CN117946830A

CN117946830A - Distiller's yeast production facility for system wine

Info

Publication number: CN117946830A
Application number: CN202410301950.1A
Authority: CN
Inventors: 王京平
Original assignee: Hebei Guyuan Brewing Co ltd
Current assignee: Hebei Guyuan Brewing Co ltd
Priority date: 2024-03-17
Filing date: 2024-03-17
Publication date: 2024-04-30

Abstract

A distiller's yeast production equipment for making wine relates to the technical field of brewing production, comprising: the device comprises a feeding mechanism, a stirring and manufacturing mechanism, a uniform placing mechanism and a transfer mechanism; the equipment can quantitatively put the main raw materials and the auxiliary raw materials for making the distiller's yeast, and simultaneously can add the put quantity in equal proportion, so that the resources are saved and the working efficiency is improved while the put quantity is ensured; the equipment can uniformly stir and mix the raw materials to prepare the wine yeast blocks with the same size, so that the condition that the sizes of the wine yeast blocks are different in manual production is avoided, and the fermentation effect of the wine yeast blocks is influenced; the device can automatically and uniformly put the cut wine yeast blocks, so that the fermentation efficiency is improved while the manpower is saved.

Description

Distiller's yeast production facility for system wine

Technical Field

The invention relates to the technical field of brewing production, in particular to distiller's yeast production equipment for making wine.

Background

The distiller's yeast is an ideal raw material for brewing wine since ancient times, and is actually developed from mildewed grains, so that the distiller's yeast has strong fermentation capability, and people improve the distiller's yeast, select different raw material manufacturing methods, and is suitable for brewing different wines. The distiller's yeast is generally prepared by pulverizing wheat and sorghum, mixing, adding water, stirring, compressing into block-shaped blank, stacking, culturing, and fermenting to obtain dry solid product. The traditional starter propagation process is generally made by manually treading starter, the labor intensity is very high, the efficiency is extremely low, and the quality of the molded distiller's yeast cannot achieve the required effect. In the process of pressing the distiller's yeast into blocks, the molded yeast blocks have uneven internal compactness and uneven appearance due to the difference of experience and force of workers.

The Chinese patent with the publication number of CN 111560300A discloses a distiller's yeast briquetting machine, which comprises a frame, be provided with the conveying mechanism who is used for carrying distiller's yeast bulk cargo in the frame, be provided with a plurality of evenly distributed on the conveying mechanism and be used for holding the rectangular form frame of distiller's yeast bulk cargo, rectangular form frame with conveying mechanism swing joint, the frame top is provided with the bottom plate, the bottom plate with rectangular form frame forms half seal structure, the frame top inboard is provided with spacing platform, spacing platform highly is greater than the height of rectangular form frame, conveying mechanism pan feeding end top is provided with the feed inlet, the feed inlet left side is provided with the strickle mechanism that is used for striving off the interior distiller's yeast bulk cargo of rectangular form frame, strickle mechanism left side is provided with the compression roller that is used for compacting distiller's yeast bulk cargo, and this equipment only accomplishes the briquetting to distiller's yeast, does not realize other steps of preparation distiller's yeast, still has the shortcoming that uses the limitation.

Therefore, a distiller's yeast production device for making wine is needed, the device can quantitatively put in main raw materials and auxiliary raw materials for making distiller's yeast, and meanwhile, the put amount can be added in equal proportion, so that the put amount is ensured, resources are saved, and the working efficiency is improved; the equipment can uniformly stir and mix the raw materials to prepare the wine yeast blocks with the same size, so that the condition that the sizes of the wine yeast blocks are different in manual production is avoided, and the fermentation effect of the wine yeast blocks is influenced; the device can automatically and uniformly put the cut wine yeast blocks, so that the fermentation efficiency is improved while the manpower is saved.

Disclosure of Invention

Aiming at the technical problems, the invention provides a distiller's yeast production device for making wine, which can quantitatively put main raw materials and auxiliary raw materials for making distiller's yeast, and simultaneously can add the put amounts in equal proportion, so that the put amounts are ensured, resources are saved, and the working efficiency is improved; the equipment can uniformly stir and mix the raw materials to prepare the wine yeast blocks with the same size, so that the condition that the sizes of the wine yeast blocks are different in manual production is avoided, and the fermentation effect of the wine yeast blocks is influenced; the device can automatically and uniformly put the cut wine yeast blocks, so that the fermentation efficiency is improved while the manpower is saved.

The technical scheme adopted by the invention is as follows: a distiller's yeast production device for making wine, comprising: the device comprises a feeding mechanism, a stirring and manufacturing mechanism, a uniform placing mechanism and a transfer mechanism; the upper support frame of the feeding mechanism is fixedly arranged on the ground, and the feeding mechanism is used for quantitatively feeding raw materials for making distiller's yeast; the stirring box of the stirring and manufacturing mechanism is fixedly arranged at the inner side of the upper supporting frame through a rod, and the stirring and manufacturing mechanism is used for mixing and manufacturing distiller's yeast raw materials; the support frame I of the uniform placing mechanism is slidably arranged on the underframe, and the uniform placing mechanism is used for uniformly placing the wine yeast blocks; the underframe of the transfer mechanism is fixedly arranged on the ground, and the transfer mechanism is used for transferring the uniform placing mechanism;

