CN218428539U - Cereal processing grinds potato machine - Google Patents

Abstract

The utility model discloses a cereal processing grinds potato machine in cereal grinding technical field. Motor drive system's middle part meshing has the transmission that control feeding subassembly opened and close the feeding case, motor drive system's one end is installed control section ware and is carried out sliced carousel one to the sweet potato in the transportation frame under it, the internally mounted who grinds the separator box has the grinding roller that is used for carrying out the grinding to the sweet potato piece after the section. One rotation of motor drives a carousel rotation, and a carousel rotation makes fixed mounting reciprocate in the preceding section ware of carousel, drives when the section ware reciprocates that fixed mounting carries out the multistage section to the monoblock sweet potato of transporting in the transport frame under the section ware in the blade of section ware lower extreme, and the potato after the section is changeed than the monoblock potato and is ground.

Description

Cereal processing grinds potato machine

Technical Field

The utility model relates to a cereal grinds technical field, specifically is a cereal processing grinds potato machine.

Background

In extracting starch from sweet potatoes, the sweet potatoes need to be ground into powder, so a sweet potato grinding machine for grinding the sweet potatoes is needed, and the sweet potatoes need to be sliced before grinding.

For example, a sweet potato slicing device for processing dried sweet potatoes disclosed in chinese patent application No. CN201711033619.2 specifically comprises: the sweet potato is inserted and is made its location on the card needle, and during the section, the sweet potato distance antedisplacement passes through the pneumatic cylinder and drives the cutter and slice the sweet potato, and it has following problem:

the whole sweet potato can not be sliced into multiple sections at one time.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a cereal processing grinds potato machine to the unable disposable problem of carrying out the section with the monoblock sweet potato that proposes in solving above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a cereal processing grinds potato machine, is including grinding the separator box, still includes the slicing box of fixed mounting in the top of transportation frame and the feeding subassembly of intermittent type throwing in to the sweet potato.

The transportation frame is including the conveyer belt that is used for the transportation and evenly articulate the transportation frame on the conveyer belt, the right side box fixed mounting of section case has the feeding case that is used for throwing in the sweet potato to the inside of section case.

The inside mounting of slice case has the slicer that carries out the segmentation section to the whole sweet potato in the transportation frame, the inside mounting of slice case has carries out synchro-controlled motor drive system to slicer and feeding component.

The middle part of the motor transmission system is meshed with a transmission device for controlling the feeding assembly to open and close the feeding box, and one end of the motor transmission system is provided with a first rotary table for controlling the slicer to slice sweet potatoes in the transportation frame right below the slicer.

Preferably, a grinding roller for grinding the sliced sweet potato slices is installed in the grinding and separating box.

Preferably, the bottom fixed mounting of section case has the separation piece that supplies the section ware to reciprocate, the upper end fixed mounting of separation piece has the guide block that leads to the section ware, the top fixed mounting of separation piece has carries out spacing stopper to the section ware.

Preferably, one side of the first rotating disc is fixedly provided with a first fixed block for controlling the slicer to move up and down.

Preferably, a first fixing block groove for sliding the first fixing block left and right is formed in the top end of the slicer, a blade fixer for slicing whole sweet potatoes in the transportation frame is fixedly installed at the bottom end of the slicer, a second fixing block which ascends and descends on the guide block is fixedly installed on two sides of the blade fixer, and a blade which moves up and down in the separation block is installed below the blade fixer.

Preferably, transmission equipment includes the transfer line that meshes in helical gear one, the one end meshing of transfer line has carousel two, the dwang that control feeding subassembly removed about the one side of carousel two is installed, the one end movable mounting of dwang has the fixed disk of carrying out the location to feeding subassembly, just the one end horizontal slip in the fixed disk of dwang.

Preferably, the one side fixed mounting of carousel II has the fixed block three that is used for controlling the dwang to remove about in the fixed disk, the one end fixed mounting of dwang has the sliding block that controls feeding subassembly and remove, set up the sliding block groove that supplies the sliding block horizontal slip on the fixed disk.

Preferably, the feeding subassembly includes by dwang and fixed disk synchro control horizontal hunting's swinging arms, just set up on the swinging arms and supply sliding block and the gliding sliding tray of fixed axle, the one end of swinging arms articulates there is the feeding baffle that control sweet potato discontinuity was put in.

Compared with the prior art, the beneficial effects of the utility model are that:

a motor rotates to drive a rotary table to rotate, the rotary table rotates to enable the slicer arranged in front of the rotary table to move up and down, the slicer drives the blade fixedly arranged at the lower end of the slicer to slice the whole sweet potatoes transported in the transport frame under the slicer in a multi-section mode when moving up and down, and the potatoes after slicing are easier to grind than the whole potatoes.

