CN112335704A - Automatic watered automatic dough kneading device that overturns through dough hardness - Google Patents

Abstract

The invention relates to the field of food processing, and discloses a reversible automatic dough kneading device capable of automatically adding water through dough hardness, which comprises a box body, wherein an outer barrel cavity with an upward opening and a backward opening is arranged in the box body, an outer barrel is connected in a sliding fit manner in the outer barrel cavity, a water adding control cavity is arranged at the left side of a turbine cavity, a stirring shaft which extends through a turbine cavity, an inner barrel rotating cavity and an inner barrel cavity to a stirring belt wheel cavity in a rightward extending manner and extends to the water adding control cavity in a leftward extending manner is connected in the right end wall of the water adding control cavity in a rotating fit manner, the flour is stirred through a belt wheel and a stirring rod to form dough, the hardness of the dough is judged through the rotating speed of the stirring shaft in the stirring process, the water adding is controlled through the opening and closing of the water controlling cavity through a rack and a wire wheel, the automatic, and the stirring drum is turned over through the worm gear and the worm, so that the dough is conveniently taken out.

Description

Automatic watered automatic dough kneading device that overturns through dough hardness

Technical Field

The invention relates to the field of food processing, in particular to a reversible automatic dough kneading device capable of automatically adding water according to the hardness of dough.

Background

Most present dough kneading devices need the manual work to add water to the condition that needs the manual work to observe the dough adds water to the dough, not only consumes the manpower, and inefficiency still has the potential safety hazard, and the dough of kneading out leads to the dough quality discrepancy because of the manual work is added water, and most dough kneading devices are after kneading the process, can not take out the dough easily, influence production efficiency.

Disclosure of Invention

The invention aims to provide the reversible automatic dough kneading device capable of automatically adding water according to the hardness of dough, which can overcome the defects in the prior art and improve the practicability of equipment.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a reversible automatic dough kneading device capable of automatically adding water through dough hardness, which comprises a box body, wherein an outer barrel cavity with an upward opening and a backward opening is arranged in the box body, an outer barrel is connected in a sliding fit manner in the outer barrel cavity, a fixed magnet cavity with a downward opening is arranged in the outer barrel, a water adding magnet cavity is communicated with the right side of the fixed magnet cavity, an inner barrel rotating cavity with an upward opening and a backward opening is arranged in the outer barrel, a water flowing cavity is communicated with the right side of the inner barrel rotating cavity, a water storage cavity with an upward opening is communicated with the right side of the water flowing cavity, a water stopping cavity is communicated with the lower side of the water flowing cavity, an inner barrel is connected in a rotating fit manner in the inner barrel rotating cavity, an inner barrel cavity with an upward opening is arranged in the inner barrel, an inner barrel through cavity which is communicated with the inside, the right side of the inner barrel rotating cavity is provided with a stirring belt wheel cavity, the left side of the inner barrel rotating cavity is provided with a turbine cavity, the front side of the turbine cavity is provided with a rotating belt wheel cavity, the rear side of the rotating belt wheel cavity is provided with a transmission bevel gear cavity positioned on the lower side of the turbine cavity, the left side of the turbine cavity is provided with a water adding control cavity, the right end wall of the water adding control cavity is in rotating fit connection with a stirring shaft which extends through the turbine cavity, the inner barrel rotating cavity and the inner barrel cavity to the stirring belt wheel cavity and extends to the water adding control cavity leftwards, the tail end of the left side of the stirring shaft is fixedly connected with a centrifugal block, eight centrifugal cavities which are circumferentially distributed by taking the stirring shaft as a center and have outward openings are arranged in the centrifugal block, the centrifugal cavities are in sliding fit connection with centrifugal throwing blocks, the centrifugal throwing blocks are close to the side end surfaces of the stirring shaft and, the utility model discloses a centrifugal piece's water feeding control chamber, including centrifugal piece, water feeding control chamber right side intercommunication is connected with and is located the rack piece of centrifugal piece upside, rack piece up end with fixedly connected with rack piece spring between water feeding control chamber upper end wall, rack piece right-hand member face fixedly connected with rack, water feeding control chamber interior sliding fit is connected with and is located the attraction magnet piece of centrifugal piece downside, attraction magnet piece down the terminal surface with water feeding control chamber lower end wall.

