CN111169087A - Prepare automatic feed subassembly of stir-fry of peanut oil - Google Patents

Abstract

The invention provides a stir-frying automatic feeding assembly for preparing peanut oil, which comprises a heating mechanism and a conveying mechanism, wherein the heating mechanism is used for heating, stir-frying and stir-frying oil, the conveying mechanism is used for conveying the oil stir-fried oil fried by the heating mechanism into an oil pressing cylinder, a pressing cage and a pressing bore, the heating mechanism comprises a fixed material barrel, the material barrel is of a barrel structure with an upward opening, a circular barrel cover matched with the material barrel in a covering manner is arranged at the opening, a heater is wrapped on the outer circumferential surface of the material barrel and is tightly attached to the outer circumferential surface of the material barrel, the heater covers the whole circumferential surface of the material barrel, the material barrel is made of a material with good heat conductivity, a stir-frying plate I and a stir-frying plate I for stirring the oil are arranged in the material barrel, a stirring shaft is driven to rotate and drive by a stirring motor, and the significance lies in that the quick stir-frying and stirring shaft can be, The fried oil is uniformly fried and the fried oil can be automatically added into the oil press cylinder/press bore/press cage.

Description

Prepare automatic feed subassembly of stir-fry of peanut oil

Technical Field

The invention relates to an oil press, in particular to a stir-frying automatic feeding assembly for preparing peanut oil.

Background

An oil press is a machine for extruding oil from oil (peanut, soybean, corn, sesame, etc.) by raising the temperature and activating oil molecules under the action of mechanical external force, and the oil press has the working procedures of firstly adding oil into a pressing cage/pressing bore, then heating, frying, squeezing, discharging the squeezed vegetable oil, and finally discharging oil residue/oil cake out of the pressing cage/pressing bore The oil frying feeding device can uniformly fry and heat and fry and can automatically add the fried oil into the oil press in the pressing cylinder/pressing cage.

Disclosure of Invention

In order to solve the defects of the prior art, the invention aims to provide the feeding device for frying the oil material of the oil press, which has the advantages of ingenious structure, simple principle, convenient operation and use, high automation degree, quick and uniform frying and frying of the oil material outside the pressing and boring cage and automatic addition of the fried oil material into the pressing and boring cage.

In order to achieve the technical purpose, the technical scheme adopted by the invention is as follows.

The automatic stir-frying feeding assembly for preparing peanut oil comprises a heating mechanism and a conveying mechanism, wherein the heating mechanism is used for heating, stir-frying and stir-frying oil, the conveying mechanism is used for conveying the oil stir-fried by the heating mechanism into an oil pressing cylinder/a pressing cage/a pressing bore, the heating mechanism comprises a fixed material barrel, the material barrel is of a barrel structure with an upward opening, a circular barrel cover matched with the material barrel in a covering manner is arranged at the opening of the material barrel, a heater is wrapped on the outer circumferential surface of the material barrel and is attached to the outer circumferential surface of the material barrel, the heater covers the whole circumferential surface of the material barrel, and the material barrel is made of a material with good heat conductivity;

the barrel cover is opened by up-and-down sliding of the sliding sleeve and axial rotation around the guide pillar, a fixing bolt with a knob is penetrated on the sliding sleeve along the radial sliding of the sliding sleeve, the fixing bolt and the sliding sleeve form threaded connection and can be tightly pressed or separated from the outer circular surface of the guide pillar, when the fixing bolt is tightly pressed, the sliding sleeve is fixed on the guide pillar, and when the sliding sleeve is separated from the guide pillar, the sliding sleeve moves on the guide pillar.

As a further optimization or improvement of the present solution.

The stirring shaft is coaxially and rotatably arranged in the charging basket, the stirring shaft extends to the opening of the charging basket from the bottom of the charging basket, a first stir-frying plate which is vertically arranged is arranged between the stirring shaft and the inner wall of the charging basket, the top of the first stir-frying plate is fixedly connected with the outer circular surface of the stirring shaft, the first stir-frying plates are four and are arranged in an array mode along the circumferential direction of the charging basket, a second stir-frying plate is further arranged between the stirring shaft and the inner wall of the charging basket, one end of the second stir-frying plate is fixedly connected with the outer circular surface of the stirring shaft, the other end of the second stir-frying plate extends to be close to the inner wall of the charging basket, the lower end face of the second stir-frying plate is attached to the bottom of the charging basket, the upper end face is obliquely arranged, the distance between the upper end face and.

As a further optimization or improvement of the present solution.