The feeding mechanism also comprises: the device comprises a supporting disc, a large disc, an arc-shaped plate, a small disc, a gear I, a gear II, a lower supporting frame, a material taking device I, a material taking device II, a material storage box and a motor III; the four storage boxes are respectively and fixedly arranged on the top plate of the upper supporting frame; the supporting disc is fixedly arranged on the lower end face of the top plate of the upper supporting frame; the upper end ring frame of the large disc is rotatably arranged on the lower end face of the supporting disc, a section of gear teeth is arranged on the periphery of the large disc, the length of the section of gear teeth is one fourth of the circumference of the large disc, three grooves at the lower end of the large disc are formed in the lower end of the large disc, round holes are formed in the grooves, and a motor is fixedly arranged on the upper end face of the large disc; the number of the arc-shaped plates is three, and the three arc-shaped plates are respectively and slidably arranged in three grooves on the large disc; the small disc is rotatably arranged in a round hole in the middle of the large disc, the shaft of the small disc is fixedly connected with the shaft of a motor fixedly arranged on the upper end face of the large disc, and the upper end of the small disc is fixedly provided with an arc-shaped bulge; the four gears I are respectively rotatably arranged in four round holes on the supporting disc, the four gears I are intermittently meshed with gear teeth on the periphery of the large disc, and the four gears I are intermittently meshed with the gear teeth on the periphery of the three arc plates after the arc plates move upwards; the lower support frame is fixedly arranged at the lower end of the upper support frame, four discs are fixedly arranged on the lower support frame, and each disc is provided with a discharging round hole; the material taking device I is rotatably arranged on a disc on the lower supporting frame, and the material taking device I is rotatably arranged on the lower end face of a storage box for placing the main raw materials; three material taking devices II are respectively and rotatably arranged on the other three discs on the lower support frame, and are respectively and rotatably arranged on the lower end surfaces of the storage boxes for placing auxiliary materials, and two material taking cylinders are arranged on the material taking devices II; the four gears II are respectively and rotatably arranged on upper end shafts of the material taking device I and the three material taking devices II, and the shafts of the four gears II are respectively and correspondingly connected with the shafts of the four gears I through synchronous belts; the motor III is fixedly arranged on the side surface of the supporting disc, a motor shaft of the motor III is fixedly connected with a gear, the gear is meshed with gear teeth on the large disc intermittently, and the gear is meshed with gear teeth on the periphery of the three arc plates intermittently after the arc plates move upwards.

Preferably, the arc plate on fixed mounting have the round bar, the round bar corresponds the round hole in passing big disc recess, the periphery of round bar installs the spring, the upper end and the lower terminal surface fixed connection of big disc ring frame of spring, the other end and the extension board on the arc plate round bar of spring are connected, the periphery of arc plate is equipped with the teeth of a cogwheel, the lower extreme fixed mounting of arc plate has semi-circular arch.

Preferably, the material taking device I is provided with four material taking cylinders.

Preferably, the stirring and manufacturing mechanism comprises: the stirring box, the hollow column, the stirring rod, the bevel gear I, the motor I, the threaded rod and the long rod; the stirring box is fixedly arranged on the inner side of the upper supporting frame through a rod, a top cover is fixedly arranged at the upper end of the stirring box, a round hole is formed in the middle of the top cover, four feed inlets and a water inlet are formed in the top cover, and the four feed inlets in the top cover of the stirring box are connected with the discharge round holes in the four discs on the lower supporting frame through pipes; the hollow column is rotatably arranged in a round hole in the middle of the top cover of the stirring box; the two stirring rods are fixedly arranged on two sides of the hollow column and are positioned in the inner cavity of the stirring box; the bevel gear I is fixedly arranged on the hollow column; the motor I is fixedly arranged on the upper end surface of the top cover of the stirring box, a bevel gear is fixedly arranged on a motor shaft of the motor I, and the bevel gear is meshed with the bevel gear I; the threaded rod penetrates through the middle hole of the hollow column and is rotatably arranged in a round hole of a shelf on the stirring box; the long rod is rotatably arranged in a round hole of the side plate of the stirring box, and is connected with the threaded rod through a synchronous belt.

Preferably, the stirring and making mechanism further comprises: the device comprises a supporting plate, a cutter, a limiting rod I, a gear set I, a motor II and a storage barrel I; the support plate is fixedly arranged at the lower end of the stirring box through a rod, a round hole is formed in the support plate and fixedly connected with a discharge hole at the lower end of the stirring box, and rectangular slotted holes are formed in two sides of the round hole in the support plate; the two cutters are respectively arranged in two rectangular slotted holes on the supporting plate in a sliding way, bent rods are arranged on the side surfaces of the two cutters, and small rods are arranged on the bent rods; the two limiting rods I are arranged, the small rods on the inner ends of the two limiting rods I are respectively rotatably arranged in the two round holes on the lower end face of the supporting plate, slotted holes are formed in the outer ends of the two limiting rods I, the small rods on the two cutter bent rods respectively slide on the slotted holes in the inner ends of the two limiting rods I, and slotted holes are formed in the middle positions of the two limiting rods I; shafts of two gears in the gear set I are respectively rotatably arranged in two round holes in the supporting plate, deflection shafts are arranged on the two gears in the gear set I and slide in slotted holes in the middle positions of the two cutters respectively; the motor II is fixedly arranged on the upper end surface of the supporting plate, a motor shaft of the motor II is fixedly connected with the shaft of one gear in the gear set I, and the shaft of the motor II is connected with the long rod through a synchronous belt; the storage barrel I is fixedly arranged on the ground, and a water outlet of the storage barrel I is connected with a water inlet on the top cover of the stirring box through a water pipe.

Preferably, the uniform placing mechanism comprises: the device comprises a supporting frame I, a circular plate, a limiting rod II, a vertical rod, a chuck and a tray; the support frame I is slidably arranged on the underframe, and a motor is fixedly arranged on the support frame I; the circular plate is fixedly arranged on the support frame I, and a circular hole is formed in the middle of the circular plate; the inner end shaft of the limiting rod II is rotatably arranged in a round hole in the middle of the round plate, and is fixedly connected with the shaft of a motor fixedly arranged on the support frame I; the lower end of the vertical rod slides in the turbine-shaped slotted hole on the circular plate, the vertical rod slides in the groove on the limiting rod II, the clamping disc at the upper end of the vertical rod is fixedly connected, and the inner wall of the clamping disc is provided with a groove edge; the tray is slidably mounted on the chuck, and the convex edges on the outer wall of the tray are matched with the groove edges on the inner wall of the chuck.

Preferably, the circular plate is provided with a turbine-shaped slot.

Preferably, the transfer mechanism further comprises: a screw rod sliding block group and a storage barrel II; the screw rod sliding block set comprises a frame, a screw rod, a motor and a sliding block, wherein the frame is fixedly arranged on the underframe, the screw rod is rotatably arranged in the frame, the motor is fixedly arranged on the frame, a motor shaft of the motor is fixedly connected with one end of the screw rod, the sliding block is slidably arranged in the frame, a threaded hole on the sliding block is in threaded fit with the screw rod, and the inner end of the sliding block in the screw rod sliding block set is fixedly connected with the side face of the support frame I; the storage barrel II is fixedly arranged on the ground through a bracket, and an automatic door is arranged at the outlet of the lower end of the storage barrel II.

