Automatic dough mixing machine
Technical Field
The utility model relates to the technical field of flour processing, in particular to an automatic flour mixing machine.
Background
A dough kneading machine belongs to a dough machine, which mainly uniformly mixes flour and water, and comprises a vacuum type dough kneading machine and a non-vacuum type dough kneading machine which are divided into a horizontal type, a vertical type, a single shaft, a double shaft, a half shaft and the like.
The existing dough kneading mode is a manual mode, when dough kneading is carried out manually, because the manpower is limited, when the dough kneading reaches a certain time, people feel tired, so on one hand, the dough kneading efficiency is reduced, on the other hand, the force is not enough, the dough can not be completely kneaded, dry dough exists in the dough, and the dough kneading is not uniform, and the defects of manual dough kneading and water are that: time consuming, hard, the easy ratio is inhomogeneous, leads to kneading dough soft or hard enough, and the steamed bun that evaporates does not have a strength way, and traditional flour-mixing machine is when kneading dough, just simple beating usually for the face atress of beating of dough is inhomogeneous, needs the secondary to beat, extravagant manpower and materials, and the qualification rate of most dough is not high simultaneously, leads to having reduced work efficiency, and the practicality is not high.
Therefore, there is a need for an automatic dough mixing machine to solve the problem of inconvenient operation of the dough mixing machine during manufacturing.
SUMMERY OF THE UTILITY MODEL
The utility model provides an automatic dough mixer, which solves the problem that the operation of the dough mixer is inconvenient during manufacturing.
In order to achieve the purpose, the utility model adopts the following technical scheme: an automatic dough kneading machine comprises a dough kneading tank, wherein a support frame is fixed on one side wall of the dough kneading tank, a rotating rod is connected to the interior of the dough kneading tank in a rotating manner, a plurality of dough kneading rods which are symmetrically arranged are fixed on the outer surface of the rotating rod, a helical blade is connected to one side inner wall of the dough kneading tank below the rotating rod in a rotating manner, rotating wheels are fixed at the same end of the rotating rod and the helical blade, belts are arranged on the outer surfaces of the two rotating wheels, a rotating motor fixed at one end of the helical blade is installed at one side of the dough kneading tank, a water tank is communicated with the top end of the dough kneading tank, a feed hopper is communicated with one side of the top end of the dough kneading tank at the water tank, a discharge hopper is communicated with the bottom end of the dough kneading tank, a driving gear a is fixed at one end of the rotating rod, a driving gear b is fixed on the outer surface of one end of the helical blade, the outer wall of one side of wasing the jar is fixed with rotates the cover, one side of kneading dough jar is provided with the spacing subassembly that is the symmetry and sets up.
Preferably, the limiting component comprises two symmetrically arranged fixing sleeves fixed with the inner wall of one side of the dough kneading tank, a sliding rod is connected inside the fixed sleeve in a sliding manner, a moving plate is fixed at one end of the sliding rod, a telescopic spring is fixed between the side wall of one side of the feed hopper and the side wall of one side of the fixed sleeve, the telescopic spring is sleeved on the outer surface of the sliding rod in a sliding manner, the inner wall of one side of the supporting frame is connected with two symmetrically arranged tooth-shaped rings in a sliding manner, a pushing plate is fixed at one end of the toothed ring and positioned in the feeding hopper, a rotating rod is rotatably connected with the inner wall of one side of the supporting frame, one end of the rotating rod is positioned above the supporting frame and is fixedly provided with a driven gear b meshed with the driving gear b, and the other end of the rotating rod is fixedly provided with a half gear meshed with the toothed ring.
Preferably, one side wall of the discharge hopper is attached to one side wall of the movable plate, and the sliding rod is connected with the inner wall of one side of the discharge hopper in a sliding mode.
Preferably, the feed hopper with the one end surface of play hopper is the inclined plane, tooth shape ring and slurcam all with one side lateral wall sliding connection of support frame.