The barrel cover is characterized in that a stirring motor is coaxially and fixedly arranged on the upper end face of the barrel cover, an output shaft of the stirring motor movably extends to the lower portion of the barrel cover, an external spline is arranged at the top end of a stirring shaft, an output shaft of the stirring motor is arranged into a sleeve shape of an internal spline, and when the barrel cover covers the charging barrel, the stirring motor is combined with the stirring shaft.

The automatic stir-fry feeding assembly of claim 1 wherein: as a further optimization or improvement of the present solution.

The conveying mechanism comprises a first conveying pipe and a second conveying pipe which are arranged below the charging basket, the first conveying pipe is positioned above the second conveying pipe, the output end of the second conveying pipe is arranged in an open mode, is in butt joint with the oil pressing cylinder/pressing cage/pressing bore, and is arranged in a closed mode, the first conveying pipe is arranged between the second conveying pipe and the charging basket, the input end of the first conveying pipe is in connection with the charging basket, the connection position is located at the eccentric position of the charging basket, the output end of the first output pipe is in connection with the second conveying pipe, and the connection position is close to the closed end of the second conveying, the conveying pipe II is internally coaxially and rotatably provided with an auger matched with the conveying pipe II, the auger penetrates through the whole conveying pipe II, a rotating shaft of the auger movably penetrates through the closed end of the conveying pipe II to extend outwards and is connected with a power driving device, the screw conveyer is driven to rotate, so that the fried and fried oil is conveyed to the oil pressing cylinder/pressing cage/pressing bore through the first opening.

Compared with the prior art, the invention has the advantages of ingenious structure, simple principle, convenient operation and use and high automation degree, can quickly and uniformly fry and fry the oil outside the pressing and boring/squeezing cage, and can automatically add the fried oil into the pressing and boring/squeezing cage.

Drawings

FIG. 1 is a schematic structural diagram of an initial state of the present invention.

FIG. 2 is a schematic structural diagram of the initial state of the present invention.

Fig. 3 is a schematic structural diagram of the working state of the present invention.

Fig. 4 is a schematic structural diagram of the working state of the present invention.

Fig. 5 is a matching diagram of the oil press device and the mounting frame.

Fig. 6 is a schematic structural diagram of the squeezing cylinder.

Fig. 7 is an external structural schematic diagram of the squeezing cylinder.

FIG. 8 is a view showing a plurality of squeezing cylinders.

Fig. 9 is a schematic structural diagram of the first fixing plate.

Fig. 10 is a view showing the engagement of the rotary cylinder with the fixed cylinder.

Fig. 11 is an exploded view of the rotating cylinder and stationary sleeve.

Fig. 12 is a schematic structural view of a slag discharge duct and a slag discharge passage.

Fig. 13 is a schematic structural diagram of the plasticizing oil groove.

Fig. 14 is a schematic view of the structure of the guide sleeve.

FIG. 15 is a view showing the combination of the squeezing rod, the residue discharge rod and the squeezing cylinder.

FIG. 16 is a schematic view showing the structure of the press bar and the residue discharge bar.

Fig. 17 is a view showing the combination of the press bar, the slag discharging bar, and the feed driving mechanism.

Fig. 18 is a view showing the combination of the press bar, the slag discharging bar, and the feed driving mechanism.

Fig. 19 is a matching view of a feeding device and a squeezing cylinder.

Fig. 20 is a schematic structural view of a feeding device.

Fig. 21 is an exploded view of the feeding device.

Fig. 22 is a schematic structural view of the heating mechanism.

Fig. 23 is a partial structural view of the heating mechanism.

Fig. 24 is a partial structural view of the heating mechanism.

Fig. 25 is a partial structural schematic view of the heating mechanism.

Fig. 26 is a partial schematic view of the heating mechanism.

Fig. 27 is a schematic structural view of the conveying mechanism.

FIG. 28 is a drawing showing the power driving device, the rotary shaft of the rotary cylinder and the packing auger.

FIG. 29 is a drawing showing the power driving device and the packing auger.

FIG. 30 is a view of the power drive means in cooperation with the rotatable drum.

Labeled as:

100. installing a frame;

200. an oil press device; 210. a squeezing cylinder; 211. a first fixing plate; 212. a second fixing plate; 213. fixing the cylinder; 213a, an annular transition chamber; 213b, an oil drain pipe; 214. rotating the cylinder; 214a, a rotating shaft of the rotating cylinder; 215a, opening one; 215b, opening two; 215c, opening three; 216. an oil drain hole; 217a, a slag discharge through pipe; 217b, a slag discharge channel; 218a, a transition oil groove; 218b, steel screens; 218c, a sealing cover plate; 219. a guide sleeve; 220. an oil tank is connected; 230. a press bar; 230a, a first rod; 230b, a first rod head; 240. a slag discharging rod; 240a, a second rod; 240b, a second club head; 250. a feed drive mechanism; 251. a slider; 252. a screw rod; 253. a feed motor; 254. a first belt transmission assembly;