The invention has the beneficial effects that:

1. According to the invention, the motor III is used for starting to drive the gear on the shaft to rotate, the gear drives the large disc to rotate, when the gear teeth on the periphery of the three arc plates and the gear teeth on the periphery of the large disc are combined into a complete circle, three times of feeding of the main raw materials and the auxiliary raw materials is realized, the equal ratio feeding is realized, the resources and the manpower are saved, and the working efficiency is improved.

2. According to the invention, the bevel gear I is driven to rotate by the motor I, so that the hollow column is driven to rotate, at the moment, the outer ends of the two limiting rods I drive the two cutters to be combined or opened at the outlet of the lower end of the stirring box, and when the two cutters are combined, the molded distiller's yeast extruded by the stirring box can be cut into small blocks, so that the uniform size of the distiller's yeast blocks is ensured, unified fermentation is facilitated, and the distiller's yeast fermentation efficiency is improved.

3. According to the invention, the chuck is driven to move outwards by the vertical rod to make a turbine-shaped track, the tray is driven to move outwards by the vertical rod to make the turbine-shaped track, and the tray is driven to move outwards by the vertical rod to make the turbine-shaped track, so that the cut distiller's yeast blocks are uniformly placed on the tray from inside to outside, and distiller's yeast fermentation is facilitated.

Drawings

FIG. 1 is a schematic view of a first angle structure of an integral part of the present invention.

FIG. 2 is a schematic view of a second angle structure of an integral part of the present invention.

Fig. 3 is a schematic view of a feeding mechanism according to the present invention.

Fig. 4 is a schematic view of a part of the structure of the feeding mechanism of the present invention.

Fig. 5 is a schematic view of the internal structure of the feeding mechanism of the present invention.

Fig. 6 is a schematic view of a first angle structure of the stirring mechanism according to the present invention.

Fig. 7 is a schematic view of a second angle structure of the stirring mechanism of the present invention.

Fig. 8 is a schematic view of the internal structure of the stirring mechanism of the present invention.

FIG. 9 is a schematic view of a uniform placement mechanism according to the present invention.

FIG. 10 is a partial schematic view of the uniform placement mechanism of the present invention.

Fig. 11 is a schematic view of a transfer mechanism according to the present invention.

Reference numeral 1, a feeding mechanism; 2. a stirring and manufacturing mechanism; 3. a uniform placing mechanism; 4. a transfer mechanism; 101. an upper support frame; 102. a support plate; 103. a large disc; 104. an arc-shaped plate; 105. a small disc; 106. a gear I; 107. a gear II; 108. a lower support frame; 109. a material taking device I; 110. a material taking device II; 111. a storage box; 112. a motor III; 201. a stirring box; 202. a hollow column; 203. a stirring rod; 204. bevel gears I; 205. a motor I; 206. a threaded rod; 207. a long rod; 208. a support plate; 209. a cutter; 210. a limiting rod I; 211. a gear set I; 212. a motor II; 213. a storage barrel I; 301. a supporting frame I; 302. a circular plate; 303. a limiting rod II; 304. a vertical rod; 305. a chuck; 306. a tray; 401. a chassis; 402. a screw slider group; 403. and a storage barrel II.

Detailed Description

The technical scheme of the invention is further specifically described below through examples and with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The invention may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit or scope of the invention, which is therefore not limited to the specific embodiments disclosed below.

It should be noted that, in this document, some connection modes, such as "fixed connection and fixed installation", refer to, but not limited to, fixing two parts between each other, such as welding, screw-nut fixing, sticking, riveting, and interference fit.

1-11, A distiller's yeast production device for making wine, comprising: a feeding mechanism 1, a stirring and manufacturing mechanism 2, a uniform placing mechanism 3 and a transfer mechanism 4; the upper support frame 101 of the feeding mechanism 1 is fixedly arranged on the ground, and the feeding mechanism 1 is used for quantitatively feeding raw materials for making distiller's yeast; the stirring box 201 of the stirring and making mechanism 2 is fixedly arranged on the inner side of the upper supporting frame 101 through a rod, and the stirring and making mechanism 2 is used for mixing and making distiller's yeast raw materials; the support frame I301 of the uniform placing mechanism 3 is slidably arranged on the underframe 401, and the uniform placing mechanism 3 is used for uniformly placing the wine yeast blocks; the underframe 401 of the transfer mechanism 4 is fixedly arranged on the ground, and the transfer mechanism 4 is used for transferring the uniform placing mechanism 3;

