the dough falls onto the dough pushing frame 84 after one kneading, the dough pushing frame 84 is pushed to the other side by controlling the dough pushing cylinder 81 on the side, and the dough pushing cylinder 81 on the other side can push the dough pushing frame 84 back in the opposite direction. Meanwhile, the dough pushing frame 84 is rotatably connected to the optical axis 82 through a sliding sleeve 83, when the bin door is pushed upwards, the dough pushing frame 84 can be synchronously pushed upwards, so that interference cannot occur, and the dough pushing frame 84 rotates towards the other dough kneading roller 25, so that dough can move in the dough kneading roller 25 more conveniently.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the spirit and scope of the invention. The present invention is not intended to be limited to the specific embodiments disclosed herein, but other embodiments falling within the scope of the appended claims are intended to be within the scope of the present invention.

Claims

1. The utility model provides an increase malaxation device that dough was chewy, its characterized in that:

the dough kneading machine comprises a first dough kneading roller (5) and a second dough kneading roller (2), wherein spiral rods (21) are arranged at one ends of the first dough kneading roller (5) and the second dough kneading roller (2) respectively so as to push and extrude dough; the first kneading roller (5) and the second kneading roller (2) rotate in a differential speed manner, and the first kneading roller (5) changes the rotating speed for a plurality of times in the period of each rotation of the second kneading roller (2); the dough kneading machine further comprises a driving shaft (11) which is coaxial with the first dough kneading roller (5), a first bevel gear (13) is arranged at the power output end of the driving shaft (11), a second bevel gear (51) is arranged on the first dough kneading roller (5), a speed regulating turntable (4) is arranged between the first bevel gear (13) and the second bevel gear (51), and the speed regulating turntable (4) is rotatably connected with the first dough kneading roller (5);

a speed regulating cam (22) is arranged on the second kneading roller (2), an inclined groove (41) is arranged on one side, close to the speed regulating cam (22), of the speed regulating rotary table (4), and the depth of the inclined groove (41) is gradually deepened from one end, close to the first kneading roller (5), to the other end;

a speed regulating bevel gear (3) is arranged on the speed regulating rotary table (4), the speed regulating bevel gear (3) is rotatably connected with one end of the speed regulating rotary table (4), and the speed regulating bevel gear (3) is meshed with the first bevel gear (13) and the second bevel gear (51) simultaneously;

the speed regulation cam (22) is abutted against the other end of the speed regulation rotary table (4) so as to drive the speed regulation rotary table (4) to rotate around the axis of the first kneading roller (5).

2. The dough kneading apparatus of claim 1, wherein:

also comprises a powder sprinkling device (6); the powder sprinkling device (6) comprises a powder sprinkling screw rod (61), a third bevel gear (31) is coaxially arranged at the other end of the speed regulating bevel gear (3), a fourth bevel gear (33) is arranged on the powder sprinkling screw rod (61), and the third bevel gear (31) is meshed with the fourth bevel gear (33);

the powder spraying device is characterized in that a T-shaped sleeve (32) is arranged on the powder spraying screw rod (61), the T-shaped sleeve (32) is rotationally connected with the powder spraying screw rod (61), a connecting rotating shaft is arranged at the tip of the third bevel gear (31), and the connecting rotating shaft is rotationally connected with the T-shaped sleeve (32).

3. Dough kneading apparatus for increasing the chewiness of dough as claimed in claim 2, wherein:

spill whitewashed device (6) both ends and be provided with installation slider (72), installation slider (72) outside is provided with spacing casing (71), so that installation slider (72) can be about slided from top to bottom, the bottom of installation slider (72) is provided with guide rail (73), installation slider (72) with guide rail (73) sliding connection, guide rail (73) with spacing casing (71) sliding connection, so that guide rail (73) can be the upper and lower direction slip, guide rail (73) downside is provided with spring (74), spring (74) with diapire offsets in spacing casing (71).

4. Dough kneading apparatus for increasing the chewiness of dough as claimed in claim 2, wherein:

spill whitewashed device (6) still including spilling a powder section of thick bamboo (63), spill powder section of thick bamboo (63) cup joint in spill the outside of powder screw rod (61), the upside of spilling powder section of thick bamboo (63) is provided with into powder storehouse (62), the downside of spilling powder section of thick bamboo (63) is provided with powder outlet (64), powder outlet (64) are located first dough roller (5) top, spill powder screw rod (61) will it carries extremely to advance powder storehouse (62) department flour outlet (64) department.

5. Dough mixing apparatus for increasing the firmness of dough as claimed in claim 4, wherein:

go out powder mouth (64) department and be provided with and spill powder board (641), spill powder board (641) can dismantle connect in the play powder mouth (64) department of spilling powder section of thick bamboo (63), be provided with a plurality of powder hole on spilling powder board (641).

6. Dough kneading apparatus for increasing the chewiness of dough as claimed in claim 1, wherein:

one end of the driving shaft (11) is provided with a speed reducing motor (1), a driving gear (12) is arranged on the driving shaft (11), a driven gear (23) is arranged on the second kneading roller (2), and the driving gear (12) is meshed with the driven gear (23).