300. a feeding device; 310. a heating mechanism; 311. a charging bucket; 312. a barrel cover; 313. a heater; 314. a guide post; 315. a sliding sleeve; 316. a cross arm; 317. fixing the bolt; 318a, a stirring shaft; 318b, a stirring motor; 319a, stir-frying the first plate; 319b, stir-frying the second plate; 320. a conveying mechanism; 321. a first conveying pipe; 322. a second conveying pipe; 323. a packing auger;

400. a power drive device; 401. a main motor; 402. a belt transmission assembly II; 403. a first transmission shaft; 404. a second transmission shaft; 405. a belt transmission assembly III; 406. a belt transmission assembly IV; 407. a gap sheave drive assembly.

Detailed Description

Referring to fig. 1 to 30, a circulating rotary cylinder type continuous automatic oil press comprises a mounting frame 100 which is stable to fall on the ground, an oil press device 200, a feeding device 300 and a power driving device 400, wherein the oil press device 200 and the power driving device 400 are fixedly arranged on the mounting frame 100, the feeding device 300 is fixedly arranged on the oil press device 200, the feeding device 300 is used for heating, frying and frying oil and conveying the fried oil into the oil press device 200, the oil press device 400 comprises a plurality of oil press cylinders 210 (which are equivalent to pressing cages/boring in the prior art) which can be circularly and sequentially communicated with the feeding device 300 and receive the oil conveyed by the oil press cylinders, an oil receiving tank 220 for collecting the pressed vegetable oil, a press rod 230, a slag discharging rod 240 and a feeding driving mechanism 250, the feeding driving mechanism 250 can drive the press rod 230 to be inserted into one of the oil press cylinders 210 corresponding to press the oil press rod and press the oil inside of the oil press cylinder, meanwhile, the feeding driving mechanism 250 can drive the residue discharging rod 240 to be inserted into a corresponding oil pressing cylinder 210 and eject the oil pressed therein outwards, the oil pressing cylinder 210 is communicated with the feeding device 300 to receive the oil conveyed by the oil pressing cylinder, the oil pressing cylinder 210 is matched with the pressing rod 230 to squeeze the oil, and the oil pressing cylinder 210 is matched with the residue discharging rod 240 to eject the oil pressed therein outwards in sequence and continuously.

The oil press device 200 further comprises a first circular fixing plate 211 and a second circular fixing plate 212 which are fixedly connected with the mounting frame 100 and coaxially arranged, a first fixing cylinder 213 with a thin-wall structure is coaxially and fixedly arranged between the first fixing plate 211 and the second fixing plate 212, one end of the first fixing cylinder 213 is fixedly connected with the first fixing plate 211 in a sealing manner, the other end of the first fixing cylinder 213 is fixedly connected with the second fixing plate 212 in a sealing manner, a rotating cylinder 214 is coaxially and movably arranged in the first fixing cylinder 213, the rotating cylinder 214 is respectively attached to the first fixing plate 211 and the second fixing plate 212 along two axial end faces of the rotating cylinder 214, the diameter of the outer circular surface of the rotating cylinder 214 is smaller than that of the inner circular surface of the fixing cylinder 213, an annular transition cavity 213a is formed between the outer circular fixing cylinder and the inner circular fixing cylinder 213, a rotating shaft 214a of the rotating cylinder 214 is rotatably connected and matched with the first fixing plate 211 and the, one end opening of the oil squeezing cylinder 210 extends to be flush with one end face of the rotary cylinder body 214, the other end opening extends to be flush with the other end face of the rotary cylinder body 214, six oil squeezing cylinders 210 are arranged in an array mode along the circumferential direction of the rotary cylinder body 214, a rotary cylinder body rotating shaft 214a of the rotary cylinder body 214 can receive the driving of the power driving device 400 and form a step-by-step rotary motion of sixty degrees around the axis direction of the rotary cylinder body rotating shaft, and the oil squeezing cylinder 210 is sequentially matched with the feeding device 300, the squeezing rods 230 and the slag discharging rods 240.