as shown in fig. 3 to 5, the feeding mechanism 1 further includes: support disc 102, large disc 103, arc plate 104, small disc 105, gear I106, gear II 107, lower support 108, reclaimer I109, reclaimer II 110, storage box 111, motor III 112; four storage boxes 111 are arranged, the four storage boxes 111 are respectively and fixedly arranged on the top plate of the upper supporting frame 101, one storage box 111 is internally provided with main raw materials for making distiller's yeast, and the other three storage boxes 111 are internally provided with auxiliary raw materials for making distiller's yeast; the support plate 102 is fixedly arranged on the lower end surface of the top plate of the upper support frame 101; the upper end ring frame of the large disc 103 is rotatably arranged on the lower end face of the supporting disc 102, a section of gear teeth is arranged on the periphery of the large disc 103, the length of the section of gear teeth is one fourth of the circumference of the large disc 103, three grooves at the lower end of the large disc 103 are formed, round holes are formed in the grooves, and a motor is fixedly arranged on the upper end face of the large disc 103; three arc plates 104 are arranged, and the three arc plates 104 are respectively and slidably arranged in three grooves on the large disc 103; the small disc 105 is rotatably arranged in a round hole in the middle of the large disc 103, the shaft of the small disc 105 is fixedly connected with the shaft of a motor fixedly arranged on the upper end face of the large disc 103, the upper end of the small disc 105 is fixedly provided with an arc-shaped bulge, the arc-shaped bulge can be contacted with a semicircular bulge at the lower end of the arc-shaped plate 104, and the arc-shaped plate 104 is pushed to move upwards, so that gear teeth on the periphery of the arc-shaped plate 104 and gear teeth on the periphery of the large disc 103 are positioned on the same horizontal plane; specifically, the motor on the upper end surface of the large disc 103 is fixedly connected to drive the small disc 105 to rotate, when the arc-shaped bulge on the small disc 105 rotates to be in contact with the semicircular bulge at the lower end of one arc-shaped plate 104, the arc-shaped plate 104 moves upwards to the position that the gear teeth on the periphery of the arc-shaped plate 104 are positioned on the same horizontal plane with the gear teeth on the periphery of the large disc 103 under the pushing of the small disc 105, and when the small disc 105 still rotates, the three arc-shaped plates 104 are sequentially pushed upwards to enable the gear teeth on the periphery of the three arc-shaped plates 104 and the gear teeth on the periphery of the large disc 103 to be combined into a complete circle; the four gears I106 are arranged, shafts of the four gears I106 are respectively rotatably arranged in four round holes on the supporting disc 102, the four gears I106 are intermittently meshed with gear teeth on the periphery of the large disc 103, and the four gears I106 are intermittently meshed with the gear teeth on the periphery of the three arc plates 104 after the arc plates 104 move upwards; the lower support frame 108 is fixedly arranged at the lower end of the upper support frame 101, four discs are fixedly arranged on the lower support frame 108, and each disc is provided with a discharge round hole; the material taking device I109 is rotatably arranged on a disc on the lower supporting frame 108, and the material taking device I109 is rotatably arranged on the lower end face of a storage box 111 for placing main raw materials; three material taking devices II 110 are arranged, the three material taking devices II 110 are respectively and rotatably arranged on the other three discs on the lower support frame 108, the three material taking devices II 110 are respectively and rotatably arranged on the lower end surfaces of the other material storage boxes 111 for containing auxiliary materials, two material taking cylinders are arranged on the material taking devices II 110, and when the material taking devices II 110 rotate, the material taking cylinders can take auxiliary materials in the corresponding material storage boxes 111 and then throw the auxiliary materials downwards along the material outlet round holes of the corresponding lower support frame 108; the four gears II 107 are respectively rotatably arranged on upper end shafts of the material taking device I109 and the three material taking devices II 110, and the shafts of the four gears II 107 are respectively correspondingly connected with the shafts of the four gears I106 through synchronous belts; the motor III 112 is fixedly arranged on the side surface of the supporting disc 102, a motor shaft of the motor III is fixedly connected with a gear, the gear is intermittently meshed with gear teeth on the large disc 103, and the gear is intermittently meshed with the gear teeth on the periphery of the three arc plates 104 after the arc plates 104 move upwards; specifically, when the raw materials are put in, firstly, the motor III 112 is started to drive the gears on the shafts thereof to rotate, the gears drive the large circular disc 103 to rotate, when the gear teeth on the large circular disc 103 move to be sequentially meshed with the four gears I106, the large circular disc 103 drives the corresponding gears I106 to rotate for one circle, the gears I106 drive the gears II 107 connected with the gears I to rotate, the gears II 107 drive the corresponding reclaimer I109 or the reclaimer II 110 to rotate, when the reclaimer I109 rotates for one circle, the four reclaiming drums on the reclaimer I109 pick up the main raw materials in the corresponding storage boxes 111 and then put the main raw materials downwards along the discharging round holes of the corresponding lower support frames 108, and when the reclaimer II 110 rotates for one circle, the reclaiming drums on the reclaimer II 110 can pick up the auxiliary raw materials in the corresponding storage boxes 111 and then put the auxiliary raw materials downwards along the discharging round holes of the corresponding lower support frames 108; thus realizing quantitative feeding of the main raw materials and the auxiliary raw materials; when a large amount of raw materials with equal proportion are required to be put in, a motor on the upper end surface of the large disc 103 is fixedly connected to drive the small disc 105 to rotate, when an arc-shaped bulge on the small disc 105 rotates to be in contact with a semicircular bulge at the lower end of one arc-shaped plate 104, the arc-shaped plate 104 moves upwards under the pushing of the small disc 105 until the peripheral gear teeth of the arc-shaped plate 104 are positioned on the same horizontal plane with the peripheral gear teeth of the large disc 103, so that when the motor III 112 drives the large disc 103 to rotate, the gear teeth on the large disc 103 and the gear teeth on the arc-shaped plate 104 act together to drive the four gears I106 to rotate for two weeks, and double putting of main raw materials and auxiliary raw materials is realized; when the small disc 105 still rotates, the three arc plates 104 are pushed upwards in sequence, so that when the peripheral gear teeth of the three arc plates 104 and the peripheral gear teeth of the large disc 103 are combined into a complete circle, three times of feeding of the main raw materials and the auxiliary raw materials is realized, the equal ratio feeding is realized, the resources and the manpower are saved, and the working efficiency is improved.

As shown in fig. 5, a circular rod is fixedly installed on the arc plate 104, the circular rod correspondingly penetrates through a circular hole in the groove of the large disc 103, a spring is installed at the periphery of the circular rod, the upper end of the spring is fixedly connected with the lower end face of the circular frame of the large disc 103, the other end of the spring is connected with a support plate on the circular rod of the arc plate 104, gear teeth are arranged at the periphery of the arc plate 104, the gear teeth at the periphery of the three arc plates 104 and the gear teeth at the periphery of the large disc 103 can be combined into a whole circle, and semicircular protrusions are fixedly installed at the lower end of the arc plate 104.

As shown in fig. 4, four material taking cylinders are arranged on the material taking device i 109, and when the material taking device i 109 rotates, the material taking cylinders on the material taking device i 109 can take the main raw materials in the corresponding material storage boxes 111 and then throw the main raw materials downwards along the material outlet round holes of the corresponding lower support frames 108.