On the basis of the technical scheme, a pulling magnet is connected with a pulling magnet in a sliding fit manner, a pulling magnet spring is fixedly connected between the right end face of the pulling magnet and the right end wall of the pulling magnet cavity, a switch shaft is connected between the front side end wall and the rear side end wall of the wire wheel cavity in a rotating fit manner, a wire wheel shaft extending forwards into the wire wheel cavity is connected with the rear side end wall of the wire wheel cavity in a rotating fit manner, a switch one-way bearing is fixedly connected onto the switch shaft, a switch shaft gear is connected onto the switch one-way bearing in a rotating fit manner, a switch rod positioned at the front side of the switch one-way bearing is also fixedly connected onto the switch shaft, an induction switch capable of being abutted against the switch rod is fixedly connected onto the lower end wall of the wire wheel cavity, a torsion spring is fixedly connected between the front end of the wire wheel shaft and, the reel shaft is also fixedly connected with a reel one-way bearing positioned at the rear side of the reel, and the reel one-way bearing is connected with a reel shaft gear meshed with the switch shaft gear in a rotating fit manner.

On the basis of the technical scheme, a motor is fixedly connected in the right end wall of the stirring belt wheel cavity, the left end surface of the motor is fixedly connected with a power shaft which extends leftwards and penetrates through the stirring belt wheel cavity to the transmission bevel gear cavity, the power shaft is fixedly connected with a power shaft belt wheel positioned in the stirring belt wheel cavity, the tail end of the right side of the stirring shaft is fixedly connected with a stirring shaft belt wheel, a stirring belt positioned in the stirring belt wheel cavity is connected between the stirring shaft belt wheel and the power shaft belt wheel in a power fit manner, the right side of the stirring belt wheel cavity is communicated with a stirring tightening cavity, a stirring tightening magnetic block capable of tightening the stirring belt is connected in the stirring tightening cavity in a sliding fit manner, the right end wall of the stirring tightening cavity is fixedly connected with a stirring electromagnet, and a stirring tightening spring is fixedly connected between the right end surface of the stirring tightening magnetic block and the, and the stirring shaft is fixedly connected with a plurality of stirring blocks positioned in the inner cylinder cavity.

On the basis of the technical scheme, the tail end of the left side of the power shaft is fixedly connected with a power shaft bevel gear, the front end wall of the transmission bevel gear cavity is connected with a transmission shaft which extends forwards into the rotation belt wheel cavity and extends backwards into the transmission bevel gear cavity in a rotating fit manner, the tail end of the rear side of the transmission shaft is fixedly connected with a transmission shaft bevel gear which is meshed with the power shaft bevel gear, the tail end of the front side of the transmission shaft is fixedly connected with a transmission shaft belt wheel, the front end wall of the turbine cavity is connected with a worm which extends forwards into the rotation belt wheel cavity and extends backwards into the turbine cavity in a rotating fit manner, the tail end of the front side of the worm is fixedly connected with a worm shaft belt wheel, the worm shaft belt wheel and the transmission shaft belt wheel are connected with a rotating belt which is positioned in the rotation belt wheel cavity in a power fit, the inner cylinder rotating rod is connected with a turbine cavity right end wall, extends leftwards to an inner cylinder rotating rod fixedly connected with a turbine right end face and extends rightwards to an inner cylinder left end face fixedly connected with the inner cylinder rotating rod, the inner cylinder rotating rod is located on the outer side of the stirring shaft and is connected with the stirring shaft in a rotating and matching mode, the rear side of the rotating belt cavity is provided with a rotating tightening cavity located on the lower side of the turbine cavity and located on the upper side of the transmission bevel gear cavity, a rotating tightening cavity is connected with a rotating tightening magnetic block capable of tightening the rotating belt in a sliding matching mode, the rear end wall of the rotating tightening cavity is fixedly connected with a rotating electromagnet, and the rear end face of the rotating tightening magnetic block and the rotating tightening spring are fixedly connected between the.

On the basis of the technical scheme, terminal surface under the urceolus with fixedly connected with urceolus spring between urceolus chamber lower extreme wall, fixedly connected with is located on the urceolus chamber lower extreme wall fixed magnet of fixed magnet chamber downside, it is connected with water adding magnet to add water magnet intracavity sliding fit, water adding magnet right-hand member face with fixedly connected with adds water magnet spring between water adding magnet chamber right-hand member wall, water adding magnet with fixedly connected with adds water magnet stay cord between pulling magnet, it can seal to be connected with in the stagnant water intracavity sliding fit the stagnant water piece in flowing water chamber, terminal surface under the stagnant water piece with fixedly connected with stagnant water piece spring between stagnant water chamber lower extreme wall, stagnant water piece with fixedly connected with adds water stay cord between water adding magnet, stagnant water piece with fixedly connected with line wheel stay cord between the line.