Of course, it is not necessary for any particular product to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments are briefly introduced below, it is obvious that the drawings in the description below are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic view of the structure of the potato grinder of the present invention;

FIG. 2 is a schematic view of the structure of the grinding separation box of the present invention;

FIG. 3 is an enlarged view of the section A of FIG. 1 according to the present invention;

FIG. 4 is a left side view of the inner structure of the slicing box of the present invention;

fig. 5 is an enlarged view of fig. 4 at D according to the present invention;

fig. 6 is an enlarged view of fig. 3B according to the present invention;

FIG. 7 is a schematic structural view of the slicer of the present invention;

FIG. 8 is a top sectional view of the transmission apparatus of the present invention;

fig. 9 is a schematic structural view of the fixing plate of the present invention;

fig. 10 is a schematic top connection view of the first motor, the transmission device and the swing rod of the present invention;

fig. 11 is an enlarged view of fig. 3 according to the present invention;

fig. 12 is a schematic structural view of the motor holder of the present invention;

fig. 13 is a rear view of fig. 3 in accordance with the present invention;

fig. 14 is an enlarged view of fig. 13 at E according to the present invention.

In the drawings, the reference numbers indicate the following list of parts:

1-grinding separation box, 11-grinding roller, 12-slurry separator, 2-slicing box, 21-feeding box, 22-separation block, 221-guide block, 23-limit block, 24-motor placing rack, 241-first support block, 242-second support block, 25-third support block, 3-transport rack, 31-transport frame, 4-motor transmission system, 41-first motor, 42-first helical gear, 43-first rotary disk, 431-first fixed block, 44-transmission device, 441-transmission rod, 442-second rotary disk, 4421-third fixed block, 4422-second connecting rod, 443-rotating rod, 4431-sliding block, 444-fixed disk, 4441-sliding block groove, 4442-fixed shaft, 5-slicer, 50-first connecting rod, 51-first fixed block groove, 52-blade holder, 521-second fixed block, 522-blade, 6-feeding component, 61-swinging rod, 611-sliding groove, 62-feeding baffle.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Example one

Referring to fig. 1-6, the present invention provides a technical solution: a grain processing potato mill, in particular to a potato mill for slicing and grinding sweet potatoes. Wherein contain and grind separator box 1, section case 2 and transportation frame 3, and grind separator box 1, section case 2 and transportation frame 3 and install in grinding potato machine incasement portion, grind separator box 1 and install the left side at grinding potato machine case, and grind and set up the slag notch and the play thick liquid mouth that align with grinding separator box 1 on the machine case. The transportation frame 3 is fixedly arranged on the inner wall of the box body in the middle of the potato grinding machine box, and the slicing box 2 is arranged above the transportation frame 3.

Sweet potato after the section in section case 2, transmit to grinding separator box 1 in through transportation frame 31, fixed mounting has the motor on the grinding separator box 1, the internally mounted who grinds separator box 1 has the grinding roller 11 that is used for carrying out the grinding to the sweet potato piece after the section, the starter motor, make grinding roller 11 rotate through the belt, grinding roller 11 rotates the sweet potato piece after will slicing in section case 2 and grinds into behind the powder and fall into in sediment thick liquid separator 12, slag notch and play thick liquid mouth have been seted up to the tank wall of sediment thick liquid separator 12, make the sweet potato sediment after the grinding discharge from the slag notch, the powder thick liquid after the grinding is discharged from a thick liquid mouth.

The conveying belt for conveying is installed on the conveying frame 3, the conveying belt is evenly hinged with a conveying frame 31, and an opening is formed in the upper portion of the conveying frame 31. The both sides of conveyer belt are evenly installed and are used for the fixed block that cup joints with one side of transportation frame 31, and transportation frame 31 overturns around transportation frame 3 along the direction of conveyer belt motion. So that the transport frame 31 can be turned over along the hinge joint when passing the left edge of the transport frame 3, the sweet potato slices in the transport frame 31 are conveyed into the grinding and separating box 1, and the transport frame 31 is turned over into a state with an upward opening when passing the right edge of the transport frame 3. When the transportation frame 31 enters the slicing box 2, the whole sweet potatoes fixedly installed in the right box body feeding box 21 of the slicing box 2 fall into the transportation frame 31, the transportation frame 31 continues to move towards the other side of the box body of the slicing box 2, when the transportation frame moves to the position below the slicer 5, the slicer 5 cuts the whole sweet potatoes in the transportation frame 31 to enable the whole sweet potatoes to be cut into slices, the slices are finally transmitted to the grinding separation box 1, and the transportation frame 31 installed on the transportation frame 3 repeats the above movement.