Specifically, in order to facilitate the vegetable oil extruded from the oil material to smoothly fall into the oil receiving tank 220, a plurality of fine holes communicated with the inside of the oil pressing cylinder 210 are formed on the outer circumferential surface of the oil pressing cylinder 210, and the fine holes cover the entire circumferential surface of the oil pressing cylinder 210 (only a part of the fine holes are shown in fig. 4), oil discharge holes 216 radially arranged along the outer circumferential surface of the rotary cylinder 214 are formed on the outer circumferential surface of the rotary cylinder 214, the oil discharge holes 216 are communicated with the fine holes on the oil pressing cylinder 210, the oil discharge holes 216 are provided with a plurality of rows and are arranged in a row along an axial array parallel to the rotary cylinder 214, the oil discharge holes 216 are provided with a plurality of rows and six rows along the circumferential direction of the rotary cylinder 214, each row of the oil discharge holes 216 is arranged corresponding to one oil pressing cylinder 210, the oil receiving tank 220 is placed on the ground and is located under the fixed cylinder 213, the oil receiving tank 220 is, the input end of the oil discharge pipe 213b is connected with the annular transition cavity 213a, the output end is connected with the oil tank 220, the fine hole, the oil discharge hole 216, the annular transition cavity 213a and the oil discharge pipe 213b form a first oil discharge channel, in the working process, oil enters the oil squeezing cylinder 210, the oil squeezing rod 230 penetrates through the first fixing plate 211 to be inserted into the oil squeezing cylinder 210 and to be squeezed by interaction with the second fixing plate 212, squeezed vegetable oil flows into the annular transition cavity 213a through the fine hole and the oil discharge hole 216, and then the vegetable oil is discharged into the collection tank 220 through the oil discharge pipe 213 b.

Specifically, in order to increase the discharge rate of the vegetable oil, a transition oil groove 218a is formed in the eccentric position of the second fixing plate 212, the transition oil groove 218a vertically extends downwards to the lower edge of the second fixing plate 212, a circular hard steel filter screen 218b which penetrates through the inner part and the outer part is arranged at the upper half part of the bottom of the transition oil groove 218a, the steel filter screen 218b rotates to the lowermost oil squeezing cylinder 210 to be coaxially communicated with the lowermost oil squeezing cylinder 210, a notch which penetrates through the annular transition cavity 213a is formed in the lower half part of the bottom of the transition oil groove 218a, a sealing cover plate 218c which is matched with the opening of the transition oil groove 218a is arranged at the opening of the transition oil groove 218a, the steel filter screen 218b, the transition oil groove 218a, the annular transition cavity 213a and the oil discharging pipe 213b form a second oil discharging channel, and the squeezed vegetable oil can sequentially pass through the steel filter screen 218, The drain pipe 213b drains into the oil receiving tank 220.

More specifically, in order to facilitate the squeezing cylinder 210 to be coupled with the squeezing rod 230, the residue discharging rod 230 and the feeding device 300, the first fixing plate 211 is provided with a first circular opening 215a, a second circular opening 215b and a third circular opening 215c, the first circular opening 215a, the second circular opening 215b and the third circular opening 215c are penetrated through, the first circular opening 215a is aligned with the same shaft of the oil pressing cylinder 210 which rotates to the topmost part and communicated, the first circular opening 215a and the second circular opening 215b are communicated, the second circular opening 215b is aligned with the same shaft of the oil pressing cylinder 210 which rotates to the bottommost part and communicated, the second circular opening 215b and the third circular opening 215c are used for allowing the pressing rod 230 to movably penetrate through, the third circular opening 215c is located at the right side position of a connecting line of the first circular opening 215a and the second circular opening, the first fixing plate 211 is further fixedly provided with a guide sleeve 219, and the guide sleeve 219 is coaxially connected with the second opening 215b and is used for guiding the pressing rod 230 to be inserted into the oil cylinder 210.

More specifically, in order to be able to eject the oil residue in the oil pressing cylinder 210 that rotates to be aligned with the opening three 215c outward, the second fixing plate 212 is fixedly provided with a slag discharge through pipe 217a in a penetrating manner, the slag discharge through pipe 217a is arranged coaxially with the opening three 215c, the other end of the oil pressing cylinder 210 that rotates to be coaxially aligned with the opening three 215c is also coaxially aligned with the slag discharge through pipe 217a, an output end of the slag discharge through pipe 217a is fixedly sleeved with a slag discharge channel 217b that is arranged obliquely downward, the inner diameter of the slag discharge through pipe 217a is not smaller than the inner diameter of the oil pressing cylinder 210, during slag discharge, the slag discharge rod 240 is inserted into the oil pressing cylinder 210 from the opening three 215c, and the oil residue inside of the oil pressing cylinder is ejected outward through the slag discharge through pipe 217a and the slag discharge channel 217b, and then the slag discharge rod 240.