The invention has the beneficial effects that: stir the formation dough through band pulley and puddler to flour to the hardness of dough is judged to the rotational speed through the (mixing) shaft at the stirring in-process, the on-off control through rack and line wheel control flow water cavity adds water, the realization is added water to the automation of dough, the dough that obtains the hardness is suitable, the efficiency of kneading the dough has been improved, the quality of dough has been promoted, the manpower has been reduced, and realize the upset of churn through the turbine worm, conveniently take out the dough.

Drawings

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

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view showing the overall structure of a reversible automatic kneading apparatus of the present invention which automatically adds water according to the hardness of dough.

Fig. 2 is a schematic top view of the structure of fig. 1.

Fig. 3 is an enlarged schematic view of a in fig. 1.

Fig. 4 is a schematic diagram of the structure of B-B in fig. 3.

Fig. 5 is a schematic view of the structure of C-C in fig. 1.

Fig. 6 is an enlarged schematic view of D in fig. 1.

Fig. 7 is an enlarged schematic view of E in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The reversible automatic dough kneading device capable of automatically adding water through dough hardness disclosed by the accompanying drawings 1-5 comprises a box body 10, an outer barrel cavity 11 with an upward opening and a backward opening is arranged in the box body 10, an outer barrel 12 is connected in the outer barrel cavity 11 in a sliding fit manner, a fixed magnet cavity 30 with a downward opening is arranged in the outer barrel 12, a water adding magnet cavity 78 is communicated with the right side of the fixed magnet cavity 30, an inner barrel rotating cavity 22 with an upward opening and a backward opening is arranged in the outer barrel 12, a flowing water cavity 15 is communicated with the right side of the inner barrel rotating cavity 22, a water storage cavity 13 with an upward opening is communicated with the right side of the flowing water cavity 15, a water stopping cavity 17 is communicated with the lower side of the flowing water cavity 15, an inner barrel 19 is connected in a matching manner with the inner barrel rotating cavity 22, an inner barrel cavity 77 with an upward opening is arranged in the inner barrel 19, an inner, the inner cylinder rotates the sealing washer 39 that the chamber 22 right-hand member wall fixedly connected with corresponds with the running water chamber 15, the inner cylinder rotates the chamber 22 right side and is equipped with stirring belt wheel chamber 26, the inner cylinder rotates the chamber 22 left side and is equipped with turbine chamber 62, turbine chamber 62 front side is equipped with rotates belt wheel chamber 64, it is equipped with the transmission bevel gear chamber 69 that is located turbine chamber 62 downside to rotate belt wheel chamber 64 rear side, turbine chamber 62 left side is equipped with adds water control chamber 23, add water control chamber 23 right-hand member wall internal rotation fit connection have extend run through right turbine chamber 62 with inner cylinder rotate chamber 22 and inner cylinder chamber 77 to in stirring belt wheel chamber 26 and extend to the (mixing) shaft 21 in adding water control chamber 23 left side, the terminal fixedly connected with centrifugation piece 79 in the (mixing) 21 left side, be equipped with eight in the centrifugation piece 79 with the (mixing) 21 is the outside centrifugal chamber 80 of opening of central circumference distribution, the centrifugal cavity 80 is connected with a centrifugal swinging block 82 in a sliding fit manner, the centrifugal swinging block 82 is close to the end face of the side of the stirring shaft 21, a centrifugal spring 81 is fixedly connected between the end wall of the side of the stirring shaft 21 and the centrifugal cavity 80, a rack block 45 positioned on the upper side of the centrifugal block 79 is connected in the water adding control cavity 23 in a sliding fit manner, a rack block spring 44 is fixedly connected between the upper end face of the rack block 45 and the upper end wall of the water adding control cavity 23, a rack 47 is fixedly connected on the right end face of the rack block 45, an attraction magnet block 46 positioned on the lower side of the centrifugal block 79 is connected in the water adding control cavity 23 in a sliding fit manner, an attraction magnet spring 48 is fixedly connected between the lower end face of the attraction magnet block 46 and the lower end wall of the water adding control cavity 23, an attraction magnet 51 is fixedly connected in the right end face of the attraction magnet block 46, and a pulling, the right side of the water feeding control cavity 23 is communicated with a wire wheel cavity 43 positioned on the upper side of the centrifugal block 79.