Slice case 2 fixed mounting has the slicer 5 that carries out the section to the monoblock sweet potato in the transportation frame 31, has still installed the feeding subassembly 6 that carries out the discontinuity to the sweet potato and put in the top on transportation frame 3, the internally mounted of slice case 2. And slicer 5 and infeed assembly 6 are controlled synchronously by motor drive system 4. When transport frame 31 is under slicer 5, slicer 5 begins to cut the monoblock sweet potato in transport frame 3, feeding component 6 is from the state with feeding case 21 shutoff simultaneously, become to become the open mode with feeding case 21, the monoblock sweet potato that is in feeding case 21 entrance begins to fall in to being in feeding case 21 bottom exit to transport frame 31, slicer 5 is to the monoblock sweet potato cutting completion back in the transport frame 31, feeding component 6 becomes the state with feeding case 21 shutoff, the monoblock sweet potato that makes the entrance that is in feeding case 21 can not fall.

The inside antetheca of box of slicer case 2 has installed the separation piece 22 that scrapes the sweet potato piece that pastes on slicer 5, and the inside antetheca of box of slicer case 2 has installed the stopper 23 that carries on spacingly to the upper end of slicer 5, and the inside antetheca of box of slicer case 2 has still installed the motor rack 24 that is used for placing motor 41, and has fixedly installed the supporting shoe 241 that is used for supporting the transfer line of motor 41 output and is used for supporting the supporting shoe two 242 that transmission 44 is close to helical gear 42 one end on the motor rack 24.

The motor transmission system 4 comprises a first motor 41, a first bevel gear 42, a first rotating disk 43 and a transmission device 44. The first motor 41 is fixed on the motor placing frame 24, a first bevel gear 42 meshed with the transmission device 44 is fixedly installed in the middle of an output shaft installed at the output end of the first motor 41, a first rotating disc 43 is connected to the top end of the output shaft of the transmission device 44, a first fixing block 431 is fixedly installed on the front face of the first rotating disc 43, and the first fixing block 431 can drive the slicer 5 to move up and down.

When 41 starts, it is rotatory to drive carousel 43, carousel 43 drives and is fixed in the positive fixed block 431 of carousel 43 and rotates, fixed block 431 rotates to drive and cup joints and reciprocates in the slicer 5 of fixed block 431 in order to cut the monoblock sweet potato in the transportation frame 31, the back is accomplished in the cutting, can follow articulated department when the transport frame 31 reaches the left side edge of transportation frame 3 along the direction of delivery of conveyer belt and overturn, carry the sweet potato piece in the transportation frame 31 to grinding separation incasement 1. The grinding roller 11 rotates to grind the sweet potato chips in the conveying frame 31 into powder and then fall into the residue-slurry separator 12, and a slag outlet and a slurry outlet are formed in the wall of the residue-slurry separator 12, so that the ground sweet potato residues are discharged from the slag outlet, and the ground powder slurry is discharged from the slurry outlet.

Example two

Based on the motor drive system 4 that embodiment one provided, the utility model discloses still provide slicer 5 and feeding component 6's further scheme.

Referring to fig. 1 and 5-14, slicer 5 of the present invention further provides a first fixed block slot 51 and a blade holder 52.

A groove for the first fixing block 431 to slide is formed in the middle of the first fixing block groove 51, when the first rotating disc 43 rotates to drive the first fixing block 431 to rotate, the first fixing block 431 slides left and right in the groove formed in the middle of the first fixing block groove 51, and the first fixing block 431 drives the slicer 5 to move up and down.

The first fixing block groove 51 is fixedly connected to the upper end of the first connecting rod 50, the lower end of the first connecting rod 50 is fixedly connected with a blade fixer 52, a blade 522 moving up and down in the separating block 22 is installed at the bottom of the blade fixer 52, and the blade 522 slices the whole sweet potatoes in the transportation frame 31. The second fixing blocks 521 are fixedly mounted on the left side and the right side of the blade holder 52, a groove with the same size as the guide block 221 is formed in the middle of the second fixing blocks 521, and the second fixing blocks 521 move up and down on the guide block 221. Because each 522 arranged at the bottom of 52 is arranged in a linear array, when the whole sweet potato is sliced, the 522 can synchronously slice the sweet potato from a plurality of places, so that the whole sweet potato is cut into a plurality of slices, namely the multi-section slicing of the whole sweet potato is completed. The sliced sweet potato slices are smaller in size than whole sweet potatoes and are therefore more easily ground by the grinding rollers 11.