The squeezing rod 230 and the slag discharging rod 240 are both positioned between the first fixing plate 211 and the feeding driving mechanism 250, the squeezing rod 230 is composed of a first rod piece 230a and a first rod head 230b which are coaxially fixed, the inner diameter of the squeezing cylinder 210, the caliber of the second opening 215b, the inner diameter of the guide sleeve 219 and the outer diameter of the first rod head 230b are equal, one end of the first rod piece 230a is fixedly connected with the first rod head 230b, the other end of the first rod piece 230a is fixedly connected with the feeding driving mechanism 250, and the initial position of the rod head 230b is inserted into the guide sleeve 219.

The slag discharging rod 240 is composed of a second rod 240a and a second rod head 240b which are coaxially fixed, the outer diameter of the second rod head 240b and the caliber of the third opening 215c are equal to the inner diameter of the oil squeezing cylinder 210, one end of the second rod 240a is fixedly connected with the second rod head 240b, the other end of the second rod 240a is fixedly connected with the feeding driving mechanism 250, and the initial position of the second rod head 240b is inserted into the third opening 215 c.

In the process of squeezing oil, a user adds oil into the feeding device 300 at one time, the feeding device 300 firstly heats and fries the oil to be cooked, then adds the fried and cooked oil into the oil squeezing cylinder 210 aligned with the first opening 215a through the first opening 215a, the power driving device 400 drives the rotary cylinder body 214 to rotate step by step, when the oil squeezing cylinder 210 filled with the oil is aligned with the squeezing rod 230, the feeding driving mechanism 250 drives the squeezing rod 230 to be inserted into the oil squeezing cylinder 210 from the second inlet 215b, the squeezing rod 230 is matched with the steel filter screen 218b to squeeze the oil, the squeezed vegetable oil is discharged into the oil receiving tank 220 through the first oil discharge channel and the second oil discharge channel, the squeezing rod 230 is withdrawn and reset, the oil is changed into oil residue, when the oil squeezing cylinder 210 filled with the oil residue is rotated to be aligned with the residue discharge rod 240, the feeding driving mechanism 250 drives the residue discharge rod 240 to be inserted into the oil squeezing cylinder 210, the oil residue is ejected outwards by the residue discharge rod 240 through the residue discharge through pipe 217a and the residue discharge channel 217b, the residue discharge rod 240 is retracted and reset, the squeezing rod 230 squeezes the oil, and the residue discharge rod 240 discharges the oil residue synchronously and all in the time interval of the gradual rotation of the rotary cylinder 214.

The feeding driving mechanism 250 comprises two screw rods 252 rotatably arranged between the mounting rack 100 and the first fixing plate 211, the axial direction of the screw rods 252 is parallel to the axial direction of the squeezing rod 230, one end of each screw rod 252 is rotatably connected and matched with the mounting rack 100, the other end of each screw rod 252 is rotatably connected and matched with the first fixing plate 211, one screw rod 252 is arranged on one side of the squeezing rod 230, the other screw rod 252 is arranged on one side of the slag discharging rod 240, a sliding block 251 is movably sleeved on each screw rod 252 and is in threaded connection and matching with the screw rod, the sliding block 251 and the mounting rack 100 form sliding guide matching along the axial direction parallel to the screw rods 252, one end of each squeezing rod 230, which is far away from the squeezing cylinder 210, is fixedly connected with the sliding block 251, one end of each slag discharging rod 240, which is far away from the squeezing cylinder 210, is fixedly connected with the sliding block 210, and in order to drive the rotation of the, a belt transmission assembly 254 for connecting the output end of the feed motor 253 and the drive end of the screw rod 252 is arranged between the output end of the feed motor 253 and the drive end of the screw rod 252, and the belt transmission assembly 254 comprises a first driving belt wheel coaxially and fixedly sleeved on the feed motor 253, a first driven belt wheel coaxially and fixedly sleeved on the drive end of the screw rod 252, and a first belt which is wound on the first driving belt wheel and the first driven belt wheel and forms a closed loop.

During the working process of the feeding driving mechanism 230, the feeding motor 253 is started, the belt transmission assembly I254 transmits the power of the feeding motor 253 to the screw rod 252 and drives the screw rod 252 to rotate around the axial direction of the screw rod 252, the screw rod 252 drives the driving slide block 251 to slide close to the fixing plate I211 along the axial direction of the screw rod 252, the slide block 252 drives the pressing rod 230 and the slag discharging rod 240 to move synchronously, the pressing rod 230 is inserted into the oil pressing cylinder 210 from the opening II 215b to press oil, the slag discharging rod 240 is inserted into the oil pressing cylinder 210 from the opening III 215c to eject oil slag outwards, finally, the feeding motor 253 rotates reversely and drives the screw rod 252 to rotate reversely, the slide block 251 is far away from the fixing plate I211 to slide and reset, and the pressing rod 230 and the slag discharging rod 240 are retracted and reset in the.