Preferably, the inner part of the rotating sleeve is rotatably connected with a connecting rod, one end of the connecting rod is fixed with a driven gear a meshed with the driving gear a, and one end of the connecting rod is fixed with a second gear.
Preferably, one side inner wall sliding connection of feeder hopper has the screening board, one side lateral wall of screening board be fixed with second gear engaged with second toothed plate, one side lateral wall of feeder hopper is fixed with two stoppers that are the symmetry and set up.
Compared with the prior art, the utility model has the beneficial effects that:
1. according to the utility model, through the arrangement of the limiting component, the pushing plate can push the sliding rod, so that the movable plate can move left and right in the feeding hopper, the product at the feeding port is pushed, the product discharging efficiency is improved, the anti-blocking function of the feeding hopper is enhanced, and the working time of workers is saved.
2. According to the utility model, the second gear and the second toothed plate can perform meshing motion through the mutual matching of the driving gear b and the driven gear b, so that the screening plate can move left and right under the movement of the toothed ring, the screening function of raw materials is realized, the purity of processed products is improved, and the quality of the products is improved.
Drawings
FIG. 1 is a schematic diagram of a main sectional structure of an automatic dough mixer according to the present invention;
FIG. 2 is an enlarged view of area A of FIG. 1;
FIG. 3 is a schematic partial front view of an automated dough mixer in accordance with the present invention;
FIG. 4 is a top partial schematic view of an automated dough mixer toothed ring according to the present invention.
In the figure: 1. a dough kneading tank; 2. a support frame; 3. rotating the rod; 4. kneading dough rods; 5. a helical blade; 6. a rotating wheel; 7. a belt; 8. rotating the motor; 9. a water tank; 10. a feed hopper; 11. a discharge hopper; 12. a driving gear a; 13. a driving gear b; 14. rotating the sleeve; 15. a limiting component; 150. fixing a sleeve; 151. a slide bar; 152. moving the plate; 153. a tension spring; 154. a toothed ring; 155. a push plate; 156. rotating the rod; 157. a driven gear b; 158. a half gear; 16. a connecting rod; 17. a driven gear a; 18. a second gear; 19. a screening plate; 20. a second toothed plate; 21. and a limiting block.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.
Referring to fig. 1-4, an automatic dough kneading machine comprises a dough kneading tank 1, a support frame 2 is fixed on one side wall of the dough kneading tank 1, a rotating rod 3 is rotatably connected inside the dough kneading tank 1, a plurality of dough kneading rods 4 which are symmetrically arranged are fixed on the outer surface of the rotating rod 3, a helical blade 5 is rotatably connected on one side inner wall of the dough kneading tank 1 below the rotating rod 3, rotating wheels 6 are fixed on the same ends of the rotating rod 3 and the helical blade 5, belts 7 are arranged on the outer surfaces of the two rotating wheels 6, a rotating motor 8 fixed on one end of the helical blade 5 is installed on one side of the dough kneading tank 1, a water tank 9 is communicated with the top end of the dough kneading tank 1, a feed hopper 10 is communicated with one side of the water tank 9 on the top end of the dough kneading tank 1, a discharge hopper 11 is communicated with the bottom end of the dough kneading tank 1, a driving gear a12 is fixed on one end of the rotating rod 3, a driving gear b13 is fixed on the outer surface of one end of the helical blade 5, wash one side outer wall of jar 1 and be fixed with rotating sleeve 14, one side of kneading dough jar 1 is provided with the spacing subassembly 15 that is the symmetry and sets up, and is concrete, through the setting of spacing subassembly 15, improves the ejection of compact efficiency to the product, has strengthened the anti-blocking function of feeder hopper 10.