In addition, in one embodiment, a pulling magnet 50 is connected in a sliding fit manner in the pulling magnet cavity 83, a pulling magnet spring 49 is fixedly connected between the right end face of the pulling magnet 50 and the right end wall of the pulling magnet cavity 83, a switch shaft 58 is connected in a rotating fit manner between the front and rear side end walls of the reel cavity 43, a reel shaft 52 extending forward into the reel cavity 43 is connected in a rotating fit manner in the rear side end wall of the reel cavity 43, a switch one-way bearing 54 is fixedly connected to the switch shaft 58, a switch shaft gear 55 is connected in a rotating fit manner in the switch one-way bearing 54, a switch lever 57 located at the front side of the switch one-way bearing 54 is further fixedly connected to the switch shaft 58, an induction switch 56 capable of abutting against the switch lever 57 is fixedly connected to the lower end wall of the reel cavity 43, a torsion spring 60 is fixedly connected between the front end of the reel shaft 52 and the front side end wall, the reel 52 is fixedly connected with a reel 61, the reel 52 is also fixedly connected with a reel one-way bearing 59 positioned at the rear side of the reel 61, and the reel one-way bearing 59 is connected with a reel shaft gear 53 meshed with the switch shaft gear 55 in a rotating and matching manner.

In addition, in an embodiment, a motor 35 is fixedly connected in the right end wall of the stirring pulley cavity 26, a power shaft 29 extending through the stirring pulley cavity 26 to the transmission bevel gear cavity 69 is fixedly connected to the left end surface of the motor 35, a power shaft pulley 27 located in the stirring pulley cavity 26 is fixedly connected to the power shaft 29, a stirring shaft pulley 18 is fixedly connected to the right end of the stirring shaft 21, a stirring belt 28 located in the stirring pulley cavity 26 is connected between the stirring shaft pulley 18 and the power shaft pulley 27 in a power fit manner, a stirring tensioning cavity 36 is communicated with the right side of the stirring pulley cavity 26, a stirring tensioning magnet 40 capable of tensioning the stirring belt 28 is connected in the stirring tensioning cavity 36 in a power fit manner, a stirring electromagnet 38 is fixedly connected to the right end wall of the stirring tensioning cavity 36, and a stirring tensioning spring 37 is fixedly connected between the right end surface of the stirring tensioning magnet 40 and the right end wall of the stirring tensioning cavity 36 And a plurality of stirring blocks 20 positioned in the inner cylinder cavity 77 are fixedly connected to the stirring shaft 21.

In addition, in one embodiment, a power shaft bevel gear 24 is fixedly connected to the left end of the power shaft 29, a transmission shaft 67 extending forward into the rotating pulley cavity 64 and extending backward into the transmission bevel gear cavity 69 is rotatably coupled to the front end wall of the transmission bevel gear cavity 69, a transmission shaft bevel gear 70 engaged with the power shaft bevel gear 24 is fixedly connected to the rear end wall of the transmission shaft 67, a transmission shaft pulley 68 is fixedly connected to the front end of the transmission shaft 67, a worm 76 extending forward into the rotating pulley cavity 64 and extending backward into the worm cavity 62 is rotatably coupled to the front end wall of the worm cavity 62, a worm shaft pulley 66 is fixedly connected to the front end of the worm 76, a rotating belt 65 located in the rotating pulley cavity 64 is rotatably coupled to the worm shaft pulley 66 and the transmission shaft pulley 68, the stirring shaft 21 is connected with a turbine 63 which is positioned in the turbine cavity 62 and meshed with the worm 76 in a rotating fit manner, an inner cylinder rotating rod 84 which extends leftwards to be fixedly connected with the right end face of the turbine 63 and extends rightwards to be fixedly connected with the left end face of the inner cylinder 19 is connected with the right end wall of the turbine cavity 62 in a rotating fit mode, the inner cylinder rotating rod 84 is positioned outside the stirring shaft 21 and is connected with the stirring shaft 21 in a rotating matching way, a rotary tightening chamber 74 which is positioned at the lower side of the turbine chamber 62 and at the upper side of the transmission bevel gear chamber 69 is arranged at the rear side of the rotary pulley chamber 64, a rotating tightening magnetic block 75 capable of tightening the rotating belt 65 is connected in the rotating tightening cavity 74 in a sliding fit manner, the rear end wall of the rotating tightening cavity 74 is fixedly connected with a rotating electromagnet 72, and a rotating tightening spring 71 is fixedly connected between the rear end face of the rotating tightening magnetic block 75 and the rear end wall of the rotating tightening cavity 74.