In order to heat and fry the oil and convey the oil into the oil cylinder 210 through the first opening 215a, the feeding device 300 comprises a heating mechanism 310 and a conveying mechanism 320, the heating mechanism 310 is used for heating, frying and stir-frying the oil, the conveying mechanism 320 is used for conveying the oil fried and stir-fried by the heating mechanism 310 into the oil pressing cylinder 210 through the first opening 215a, the heating mechanism 310 comprises a charging bucket 311 which is positioned right above the first fixing plate 211 and is fixedly connected with the first fixing plate, the charging bucket 311 is of a cylinder structure with an upward opening, a circular bucket cover 312 which is matched with the charging bucket in a covering manner is arranged at the opening, a heater 313 is wrapped on the outer circular surface of the charging bucket 311, the heater 313 is attached to the outer circular surface of the charging bucket 311, the heater 313 covers the whole circumferential surface of the charging bucket 311, the charging bucket 311 is made of a material with good thermal conductivity, the purpose is to smoothly transfer the heat generated by the heater 313 into the barrel 311.

Specifically, in the process of heating, frying, heating and frying oil, a part of heat is transferred to the barrel cover 312, so that the temperature of the barrel cover 312 is high, and a user cannot conveniently open and close the barrel cover 312, therefore, one side of the barrel 311 is provided with a guide pillar 314 which is axially parallel to the axial direction of the barrel 311, the lower end of the guide pillar 314 is fixedly connected with the second fixing plate 212, the height of the guide pillar 314 is greater than that of the barrel 311, the guide pillar 314 is slidably sleeved with a sliding sleeve 315 which can slide up and down along the axial direction of the guide pillar, a heat insulation cross arm 316 for fixedly connecting the outer circumferential surface of the sliding sleeve 315 and the upper end surface of the barrel cover 312 is arranged between the outer circumferential surface of the sliding sleeve 315 and the upper end surface of the barrel cover 312, the barrel cover 312 is opened by the up and down sliding of the sliding sleeve 315 and the axial rotation around the guide pillar 314, in order to fix the barrel cover 312, a fixing bolt 317 with a knob is slidably arranged on the sliding sleeve 315, during compression, the sliding sleeve 315 is fixed on the guide post 314, and during separation, the sliding sleeve 315 moves on the guide post 314, and the barrel cover 312 is opened and closed through the mutual matching of the sliding sleeve 315 and the fixing bolt 317.

More specifically, in order to improve the efficiency of frying oil in the material barrel 311, a stirring shaft 318a is coaxially and rotatably disposed in the material barrel 311, the stirring shaft 318a extends from the bottom of the material barrel 311 to the opening of the material barrel 311, a first stir-frying plate 319a is disposed between the stirring shaft 318a and the inner wall of the material barrel 311, the top of the first stir-frying plate 319a is fixedly connected to the outer circumferential surface of the stirring shaft 318a, four first stir-frying plates 319a are disposed and arrayed along the circumferential direction of the material barrel 311, a second stir-frying plate 319b is disposed between the stirring shaft 318a and the inner wall of the material barrel 311, one end of the second stir-frying plate 319b is fixedly connected to the outer circumferential surface of the stirring shaft 318a, the other end of the second stir-frying plate 319b extends to be close to the inner wall of the material barrel 311, the lower end surface of the second stir-frying plate 319b is attached to the bottom of the material barrel 311, the upper end surface is obliquely disposed, and the distance between the, the second stir-frying plates 319b are four and are arranged in an array along the circumferential direction of the material barrel 311, in order to drive the stir-frying shaft 318a to rotate, the upper end surface of the barrel cover 312 is coaxially and fixedly provided with a stirring motor 318b, an output shaft of the stirring motor 318b movably extends to the lower side of the barrel cover 312, the top end of the stirring shaft 318a is provided with an external spline, an output shaft of the stirring motor 318b is provided with a sleeve shape with an internal spline, when the barrel cover 312 covers the material barrel 311, the stirring motor 318b is combined with the stirring shaft 318a, the stirring shaft 318a is driven by the stirring motor 318b to rotate around the self axial direction, so that the first stir-frying plates 319a and the second stir-frying plates 319b stir and fry the oil, and the oil is heated uniformly and.