The transmission device 44 engaged with the first bevel gear 42 comprises a transmission rod 441, a second rotary disk 442, a rotating rod 443 and a fixed disk 444.

The left end of the transmission rod 441 is meshed with a first bevel gear 42 arranged in the middle of an output shaft of a first motor 41, a second supporting block 242 used for supporting the transmission rod 441 is further arranged at the left end of the transmission rod 441, the second supporting block 242 is fixedly arranged on the motor placing frame 24, a third supporting block 25 used for supporting and limiting the transmission rod 441 is further arranged at the right end of the transmission rod 441, and the third supporting block 25 is arranged on the rear wall inside the box body of the slice box 2. The right bevel gear of the transmission rod 441 is meshed with the second rotating disc 442, the second connecting rod 4422 is installed in the middle of the second rotating disc 422, the front end of the second connecting rod 4422 is connected into the second rotating disc 442, the rear end of the second connecting rod 4422 is connected onto the rear wall of the interior of the slicing box 2, the second rotating disc 442 and the second connecting rod 4422 are concentric circles, a third fixing block 4421 is fixedly installed in front of the second rotating disc 442, the third fixing block 4421 is hinged to the rotating rod 443, and the third fixing block 4421 drives the right end of the rotating rod 443 to slide left and right in a sliding block groove 4441 formed in the fixed disc 444. The right end of the rotating rod 443 is fixedly connected with a sliding block 4431 moving left and right in a sliding block groove 4441 formed in the fixed disk 444, the middle part of the fixed disk 444 is provided with a fixed shaft 4442, the front end of the fixed shaft 4442 is connected in the fixed disk 444, the rear end of the fixed shaft 4442 is connected on the rear wall in the box body of the slicing box 2, and the fixed disk 444 and the fixed shaft 4442 are concentric circles.

The slide block 4431 and the fixed shaft 4442 are disposed in a slide groove 611 formed in the swing lever 61.

After a first motor 41 fixedly arranged on the motor placing frame 24 is started, an output shaft arranged at the output end of the first motor 41 starts to rotate, and the output shaft rotates to drive a first bevel gear 42 and a first rotating disc 43 to synchronously rotate. The first bevel gear 42 rotates to drive the transmission rod 441, the transmission rod 441 rotates to drive the second rotating disk 442 meshed with the transmission rod 441 to rotate, the left end of the rotating rod 443 sleeved on the third fixed block 4421 rotates circumferentially around the center of the second rotating disk 442, and meanwhile, the sliding block 4431 fixedly installed at the right end of the rotating rod 443 moves leftwards in the sliding block groove 4441. When the slide block 4431 moves leftward, the lower end of the swing lever 61 is rotated about the fixed shaft 4442, and when the swing lever 61 rotates, the fixed shaft 4442 and the slide block 4431 move in the slide groove 611 formed in the swing lever 61. When the sliding block 4431 moves to the leftmost side of the sliding block groove 4441, the feeding baffle plate 62 hinged to one end of the swinging rod 61 moves rightwards to enter the feeding box 21, so that the whole sweet potatoes located at the inlet of the feeding box 21 cannot fall down, and when the sliding block 4431 moves to the right side of the sliding block groove 4441, the feeding baffle plate 62 moves leftwards to enter the feeding assembly 6, and the whole sweet potatoes located at the inlet of the feeding box 21 fall down into the transport frame 31 located at the outlet of the feeding box 21.

The first rotating disc 43 which synchronously rotates with the first bevel gear 42 drives the first fixed block 431 fixed on the front surface of the first rotating disc 43 to rotate, and the first fixed block 431 drives the slicer 5 sleeved on the first fixed block 431 to move up and down so as to cut the whole sweet potatoes in the transportation frame 31. When the slicer 5 cuts the whole sweet potato in the transportation frame 31, the feeding baffle plate 62 moves leftwards to enter the feeding assembly 6, and the feeding box 21 puts the whole sweet potato in the transportation frame 31. When the slicer 5 finishes cutting and rises upwards, the feeding baffle plate 62 moves rightwards to enter the feeding box 21, so that the whole sweet potato at the inlet of the feeding box 21 cannot fall into the conveying frame 31.