As shown in fig. 6 to 8, the stirring mechanism 2 includes: a stirring box 201, a hollow column 202, a stirring rod 203, a bevel gear I204, a motor I205, a threaded rod 206 and a long rod 207; the stirring box 201 is fixedly arranged on the inner side of the upper supporting frame 101 through a rod, a top cover is fixedly arranged on the upper end of the stirring box 201, a round hole is formed in the middle of the top cover, four feed inlets and a water inlet are formed in the top cover, and the four feed inlets on the top cover of the stirring box 201 are connected with the discharge round holes on the four discs on the lower supporting frame 108 through pipes; the hollow column 202 is rotatably arranged in a round hole in the middle position of the top cover of the stirring box 201; two stirring rods 203 are arranged, the two stirring rods 203 are fixedly arranged on two sides of the hollow column 202, and the two stirring rods 203 are positioned in the inner cavity of the stirring box 201; the bevel gear I204 is fixedly arranged on the hollow column 202; the motor I205 is fixedly arranged on the upper end surface of the top cover of the stirring box 201, and a bevel gear is fixedly arranged on a motor shaft of the motor I, and the bevel gear is meshed with the bevel gear I204; specifically, the motor I205 is started to drive the bevel gear I204 to rotate, so as to drive the hollow column 202 to rotate, the hollow column 202 drives the two stirring rods 203 to rotate, and the two stirring rods 203 rotate to stir the raw materials in the stirring box 201; threaded rod 206 is rotatably mounted in a circular hole of a shelf on stirring box 201 through a central hole of hollow column 202; the long rod 207 is rotatably arranged in a round hole of a side plate of the stirring box 201, and the long rod 207 is connected with the threaded rod 206 through a synchronous belt.

As shown in fig. 6 to 8, the stirring and producing mechanism 2 further includes: the device comprises a supporting plate 208, a cutter 209, a limiting rod I210, a gear set I211, a motor II 212 and a storage barrel I213; the supporting plate 208 is fixedly arranged at the lower end of the stirring box 201 through a rod, a round hole is formed in the supporting plate 208 and fixedly connected with a discharge hole at the lower end of the stirring box 201, and rectangular slotted holes are formed in two sides of the round hole in the supporting plate 208; the two cutters 209 are respectively arranged in two rectangular slotted holes on the supporting plate 208 in a sliding manner, bent rods are arranged on the side surfaces of the two cutters 209, small rods are arranged on the bent rods, the two cutters 209 can be combined or opened, and when the two cutters 209 are combined, molded distiller's yeast extruded by the stirring box 201 can be cut into small blocks; the two limiting rods I210 are arranged, the small rods on the inner ends of the two limiting rods I210 are respectively rotatably arranged in two round holes on the lower end face of the supporting plate 208, slotted holes are formed in the outer ends of the two limiting rods I210, the small rods on the bent rods of the two cutters 209 respectively slide on the slotted holes on the inner ends of the two limiting rods I210, and slotted holes are formed in the middle positions of the two limiting rods I210; shafts of two gears in the gear set I211 are respectively rotatably arranged in two round holes on the supporting plate 208, deflection shafts are arranged on the two gears in the gear set I211 and respectively slide in slotted holes in the middle positions of the two cutters 209; the motor II 212 is fixedly arranged on the upper end surface of the supporting plate 208, a motor shaft of the motor II is fixedly connected with the shaft of one gear in the gear set I211, and the shaft of the motor II 212 is connected with the long rod 207 through a synchronous belt; the storage barrel I213 is fixedly arranged on the ground, clean water for making distiller's yeast is placed in the storage barrel I213, and a water outlet of the storage barrel I213 is connected with a water inlet on the top cover of the stirring box 201 through a water pipe; specifically, after all main raw materials and auxiliary raw materials required for making distiller's yeast are put into the stirring box 201, the motor I205 is started to drive the bevel gear I204 to rotate so as to drive the hollow column 202 to rotate, the hollow column 202 drives the two stirring rods 203 to rotate, the two stirring rods 203 rotate to stir the raw materials in the stirring box 201, and meanwhile, the storage barrel I213 injects a certain amount of water into the stirring box 201 through the water pipe, so that the two stirring rods 203 stir the raw materials in the stirring box 201 into a dough shape; when dough-like distiller's yeast is extruded from the inside of the stirring box 201 outwards, the motor II 212 is started to drive the long rod 207 to rotate, the long rod 207 drives the threaded rod 206 to rotate, the threaded rod 206 extrudes dough-like distiller's yeast stirred by the stirring rod 203 from the outlet of the lower end of the stirring box 201, meanwhile, the motor II 212 drives the gear set I211 to rotate, the gear set I211 drives the outer ends of the two limiting rods I210 to simultaneously outwards or inwards move, at the moment, the outer ends of the two limiting rods I210 drive the two cutters 209 to simultaneously combine or open at the outlet of the lower end of the stirring box 201, and when the two cutters 209 combine, the molded distiller's yeast extruded by the stirring box 201 can be cut into small blocks.

As shown in fig. 9 and 10, the uniform placement mechanism 3 includes: the device comprises a supporting frame I301, a circular plate 302, a limiting rod II 303, a vertical rod 304, a chuck 305 and a tray 306; the support frame I301 is slidably arranged on the underframe 401, and a motor is fixedly arranged on the support frame I301; the circular plate 302 is fixedly arranged on the support frame I301, and a circular hole is formed in the middle of the circular plate 302; the inner end shaft of the limiting rod II 303 is rotatably arranged in a round hole in the middle of the round plate 302, and the inner end shaft of the limiting rod II 303 is fixedly connected with the shaft of a motor fixedly arranged on the support frame I301; the lower end of the vertical rod 304 slides in a turbine-shaped slotted hole on the circular plate 302, the vertical rod 304 slides in a groove on the limiting rod II 303, a clamping disc 305 at the upper end of the vertical rod 304 is fixedly connected, and a groove edge is arranged on the inner wall of the clamping disc 305; tray 306 is slidably mounted on chuck 305, ribs on the outer wall of tray 306 are mounted in cooperation with ribs on the inner wall of chuck 305, and tray 306 can be removed from chuck 305 by manually holding tray 306 and pulling upward; specifically, when the extruded distiller's yeast block needs to be uniformly placed on the tray 306, the stirring box 201 extrudes distiller's yeast outwards, the two cutters 209 cut the distiller's yeast block into distiller's yeast blocks, meanwhile, the motor fixedly installed on the support frame I301 is started to drive the inner end of the limiting rod II 303 to rotate, the outer end of the limiting rod II 303 drives the vertical rod 304 to move along the turbine-shaped slot hole on the circular plate 302 to make turbine-shaped track outwards, at this time, the vertical rod 304 drives the chuck 305 to move outwards so as to drive the tray 306 to move outwards make turbine-shaped track, and thus, the cut distiller's yeast block is uniformly placed on the tray 306 from inside to outside.