In order to convey the fried and fried oil material into the oil squeezing cylinder 210, the conveying mechanism 320 comprises a first conveying pipe 321 and a second conveying pipe 322 which are arranged below the material barrel 311 and are close to the first fixing plate 211, the first conveying pipe 321 is arranged above the second conveying pipe 322, the output end of the second conveying pipe 322 is arranged in an open mode, is coaxially and fixedly connected and communicated with the first opening 215a, and is arranged in a closed mode, the first conveying pipe 321 is arranged between the second conveying pipe 322 and the material barrel 311, the input end of the first conveying pipe 321 is connected and communicated with the material barrel 311, the connecting position is located at the eccentric position of the material barrel 311, the output end of the first conveying pipe 321 is connected and communicated with the second conveying pipe 322, the connecting position is close to the closed end of the second conveying pipe 322, the packing auger 323 matched with the second conveying pipe 322 is coaxially and rotatably arranged in the second conveying pipe 322, the closed end 323 of the packing auger 322 penetrates through the whole conveying pipe 322, and, the screw 323 is driven to rotate, so that the fried and fried oil is conveyed into the oil pressing cylinder 210 through the first opening 215 a.

In the working process of the feeding device 300, a user places oil in the charging barrel 311 at one time, covers the barrel cover 312 and is fixed by the fixing bolt 317, opens the heater 313, the heater 313 transfers heat from the charging barrel 311 to the oil and promotes the oil to be heated, in the process, the stirring motor 318b drives the stirring shaft 318a to rotate around the self axial direction, the first stir-frying plate 319a and the second stir-frying plate 319b synchronously rotate around the axial direction of the stirring shaft 318a and stir the oil, the oil is rapidly heated and stir-fried, when the material needs to be fed into the oil squeezing cylinder 210, the power driving device 400 drives the packing auger 323 to rotate, the oil is conveyed into the oil squeezing cylinder 210 aligned with the first opening 215a through the first conveying pipe 321 and the second conveying pipe 322, and the oil squeezing cylinder 210 sequentially circulates and is aligned with the first opening 215a and receives the feeding of the feeding device 300.

It can be known from the above that, the power driving device 400 needs to drive both the rotating shaft 214a of the rotating cylinder and the screw conveyor 323, for this purpose, the power driving device 400 is located above the oil extraction rod 230 and the residue discharge rod 240 and is opposite to the first fixing plate 211, the power driving device 400 includes a main motor 401, a first transmission shaft 403 and a second transmission shaft 404, the main motor 401 is fixedly installed on the installation frame 100 and the axial direction of the transmission shaft thereof is parallel to the axial direction of the oil extraction rod 230, the axial directions of the first transmission shaft 403 and the second transmission shaft 404 are parallel to each other and are parallel to the axial direction of the oil extraction rod 230, the end positions of the first transmission shaft 403 and the second transmission shaft 404 are both rotatably installed on the installation frame 100, a second belt transmission assembly 402 for connecting the output shaft of the main motor 401 and the rotating shaft of the screw conveyor 323 is arranged between the output shaft of the main motor 401 and the rotating, The other end of the belt transmission assembly II 402 is connected with a rotating shaft of the packing auger 323, the power on the output shaft of the main motor 401 can be transmitted to the rotating shaft of the packing auger 323 and drives the packing auger 323 to rotate around the axial direction of the belt transmission assembly II 402, and the packing auger 323 is driven through the transmission of the belt transmission assembly II 402.

Specifically, a third belt transmission assembly 405 for connecting the output shaft of the main motor 401 and the driving end of the first transmission shaft 403 is arranged between the output shaft of the main motor 401 and the driving end of the first transmission shaft 403, one end of the third belt transmission assembly 405 is connected with the output shaft of the main motor 401, the other end of the third belt transmission assembly is connected with the driving end of the first transmission shaft 403, the third belt transmission assembly 405 can transmit power on the output shaft of the main motor 401 to the first transmission shaft 403 and drive the first transmission shaft 403 to rotate around the self-axial direction, a fourth belt transmission assembly 406 for connecting the output end of the first transmission shaft 403 and the driving end of the second transmission shaft 404 is arranged between the output end of the first transmission shaft 403 and the driving end of the second transmission shaft 404, one end of the fourth belt transmission assembly 406 is connected with the driving end of the second transmission shaft 404, the fourth belt transmission assembly 406 is used for transmitting power of the first transmission shaft to the second transmission shaft 407, a driving member of the intermittent sheave transmission assembly 407 is sleeved on an output end of the second transmission shaft 404, and a driven member is sleeved on the rotating shaft 214a of the rotating cylinder, the intermittent sheave transmission assembly 407 can transmit power on the second transmission shaft 404 to the rotating shaft 214a of the rotating cylinder and drive the rotating shaft 214a of the rotating cylinder to rotate step by step, and the rotating shaft 214a of the rotating cylinder rotates one sixteenth of a week every time the second transmission shaft 404 rotates one circle, so as to achieve that the rotating cylinder 214 can rotate step by sixty degrees around its own axial direction, so that the oil cylinder 210 can be sequentially and step by step communicated with the first opening 215a, the second opening 215b, and the third opening 215 c.