After the cutting, the transport frame 31 can be turned over along the hinge joint when reaching the left edge of the transport frame 3 along the transport direction of the conveyor belt, and the sweet potato slices in the transport frame 31 are transported into the grinding and separating box 1. The grinding roller 11 rotates to grind the sweet potato chips in the conveying frame 31 into powder and then fall into the residue-slurry separator 12, and a slag outlet and a slurry outlet are formed in the wall of the residue-slurry separator 12, so that the ground sweet potato residues are discharged from the slag outlet, and the ground powder slurry is discharged from the slurry outlet.

In the foregoing, exemplary embodiments of the proposed solution have been described in detail with reference to preferred embodiments, however, it will be understood by those skilled in the art that various modifications and variations can be made to the above specific embodiments without departing from the concept of the present invention, and various combinations of the various technical features and structures proposed by the present invention can be made without departing from the scope of the present invention, which is defined by the appended claims.

Claims (7)

1. The utility model provides a cereal processing grinds potato machine, includes grinding separator box (1), its characterized in that: the sweet potato slicing machine also comprises a slicing box (2) fixedly arranged above the transport frame (3) and a feeding assembly (6) for discontinuously feeding sweet potatoes;

the conveying frame (3) comprises a conveying belt for conveying and a conveying frame (31) which is uniformly hinged to the conveying belt, and a feeding box (21) for feeding sweet potatoes into the slicing box (2) is fixedly mounted on the right box body of the slicing box (2);

a slicer (5) for slicing the whole sweet potatoes in the conveying frame (31) in a segmented manner is arranged in the slicing box (2), and a motor transmission system (4) for synchronously controlling the slicer (5) and the feeding assembly (6) is arranged in the slicing box (2);

the middle part of the motor transmission system (4) is meshed with a transmission device (44) for controlling the feeding assembly (6) to open and close the feeding box (21), and one end of the motor transmission system (4) is provided with a first rotary table (43) for controlling the slicer (5) to slice sweet potatoes in the transportation frame (31) right below the slicer.

2. The grain processing potato mill of claim 1, wherein: the bottom fixed mounting of section case (2) has separation piece (22) that supplies section ware (5) to reciprocate, the upper end fixed mounting of separation piece (22) has guide block (221) that carry out the direction to section ware (5), the top fixed mounting of separation piece (22) has carries out spacing stopper (23) to section ware (5).

3. The grain processing potato mill of claim 1, wherein: one surface of the first rotating disc (43) is fixedly provided with a first fixed block (431) for controlling the slicer (5) to move up and down.

4. The grain processing potato mill of claim 3, wherein: the utility model discloses a potato slicer, including slicer (5), slicer, blade fixer, guide block (221), blade fixer, blade (522) that reciprocates in separation piece (22) are installed to the both sides fixed mounting of blade fixer (52), the top of slicer (5) is seted up and is supplied fixed block one (431) horizontal slip's fixed block groove (51), the bottom fixed mounting of slicer (5) has carries out sliced blade fixer (52) to the monoblock sweet potato in transporting frame (31), the both sides fixed mounting of blade fixer (52) has fixed block two (521) of going up and down on guide block (221), blade (522) of reciprocating in separation piece (22) are installed to the below of blade fixer (52).

5. The grain processing potato mill of claim 1, wherein: the transmission device (44) comprises a transmission rod (441) meshed with the first bevel gear (42), one end of the transmission rod (441) is meshed with a second rotary table (442), one surface of the second rotary table (442) is provided with a rotary rod (443) for controlling the feeding assembly (6) to move left and right, one end of the rotary rod (443) is movably provided with a fixed disk (444) for positioning the feeding assembly (6), and one end of the rotary rod (443) slides left and right in the fixed disk (444).

6. The grain processing potato mill of claim 5, wherein: and a fixed block III (4421) used for controlling the rotating rod (443) to move left and right in the fixed disc (444) is fixedly arranged on one surface of the rotating disc II (442), a sliding block (4431) used for controlling the feeding assembly (6) to move left and right is fixedly arranged at one end of the rotating rod (443), and a sliding block groove (4441) for allowing the sliding block (4431) to slide left and right is formed in the fixed disc (444).

7. The grain processing potato mill of claim 6, wherein: the feeding assembly (6) comprises a swinging rod (61) synchronously controlled to swing left and right by a rotating rod (443) and a fixed disk (444), a sliding groove (611) for a sliding block (4431) and a fixed shaft (4442) to slide is formed in the swinging rod (61), and a feeding baffle (62) for controlling intermittent throwing of sweet potatoes is hinged to one end of the swinging rod (61).

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