In addition, in one embodiment, an outer cylinder spring 25 is fixedly connected between the lower end surface of the outer cylinder 12 and the lower end wall of the outer cylinder cavity 11, a fixed magnet 31 positioned at the lower side of the fixed magnet cavity 30 is fixedly connected to the lower end wall of the outer cylinder cavity 11, the watering magnet cavity 78 is connected with the watering magnet 34 in a sliding fit way, a watering magnet spring 32 is fixedly connected between the right end face of the watering magnet 34 and the right end wall of the watering magnet cavity 78, a watering magnet pull rope 33 is fixedly connected between the watering magnet 34 and the pulling magnet 50, a water stop block 16 which can seal the running water cavity 15 is connected in the water stop cavity 17 in a sliding fit manner, a water stop block spring 14 is fixedly connected between the lower end surface of the water stop block 16 and the lower end wall of the water stop cavity 17, a water adding pull rope 42 is fixedly connected between the water stopping block 16 and the water adding magnet 34, and a wire wheel pull rope 41 is fixedly connected between the water stopping block 16 and the wire wheel 61.

The fixing and connecting method in this embodiment includes, but is not limited to, bolting, welding, and the like.

As shown in fig. 1-5, when the apparatus of the present invention is in an initial state, the inner cylinder through cavity 73 corresponds to the seal ring 39, the outer cylinder spring 25 is in a relaxed state, the fixed magnet cavity 30 is located on the upper side of the fixed magnet 31, the fixed magnet 31 is not attracted to the watering magnet 34, the watering magnet spring 32 is in a relaxed state, the watering rope 42 and the watering magnet rope 33 are in a relaxed state, the water stop block spring 14 is in a relaxed state, the upper end surface of the water stop block 16 is tightly attached to the upper end wall of the watering cavity 15, the reel rope 41 is in a relaxed state, the stirring tension spring 37 is in a relaxed state, the stirring tension magnetic block 40 is located in the stirring belt 28, the stirring belt 28 is in a tensioned state, the rotating tension spring 71 is in a relaxed state, the rotating tension magnetic block 75 is separated from the rotating belt 65, the rotating belt 65 is in a relaxed state, the rack block spring 44 is in a relaxed, the pulling magnet spring 49 is in a relaxed state, the attracting magnet block 46 is in a position close to the stirring shaft 21, the centrifugal spring 81 is in a relaxed state, the centrifugal swinging block 82 is in a position close to the stirring shaft 21, the pulling magnet spring 49 is in a relaxed state, and the pulling magnet 50 is close to the right end wall of the pulling magnet cavity 83.

Sequence of mechanical actions of the whole device:

when the water storage device starts to work, flour is added into the inner barrel cavity 77, under the action of the gravity of the flour, the outer barrel 12 moves downwards against the pushing force of the outer barrel spring 25, at the moment, the fixed magnet 31 enters the fixed magnet cavity 30 and just corresponds to the water adding magnet 34, the suction force between the fixed magnet 31 and the water adding magnet 34 overcomes the pulling force of the water adding magnet spring 32 to move leftwards, the water adding pull rope 42 is tensioned, the water adding magnet pull rope 33 is just tightened, the water stopping block 16 is pulled to move downwards against the pushing force of the water stopping block spring 14, and therefore water in the water storage cavity 13 flows into the inner barrel cavity 77 through the water flowing cavity 15, the sealing ring 39 and the inner barrel through cavity 73;

at the moment, the motor 35 is started, the motor 35 drives the power shaft 29 to rotate, the power shaft 29 drives the power shaft belt wheel 27 and the power shaft bevel gear 24 to rotate, the power shaft belt wheel 27 drives the stirring shaft belt wheel 18 to rotate through the stirring belt 28, the stirring shaft belt wheel 18 drives the stirring block 20 to rotate through the stirring shaft 21, stirring of flour in the inner barrel cavity 77 is achieved, the power shaft bevel gear 24 drives the transmission shaft 67 to rotate through the transmission shaft bevel gear 70, the transmission shaft 67 drives the transmission shaft belt wheel 68 to rotate, and the transmission shaft belt wheel 65 is loosened because the rotating tightening magnetic block 75 and the rotating belt 65 are in a separation state at the moment, and the transmission shaft belt wheel 68;