In the working process of the power driving device 400, the main motor 401 is started, the belt transmission assembly II 402 transmits power on the output shaft of the main motor 401 to the screw conveyer 323 and drives the screw conveyer 323 to rotate around the axial direction of the screw conveyer 323, the screw conveyer 323 transmits fried and fried oil to the oil extracting cylinders 210 which are communicated with the first opening 215a in an aligned mode, after the oil extracting cylinders 210 are filled with a proper amount of oil, the intermittent grooved wheel transmission assembly 407 drives the rotary cylinder bodies 214 to rotate sixty degrees around the axial direction of the rotary cylinder bodies 214, the next oil extracting cylinder 210 is communicated with the first opening 215a in an aligned mode, and oil is continuously added into the oil extracting cylinders 210.

Claims (4)

1. Prepare automatic feed subassembly of stir-fry of peanut oil, its characterized in that: the heating mechanism is used for heating, frying and thoroughly frying the oil, the conveying mechanism is used for conveying the oil fried and thoroughly fried by the heating mechanism into an oil pressing cylinder/a pressing cage/a pressing bore, the heating mechanism comprises a fixed material barrel, the material barrel is of a barrel structure with an upward opening, a circular barrel cover matched with the material barrel in a covering mode is arranged at the opening of the material barrel, a heater is wrapped on the outer circumferential surface of the material barrel and is tightly attached to the outer circumferential surface of the material barrel, the heater covers the whole circumferential surface of the material barrel, and the material barrel is made of a material with good thermal conductivity;

the barrel cover is opened by up-and-down sliding of the sliding sleeve and axial rotation around the guide pillar, a fixing bolt with a knob is penetrated on the sliding sleeve along the radial sliding of the sliding sleeve, the fixing bolt and the sliding sleeve form threaded connection and can be tightly pressed or separated from the outer circular surface of the guide pillar, when the fixing bolt is tightly pressed, the sliding sleeve is fixed on the guide pillar, and when the sliding sleeve is separated from the guide pillar, the sliding sleeve moves on the guide pillar.

2. The automatic stir-fry feeding assembly of claim 1 wherein: the stirring shaft is coaxially and rotatably arranged in the charging basket, the stirring shaft extends to the opening of the charging basket from the bottom of the charging basket, a first stir-frying plate which is vertically arranged is arranged between the stirring shaft and the inner wall of the charging basket, the top of the first stir-frying plate is fixedly connected with the outer circular surface of the stirring shaft, the first stir-frying plates are four and are arranged in an array mode along the circumferential direction of the charging basket, a second stir-frying plate is further arranged between the stirring shaft and the inner wall of the charging basket, one end of the second stir-frying plate is fixedly connected with the outer circular surface of the stirring shaft, the other end of the second stir-frying plate extends to be close to the inner wall of the charging basket, the lower end face of the second stir-frying plate is attached to the bottom of the charging basket, the upper end face is obliquely arranged, the distance between the upper end face and.

3. The automatic stir-fry feeding assembly of claim 1 wherein: the barrel cover is characterized in that a stirring motor is coaxially and fixedly arranged on the upper end face of the barrel cover, an output shaft of the stirring motor movably extends to the lower portion of the barrel cover, an external spline is arranged at the top end of a stirring shaft, an output shaft of the stirring motor is arranged into a sleeve shape of an internal spline, and when the barrel cover covers the charging barrel, the stirring motor is combined with the stirring shaft.

4. The automatic stir-fry feeding assembly of claim 1 wherein: the conveying mechanism comprises a first conveying pipe and a second conveying pipe which are arranged below the charging basket, the first conveying pipe is positioned above the second conveying pipe, the output end of the second conveying pipe is arranged in an open mode, is in butt joint with the oil pressing cylinder/pressing cage/pressing bore, and is arranged in a closed mode, the first conveying pipe is arranged between the second conveying pipe and the charging basket, the input end of the first conveying pipe is in connection with the charging basket, the connection position is located at the eccentric position of the charging basket, the output end of the first output pipe is in connection with the second conveying pipe, and the connection position is close to the closed end of the second conveying, the conveying pipe II is internally coaxially and rotatably provided with an auger matched with the conveying pipe II, the auger penetrates through the whole conveying pipe II, a rotating shaft of the auger movably penetrates through the closed end of the conveying pipe II to extend outwards and is connected with a power driving device, the screw conveyer is driven to rotate, so that the fried and fried oil is conveyed to the oil pressing cylinder/pressing cage/pressing bore through the first opening.

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