As shown in fig. 10, a turbine-shaped slot is provided in the circular plate 302.

As shown in fig. 11, the transfer mechanism 4 further includes: a screw slider group 402 and a storage barrel II 403; the screw rod sliding block set 402 comprises a frame, a screw rod, a motor and a sliding block, wherein the frame is fixedly arranged on the underframe 401, the screw rod is rotatably arranged in the frame, the motor is fixedly arranged on the frame, a motor shaft of the motor is fixedly connected with one end of the screw rod, the sliding block is slidably arranged in the frame, a threaded hole on the sliding block is in threaded fit with the screw rod, and the inner end of the sliding block in the screw rod sliding block set 402 is fixedly connected with the side face of the support frame I301; the storage barrel II 403 is fixedly arranged on the ground through a bracket, rice hulls which are beneficial to distiller's yeast fermentation are placed in the storage barrel II 403, and an automatic door is arranged at the outlet of the lower end of the storage barrel II 403; specifically, the screw rod sliding block set 402 works to drive the supporting frame I301 to move to the position right below the storage barrel II 403, then an automatic door at the outlet of the lower end of the storage barrel II 403 is opened, rice hulls in the storage barrel II 403 are thrown into the tray 306, at the moment, a motor fixedly arranged on the supporting frame I301 is started to drive the inner end of the limiting rod II 303 to rotate, the outer end of the limiting rod II 303 drives the vertical rod 304 to move along a turbine-shaped slot hole on the circular plate 302 to make a turbine-shaped track outwards, at the moment, the vertical rod 304 drives the chuck 305 to move outwards to make a turbine-shaped track to drive the tray 306 to move outwards, and rice hulls in the storage barrel II 403 are uniformly sprinkled on the tray 306 from inside to outside; then, the screw rod sliding block set 402 works to drive the support frame I301 and an upper mechanism thereof to move to the position right below the stirring box 201; when the tray 306 with the distiller's yeast blocks uniformly placed is required to be taken away for fermentation manually, the screw rod sliding block set 402 works to drive the support frame I301 and the upper mechanism thereof to move to one end far away from the storage barrel II 403, so that the tray 306 can be taken down from the chuck 305 by manually holding the tray 306 and pulling upwards, and then the tray 306 with the distiller's yeast blocks placed is taken away for distiller's yeast fermentation.

Working principle: the equipment can quantitatively put the main raw materials and the auxiliary raw materials for making the distiller's yeast, and simultaneously can add the put quantity in equal proportion, so that the resources are saved and the working efficiency is improved while the put quantity is ensured; the equipment can uniformly stir and mix the raw materials to prepare the wine yeast blocks with the same size, so that the condition that the sizes of the wine yeast blocks are different in manual production is avoided, and the fermentation effect of the wine yeast blocks is influenced; the device can automatically and uniformly put the cut wine yeast blocks, so that the labor is saved, and the fermentation efficiency is improved;

When the raw materials are put in, firstly, a motor III 112 is started to drive a gear on a shaft of the motor III to rotate, the gear drives a large disc 103 to rotate, when gear teeth on the large disc 103 move to be meshed with four gears I106 in sequence, the large disc 103 drives a corresponding gear I106 to rotate for one circle, the gear I106 drives a gear II 107 connected with the gear I to rotate, the gear II 107 drives a corresponding material taking device I109 or a material taking device II 110 to rotate, when the material taking device I109 rotates for one circle, four material taking cylinders on the material taking device I109 take main raw materials in a corresponding material storage box 111 and then put the main raw materials into a stirring box 201 downwards along a material discharging round hole of a corresponding lower support frame 108, and when the material taking device II 110 rotates for one circle, the material taking cylinders on the material taking device II 110 can take auxiliary raw materials in a corresponding material storage box 111 and then put the auxiliary raw materials into the stirring box 201 downwards along the material discharging round hole of the corresponding lower support frame 108; thus realizing quantitative feeding of the main raw materials and the auxiliary raw materials; when a large amount of raw materials with equal proportion are required to be put in, a motor on the upper end surface of the large disc 103 is fixedly connected to drive the small disc 105 to rotate, when an arc-shaped bulge on the small disc 105 rotates to be in contact with a semicircular bulge at the lower end of one arc-shaped plate 104, the arc-shaped plate 104 moves upwards under the pushing of the small disc 105 until the peripheral gear teeth of the arc-shaped plate 104 are positioned on the same horizontal plane with the peripheral gear teeth of the large disc 103, so that when the motor III 112 drives the large disc 103 to rotate, the gear teeth on the large disc 103 and the gear teeth on the arc-shaped plate 104 act together to drive the four gears I106 to rotate for two weeks, and double putting of main raw materials and auxiliary raw materials is realized; when the small disc 105 still rotates, the three arc plates 104 are pushed upwards in sequence, so that when the gear teeth on the periphery of the three arc plates 104 and the gear teeth on the periphery of the large disc 103 are combined into a complete circle, three times of feeding of the main raw material and the auxiliary raw material is realized, the equal ratio feeding is realized, the resources and the manpower are saved, and the working efficiency is improved;

When all main raw materials and auxiliary raw materials required for making distiller's yeast are put into the stirring box 201, the motor I205 is started to drive the bevel gear I204 to rotate so as to drive the hollow column 202 to rotate, the hollow column 202 drives the two stirring rods 203 to rotate, the two stirring rods 203 rotate to stir the raw materials in the stirring box 201, and meanwhile, the storage barrel I213 injects a certain amount of water into the stirring box 201 through the water pipe, so that the two stirring rods 203 stir the raw materials in the stirring box 201 into a dough shape; when dough-shaped distiller's yeast is extruded from the inside of the stirring box 201 outwards, the motor II 212 is started to drive the long rod 207 to rotate, the long rod 207 drives the threaded rod 206 to rotate, the threaded rod 206 extrudes the dough-shaped distiller's yeast stirred by the stirring rod 203 from the outlet of the lower end of the stirring box 201, meanwhile, the motor II 212 drives the gear set I211 to rotate, the gear set I211 drives the outer ends of the two limiting rods I210 to simultaneously move outwards or inwards, at the moment, the outer ends of the two limiting rods I210 drive the two cutters 209 to simultaneously combine or open at the outlet of the lower end of the stirring box 201, and when the two cutters 209 combine, the molded distiller's yeast extruded by the stirring box 201 can be cut into small blocks;