the stirring shaft 21 drives the stirring block 20 to rotate and also drives the centrifugal block 79 to rotate, the centrifugal block 79 rotates to enable the centrifugal swinging block 82 to overcome the pulling force of the centrifugal spring 81 to move outwards under the action of centrifugal force, so that the centrifugal swinging block 82 pushes the attraction magnet block 46 to move downwards under the action of the pushing force of the attraction magnet spring 48, when the attraction magnet block 46 moves downwards to the attraction magnet 51 to correspond to the pulling magnet 50, the attraction force between the attraction magnet 51 and the pulling magnet 50 overcomes the pulling force of the pulling magnet spring 49 to move leftwards, so that the water adding magnet 34 is driven by the water adding magnet pull rope 33 to overcome the attraction force between the water adding magnet 34 and the fixed magnet 31 to move rightwards to return to the initial state, so that the water stopping block 16 is closed again, and water;

meanwhile, the centrifugal swinging block 82 moves outwards and can also drive the rack block 45 to move upwards against the thrust of the rack block spring 44, the rack block 45 moves upwards to drive the switch shaft gear 55 to rotate forwards through the rack 47, so that the switch shaft 58 is driven to rotate through the switch one-way bearing 54, the switch rod 57 is driven to rotate, when the rack 47 moves to the upper side of the switch shaft gear 55 and is disengaged with the switch shaft gear 55, the switch rod 57 rotates right ninety degrees, meanwhile, the switch shaft gear 55 rotates and can also drive the reel shaft gear 53 to rotate, and the reel shaft 52 does not rotate due to the action of the reel one-way bearing 59;

when the flour is stirred to be hardened, the resistance of the flour is increased to reduce the rotating speed of the stirring block 20, so that the rack block 45 moves downwards under the thrust of the rack block spring 44 to drive the switch shaft gear 55 to rotate reversely, the switch shaft 58 does not rotate under the action of the switch one-way bearing 54, the switch shaft gear 55 also drives the reel shaft gear 53 to rotate, the reel shaft 52 is driven by the reel one-way bearing 59 to rotate against the elastic force of the torsion spring 60, the reel shaft 52 drives the reel 61 to rotate, the reel pull rope 41 pulls the water stop block 16 downwards against the thrust of the water stop block spring 14 to realize water adding, when the rack 47 moves downwards to be separated from the switch shaft gear 55, the centrifugal block 79 still keeps a certain rotating speed, the magnet 51 is attracted to be still opposite to the pull magnet 50, and the reel shaft 52 rotates reversely under the action of the torsion spring 60, so that the pull rope reel 41 is loosened, the water stop block 16 is closed again under the thrust action of the water stop block spring 14, water adding is stopped, when the flour after water adding is stirred again to be soft, the resistance of the flour is reduced, the rotating speed of the stirring shaft 21 is increased, so that the rack 47 is driven to move upwards, the rack block 45 is driven to move upwards, the switch rod 57 rotates ninety degrees again, the process is repeated, and the effects of detecting hardening of the flour and automatically adding water are achieved;

when the switch lever 57 rotates for one circle, the switch lever just contacts the inductive switch 56 again, the inductive switch 56 sends a signal to start the stirring electromagnet 38 and the rotating electromagnet 72, the stirring electromagnet 38 is started, a suction force is generated between the stirring electromagnet 38 and the stirring tightening magnet 40, the stirring electromagnet 38 attracts the stirring tightening magnet 40 to move rightwards against the pushing force of the stirring tightening spring 37, the stirring tightening magnet 40 is separated from the stirring belt 28, the stirring belt 28 is loosened, the stirring shaft 21 stops rotating, meanwhile, the rotating electromagnet 72 is started, a repulsion force is generated between the rotating electromagnet 72 and the rotating tightening magnet 75, the rotating tightening magnet 75 is pushed to move leftwards against the pulling force of the rotating tightening spring 71, the rotating tightening magnet 75 enters the rotating belt 65, the rotating belt 65 is tightened, the transmission shaft belt wheel 68 drives the worm shaft belt wheel 66 to rotate through the rotating belt 65, the rotating belt 65 drives the worm 76 to rotate, the worm 76 is meshed with the worm wheel 63 to drive the worm wheel 63 to rotate, the worm wheel 63 drives the inner cylinder 19 to rotate through the inner cylinder rotating rod 84, and the inner cylinder 19 is turned by ninety degrees, so that dough in the inner cylinder cavity 77 falls into the inner cylinder rotating cavity 22 and rolls out to the outside through the inner cylinder rotating cavity 22.