The limiting component 15 comprises two symmetrically arranged fixing sleeves 150 fixed with the inner wall of one side of the dough kneading tank 1, a sliding rod 151 is slidably connected inside the fixing sleeves 150, a moving plate 152 is fixed at one end of the sliding rod 151, a telescopic spring 153 is fixed between the side wall of one side of the feed hopper 10 and the side wall of one side of the fixing sleeves 150, the telescopic spring 153 is slidably sleeved on the outer surface of the sliding rod 151, two symmetrically arranged toothed rings 154 are slidably connected with the inner wall of one side of the support frame 2, a pushing plate 155 is fixed at one end of the toothed rings 154, the pushing plate 155 is positioned inside the feed hopper 10, a rotating rod 156 is rotatably connected with the inner wall of one side of the support frame 2, a driven gear b157 meshed with a driving gear b13 is fixed at one end of the rotating rod 156 positioned above the support frame 2, a half gear 158 meshed with the toothed rings 154 is fixed at the other end of the rotating rod 156, and specifically, through the arrangement of the pushing plate 155 and the sliding rod 151, the pushing plate 155 pushes the sliding rod 151 so that the moving plate 152 can move left and right inside the hopper 10.
One side wall of the discharge hopper 11 is attached to one side wall of the moving plate 152, the sliding rod 151 is slidably connected to one side inner wall of the discharge hopper 11, the surfaces of one ends of the feed hopper 10 and the discharge hopper 11 are inclined planes, the toothed ring 154 and the pushing plate 155 are both slidably connected to one side wall of the support frame 2, the inside of the rotating sleeve 14 is rotatably connected to the connecting rod 16, one end of the connecting rod 16 is fixed to the driven gear a17 engaged with the driving gear a12, one end of the connecting rod 16 is fixed to the second gear 18, one side inner wall of the feed hopper 10 is slidably connected to the sieving plate 19, one side wall of the sieving plate 19 is fixed to the second toothed plate 20 engaged with the second gear 18, and one side wall of the feed hopper 10 is fixed to two symmetrically arranged limiting blocks 21, the screen plate 19 is allowed to move left and right by the movement of the toothed ring 154 by the meshing movement of the second gear 18 with the second toothed plate 20.
The working principle is as follows: when the dough kneading machine needs to be used, raw materials are put into the dough kneading tank 1 from the feeding hopper 10, a power supply is started, the rotating motor 8 is driven to rotate, the rotating motor 8 can drive the helical blade 5 to rotate when rotating, the helical blade 5 can drive the driving gear b13 and the rotating wheel 6 to rotate simultaneously when rotating, the rotating wheel 6 can drive the belt 7 to rotate when rotating, the two rotating wheels 6 can rotate simultaneously when the belt 7 rotates, the rotating rod 3 can rotate under the rotation of the rotating wheel 6, the rotating rod 3 can drive the dough kneading rod 4 and the driving gear a12 to rotate when rotating, the driving gear a12 can drive the driven gear a17 to rotate when rotating, the driven gear a17 can drive the connecting rod 16 to rotate when rotating, the connecting rod 16 can drive the second gear 18 to rotate when rotating, the second gear 18 drives the second toothed plate 20 to move when rotating, the second toothed plate 20 drives the sieving plate 19 to move when moving, the sieving plate 19 slides inside the feeding hopper 10, the driving gear b13 drives the driven gear b157 to rotate when rotating, the driven gear b157 drives the rotating rod 156 to rotate when rotating, the rotating rod 156 drives the half gear 158 to rotate when rotating, the half gear 158 drives the half gear 158 to move when rotating, the toothed ring 154 slides inside the supporting frame 2, the toothed ring 154 drives the pushing plate 155 to move when moving, the pushing plate 155 contacts with the sliding rod 151 to extrude the sliding rod 155 when moving, the sliding rod 151 moves under the extrusion of the pushing plate 155, the sliding rod 151 drives the fixing sleeve 150 and the moving plate 152 to move when moving, the moving plate 152 slides inside the hopper 10, and the extension spring 153 contracts when the fixing sleeve 150 moves.
The rotating motor 8 is commercially available, and the rotating motor 8 is provided with a power supply, which belongs to the mature technology in the field and is fully disclosed, so repeated description in the specification is omitted.
The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.