When the extruded distiller's yeast block is required to be uniformly placed on the tray 306, firstly, the screw rod sliding block set 402 works to drive the support frame I301 to move to the position right below the storage barrel II 403, then, an automatic door at the outlet of the lower end of the storage barrel II 403 is opened, rice hulls in the storage barrel II 403 are thrown into the tray 306, at this time, a motor fixedly installed on the support frame I301 is started to drive the inner end of the limiting rod II 303 to rotate, the outer end of the limiting rod II 303 drives the vertical rod 304 to move along a turbine-shaped slot hole on the circular plate 302 to make a turbine-shaped track outwards, at this time, the vertical rod 304 drives the chuck 305 to move outwards to make a turbine-shaped track to drive the tray 306 to move outwards to make a turbine-shaped track, and thus, rice hulls in the storage barrel II 403 are uniformly sprinkled on the tray 306 from inside to outside; then, the screw rod sliding block set 402 works to drive the support frame I301 and an upper mechanism thereof to move to the position right below the stirring box 201; then, the stirring box 201 extrudes distiller's yeast outwards, the two cutters 209 cut the distiller's yeast into distiller's yeast blocks, and simultaneously, a motor fixedly arranged on the support frame I301 is started to drive the inner end of the limiting rod II 303 to rotate, the outer end of the limiting rod II 303 drives the vertical rod 304 to move along the turbine-shaped slot hole on the circular plate 302 outwards in a turbine-shaped track, at this time, the vertical rod 304 drives the chuck 305 to move outwards in a turbine-shaped track, and further drives the tray 306 to move outwards in a turbine-shaped track, so that the distiller's yeast blocks after cutting are uniformly placed on the tray 306 from inside to outside;

When the tray 306 with the distiller's yeast blocks uniformly placed is required to be taken away for fermentation manually, the screw rod sliding block set 402 works to drive the support frame I301 and the upper mechanism thereof to move to one end far away from the storage barrel II 403, so that the tray 306 can be taken down from the chuck 305 by manually holding the tray 306 and pulling upwards, and then the tray 306 with the distiller's yeast blocks placed is taken away for distiller's yeast fermentation.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. A distiller's yeast production device for making wine, characterized by comprising: a feeding mechanism (1), a stirring and manufacturing mechanism (2), a uniform placing mechanism (3) and a transfer mechanism (4); the upper support frame (101) of the feeding mechanism (1) is fixedly arranged on the ground, and the feeding mechanism (1) is used for quantitatively feeding raw materials for making distiller's yeast; the stirring box (201) of the stirring and making mechanism (2) is fixedly arranged at the inner side of the upper supporting frame (101) through a rod, and the stirring and making mechanism (2) is used for mixing and making distiller's yeast raw materials; the support frame I (301) of the uniform placing mechanism (3) is slidably arranged on the underframe (401), and the uniform placing mechanism (3) is used for uniformly placing the wine yeast blocks; the underframe (401) of the transfer mechanism (4) is fixedly arranged on the ground, and the transfer mechanism (4) is used for transferring the uniform placing mechanism (3);

The feeding mechanism (1) also comprises: the device comprises a supporting disc (102), a large disc (103), an arc-shaped plate (104), a small disc (105), a gear I (106), a gear II (107), a lower supporting frame (108), a material taking device I (109), a material taking device II (110), a material storage box (111) and a motor III (112); four storage boxes (111) are arranged, and the four storage boxes (111) are fixedly arranged on the top plate of the upper supporting frame (101) respectively; the supporting disc (102) is fixedly arranged on the lower end surface of the top plate of the upper supporting frame (101); the upper end ring frame of the large disc (103) is rotatably arranged on the lower end face of the supporting disc (102), a section of gear teeth is arranged on the periphery of the large disc (103), the length of the section of gear teeth is one fourth of the circumference of the large disc (103), three grooves at the lower end of the large disc (103) are formed, round holes are formed in the grooves, and a motor is fixedly arranged on the upper end face of the large disc (103); three arc plates (104) are arranged, and the three arc plates (104) are respectively and slidably arranged in three grooves on the large disc (103); the small disc (105) is rotatably arranged in a round hole in the middle of the large disc (103), the shaft of the small disc (105) is fixedly connected with the shaft of a motor fixedly arranged on the upper end surface of the large disc (103), and an arc-shaped bulge is fixedly arranged at the upper end of the small disc (105); the four gears I (106) are arranged, shafts of the four gears I (106) are respectively rotatably arranged in four round holes on the supporting disc (102), the four gears I (106) are intermittently meshed with gear teeth on the periphery of the large disc (103), and the four gears I (106) are intermittently meshed with the gear teeth on the periphery of the three arc plates (104) after the arc plates (104) move upwards; the lower support frame (108) is fixedly arranged at the lower end of the upper support frame (101), four discs are fixedly arranged on the lower support frame (108), and each disc is provided with a discharge round hole; the material taking device I (109) is rotatably arranged on a disc on the lower supporting frame (108), and the material taking device I (109) is rotatably arranged on the lower end face of a storage box (111) for placing the main raw materials; three material taking devices II (110) are respectively and rotatably arranged on the other three discs on the lower supporting frame (108), the three material taking devices II (110) are respectively and rotatably arranged on the lower end surfaces of the other material storage boxes (111) for placing auxiliary materials, and two material taking cylinders are arranged on the material taking devices II (110); the four gears II (107) are respectively and rotatably arranged on upper end shafts of the material taking device I (109) and the three material taking devices II (110), and shafts of the four gears II (107) are respectively and correspondingly connected with shafts of the four gears I (106) through synchronous belts; the motor III (112) is fixedly arranged on the side surface of the supporting disc (102), a motor shaft of the motor III is fixedly connected with a gear, the gear is intermittently meshed with gear teeth on the large disc (103), and the gear is intermittently meshed with gear teeth on the periphery of the three arc plates (104) after the arc plates (104) move upwards.