The invention has the beneficial effects that: stir the formation dough through band pulley and puddler to flour to the hardness of dough is judged to the rotational speed through the (mixing) shaft at the stirring in-process, the on-off control through rack and line wheel control flow water cavity adds water, the realization is added water to the automation of dough, the dough that obtains the hardness is suitable, the efficiency of kneading the dough has been improved, the quality of dough has been promoted, the manpower has been reduced, and realize the upset of churn through the turbine worm, conveniently take out the dough.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (5)

1. The utility model provides an automatic watered automatic dough kneading device that can overturn through dough hardness, includes the box, its characterized in that: an outer barrel cavity with an upward opening and a backward opening is arranged in the box body, an outer barrel is connected in the outer barrel cavity in a sliding fit manner, a fixed magnet cavity with a downward opening is arranged in the outer barrel, a water adding magnet cavity is communicated and arranged on the right side of the fixed magnet cavity, an inner barrel rotating cavity with an upward opening and a backward opening is arranged in the outer barrel, a water flowing cavity is communicated and arranged on the right side of the inner barrel rotating cavity, a water storage cavity with an upward opening is communicated and arranged on the right side of the water flowing cavity, a water stopping cavity is communicated and arranged on the lower side of the water flowing cavity, an inner barrel is connected in the inner barrel rotating cavity in a rotating fit manner, an inner barrel cavity with an upward opening is arranged in the inner barrel, an inner barrel through cavity which is communicated inside and outside is arranged on the right end wall of the inner barrel, a sealing ring corresponding to the water, the front side of the turbine cavity is provided with a rotating belt wheel cavity, the rear side of the rotating belt wheel cavity is provided with a transmission bevel gear cavity positioned on the lower side of the turbine cavity, the left side of the turbine cavity is provided with a water adding control cavity, the right end wall of the water adding control cavity is connected with a stirring shaft which extends through the turbine cavity, the inner cylinder rotating cavity and the inner cylinder cavity to the stirring belt wheel cavity rightwards and extends to the water adding control cavity leftwards, the left end of the stirring shaft is fixedly connected with a centrifugal block, the centrifugal block is internally provided with eight centrifugal cavities which are circumferentially distributed by taking the stirring shaft as the center and are provided with outward openings, the centrifugal cavities are connected with a centrifugal throwing block in a sliding fit manner, the centrifugal throwing block is close to the side end face of the stirring shaft and is close to a centrifugal spring fixedly connected between the side end walls of the stirring shaft, and the water adding control cavity is internally connected with, the rack piece up end with fixedly connected with rack piece spring between water control chamber upper end wall, rack piece right-hand member face fixedly connected with rack, water control intracavity sliding fit is connected with and is located the attraction magnet piece of centrifugal piece downside, attract magnet piece down the terminal surface with water control chamber lower end wall fixedly connected with attracts the magnet spring between, attraction magnet piece right-hand member face fixedly connected with attracts magnet, water control chamber right side intercommunication is equipped with and is located the pulling magnet chamber of centrifugal piece downside, water control chamber right side intercommunication is equipped with and is located the line wheel chamber of centrifugal piece upside.

2. The reversible automatic kneading apparatus of claim 1, wherein the water is automatically added by the hardness of the dough, and the apparatus further comprises: the pulling magnet cavity is connected with a pulling magnet in a sliding fit manner, a pulling magnet spring is fixedly connected between the right end face of the pulling magnet and the right end wall of the pulling magnet cavity, a switch shaft is connected between the front side end wall and the rear side end wall of the wire wheel cavity in a rotating fit manner, a wire wheel shaft extending forwards into the wire wheel cavity is connected in the rotating fit manner in the rear side end wall of the wire wheel cavity in a rotating fit manner, a switch one-way bearing is fixedly connected onto the switch shaft, a switch shaft gear is connected onto the switch one-way bearing in a rotating fit manner, a switch rod positioned in the front side of the switch one-way bearing is also fixedly connected onto the switch shaft, an induction switch capable of being abutted against the switch rod is fixedly connected onto the lower end wall of the wire wheel cavity, a torsion spring is fixedly connected between the tail end of the front side of the wire wheel shaft and the front side end wall of the wire, and the reel one-way bearing is connected with a reel shaft gear meshed with the switch shaft gear in a rotating fit manner.