2. The distiller's yeast production device for making wine according to claim 1, wherein a round rod is fixedly installed on the arc-shaped plate (104), the round rod correspondingly penetrates through a round hole in a groove of the large disc (103), a spring is installed on the periphery of the round rod, the upper end of the spring is fixedly connected with the lower end face of a ring frame of the large disc (103), the other end of the spring is connected with a support plate on the round rod of the arc-shaped plate (104), gear teeth are arranged on the periphery of the arc-shaped plate (104), and semicircular protrusions are fixedly installed at the lower end of the arc-shaped plate (104).

3. The distiller's yeast production device for producing wine according to claim 1, wherein four material taking cylinders are arranged on the material taking device I (109).

4. The distiller's yeast production device for making wine according to claim 1, wherein the stirring and making mechanism (2) comprises: the stirring box (201), the hollow column (202), the stirring rod (203), the bevel gear I (204), the motor I (205), the threaded rod (206) and the long rod (207); the stirring box (201) is fixedly arranged on the inner side of the upper supporting frame (101) through a rod, a top cover is fixedly arranged at the upper end of the stirring box (201), a round hole is formed in the middle of the top cover, four feeding holes and a water inlet are formed in the top cover, and the four feeding holes in the top cover of the stirring box (201) are connected with the discharging round holes in the four discs on the lower supporting frame (108) through pipes; the hollow column (202) is rotatably arranged in a round hole in the middle of the top cover of the stirring box (201); the two stirring rods (203) are arranged, the two stirring rods (203) are fixedly arranged on two sides of the hollow column (202), and the two stirring rods (203) are positioned in the inner cavity of the stirring box (201); the bevel gear I (204) is fixedly arranged on the hollow column (202); the motor I (205) is fixedly arranged on the upper end surface of the top cover of the stirring box (201), a bevel gear is fixedly arranged on the motor shaft of the motor I, and the bevel gear is meshed with the bevel gear I (204); the threaded rod (206) passes through the middle hole of the hollow column (202) and is rotatably arranged in a round hole of a frame on the stirring box (201); the long rod (207) is rotatably arranged in a round hole of a side plate of the stirring box (201), and the long rod (207) is connected with the threaded rod (206) through a synchronous belt.

5. The distiller's yeast production device for making wine according to claim 1, wherein the stirring and making mechanism (2) further comprises: the device comprises a supporting plate (208), a cutter (209), a limiting rod I (210), a gear set I (211), a motor II (212) and a storage barrel I (213); the supporting plate (208) is fixedly arranged at the lower end of the stirring box (201) through a rod, a round hole is formed in the supporting plate (208), the round hole is fixedly connected with a discharge hole at the lower end of the stirring box (201), and rectangular slotted holes are formed in two sides of the round hole in the supporting plate (208); the two cutters (209) are arranged, rods on the two cutters (209) are respectively and slidably arranged in two rectangular slotted holes on the supporting plate (208), bent rods are arranged on the side surfaces of the two cutters (209), and small rods are arranged on the bent rods; the two limiting rods I (210) are arranged, the small rods on the inner ends of the two limiting rods I (210) are respectively rotatably arranged in two round holes on the lower end face of the supporting plate (208), slotted holes are formed in the outer ends of the two limiting rods I (210), the small rods on the bent rods of the two cutters (209) respectively slide on the slotted holes on the inner ends of the two limiting rods I (210), and slotted holes are formed in the middle positions of the two limiting rods I (210); shafts of two gears in the gear set I (211) are respectively rotatably arranged in two round holes on the supporting plate (208), deflection shafts are arranged on the two gears in the gear set I (211), and the deflection shafts respectively slide in slotted holes in the middle positions of the two cutters (209); the motor II (212) is fixedly arranged on the upper end surface of the supporting plate (208), a motor shaft of the motor II is fixedly connected with the shaft of one gear in the gear set I (211), and the shaft of the motor II (212) is connected with the long rod (207) through a synchronous belt; the storage barrel I (213) is fixedly arranged on the ground, and a water outlet of the storage barrel I (213) is connected with a water inlet on the top cover of the stirring box (201) through a water pipe.

6. The distiller's yeast production device for making wine according to claim 1, wherein the uniform placement mechanism (3) comprises: a supporting frame I (301), a circular plate (302), a limiting rod II (303), a vertical rod (304), a chuck (305) and a tray (306); the support frame I (301) is slidably arranged on the underframe (401), and a motor is fixedly arranged on the support frame I (301); the circular plate (302) is fixedly arranged on the support frame I (301), and a circular hole is formed in the middle of the circular plate (302); the inner end shaft of the limiting rod II (303) is rotatably arranged in a round hole in the middle of the round plate (302), and the inner end shaft of the limiting rod II (303) is fixedly connected with the shaft of a motor fixedly arranged on the support frame I (301); the lower end of the vertical rod (304) slides in a turbine-shaped slotted hole on the circular plate (302), the vertical rod (304) slides in a groove on the limiting rod II (303), a clamping disc (305) at the upper end of the vertical rod (304) is fixedly connected, and a groove edge is arranged on the inner wall of the clamping disc (305); the tray (306) is slidably mounted on the chuck (305), and the ribs on the outer wall of the tray (306) are mounted in cooperation with the groove ribs on the inner wall of the chuck (305).

7. The distiller's yeast production device for producing wine according to claim 6, wherein the circular plate (302) is provided with a turbine-shaped slot.

8. The distiller's yeast production device for making wine according to claim 1, wherein the transfer mechanism (4) further comprises: a screw rod sliding block group (402) and a storage barrel II (403); the screw rod sliding block set (402) comprises a frame, a screw rod, a motor and a sliding block, wherein the frame is fixedly arranged on the underframe (401), the screw rod is rotatably arranged in the frame, the motor is fixedly arranged on the frame, a motor shaft of the motor is fixedly connected with one end of the screw rod, the sliding block is slidably arranged in the frame, a threaded hole on the sliding block is in threaded fit with the screw rod, and the inner end of the sliding block in the screw rod sliding block set (402) is fixedly connected with the side face of the support frame I (301); the storage barrel II (403) is fixedly arranged on the ground through a bracket, and an automatic door is arranged at the outlet of the lower end of the storage barrel II (403).