3. The reversible automatic kneading apparatus of claim 1, wherein the water is automatically added by the hardness of the dough, and the apparatus further comprises: a motor is fixedly connected in the right end wall of the stirring belt wheel cavity, the left end surface of the motor is fixedly connected with a power shaft which extends leftwards and penetrates through the stirring belt wheel cavity to the transmission bevel gear cavity, the power shaft is fixedly connected with a power shaft belt wheel positioned in the stirring belt wheel cavity, the tail end of the right side of the stirring shaft is fixedly connected with a stirring shaft belt wheel, the stirring belt wheel and the power shaft belt wheel are in power fit connection with a stirring belt positioned in the stirring belt wheel cavity, the right side of the stirring belt wheel cavity is communicated with a stirring tightening cavity, a stirring tightening magnetic block capable of tightening the stirring belt is connected in the stirring tightening cavity in a sliding fit manner, the stirring device is characterized in that a stirring electromagnet is fixedly connected to the right end wall of the stirring tightening cavity, a stirring tightening spring is fixedly connected between the right end face of the stirring tightening magnetic block and the right end wall of the stirring tightening cavity, and a plurality of stirring blocks located in the inner cylinder cavity are fixedly connected to the stirring shaft.

4. The reversible automatic kneading apparatus of claim 3, wherein the water is automatically added by the hardness of the dough, and the apparatus further comprises: the tail end of the left side of the power shaft is fixedly connected with a power shaft bevel gear, the front end wall of the transmission bevel gear cavity is connected with a transmission shaft which extends forwards into the rotating belt wheel cavity and extends backwards into the transmission bevel gear cavity in a rotating and matching manner, the tail end of the rear side of the transmission shaft is fixedly connected with a transmission shaft bevel gear meshed with the power shaft bevel gear, the tail end of the front side of the transmission shaft is fixedly connected with a transmission shaft belt wheel, the front end wall of the turbine cavity is connected with a worm which extends forwards into the rotating belt wheel cavity and extends backwards into the turbine cavity in a rotating and matching manner, the tail end of the front side of the worm is fixedly connected with a worm shaft belt wheel, the worm shaft belt wheel and the transmission shaft belt wheel are connected with a rotating belt positioned in the rotating belt wheel cavity in a power matching manner, and, the inner cylinder rotating rod is connected with a turbine cavity right end wall, extends leftwards to an inner cylinder rotating rod fixedly connected with a turbine right end face and extends rightwards to an inner cylinder left end face fixedly connected with the inner cylinder rotating rod, the inner cylinder rotating rod is located on the outer side of the stirring shaft and is connected with the stirring shaft in a rotating and matching mode, the rear side of the rotating belt cavity is provided with a rotating tightening cavity located on the lower side of the turbine cavity and located on the upper side of the transmission bevel gear cavity, a rotating tightening cavity is connected with a rotating tightening magnetic block capable of tightening the rotating belt in a sliding matching mode, the rear end wall of the rotating tightening cavity is fixedly connected with a rotating electromagnet, and the rear end face of the rotating tightening magnetic block and the rotating tightening spring are fixedly connected between the.

5. The reversible automatic kneading apparatus of claim 1, wherein the water is automatically added by the hardness of the dough, and the apparatus further comprises: terminal surface under the urceolus with fixedly connected with urceolus spring between urceolus chamber lower extreme wall, fixedly connected with is located on the urceolus chamber lower extreme wall the fixed magnet of fixed magnet chamber downside, it is connected with water adding magnet to add water magnet intracavity sliding fit, water adding magnet right-hand member face with fixedly connected with adds water magnet spring between water adding magnet chamber right-hand member wall, water adding magnet with fixedly connected with adds water magnet stay cord between pulling magnet, it can seal to be connected with in the water stopping intracavity sliding fit the stagnant water piece in flowing water chamber, terminal surface under the stagnant water piece with fixedly connected with stagnant water piece spring between stagnant water chamber lower extreme wall, stagnant water piece with it adds water stay cord to add fixedly connected with between water magnet, stagnant water piece with line wheel fixedly connected with line stay cord between the line.

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