CN215389747U - Multi-bacterium composite leaven production device - Google Patents

Abstract

The utility model discloses a multi-bacterium compound leavening agent production device which comprises a box body, a feeding box, a cutting mechanism, a crushing mechanism, a filtering mechanism and a grinding mechanism, wherein the feeding box is arranged on the box body; cut scattered mechanism including locating cut groove on the feeding case, can be relative cut groove upper and lower action cut the cutting knife rest, locate a plurality of cutting edges on the cutting knife rest, be used for the drive cutting knife rest upper and lower action drive assembly, locate branch on the box, locate roof on the cutting knife rest, locate adhesive tape on the roof, locate dead lever on the cutting knife rest, locate scraper blade on the dead lever, locate first torsion member and strike the subassembly on the dead lever.

Description

Multi-bacterium composite leaven production device

Technical Field

The utility model belongs to the technical field of food processing, and particularly relates to a multi-bacterium composite leaven production device.

Background

Along with economic development and social progress, people have higher and higher requirements on the flavor and the taste of flour products such as steamed bread, bread and the like, and the multi-bacterium composite leaven can endow the dough with unique flavor and taste, is superior to active dry yeast, and is popular with consumers.

The prior research on the mixed culture process parameters of a multi-bacterium composite starter fermentation tank is as follows: inoculating 1% baker's yeast, stirring at 60r/min, culturing at 25 deg.C for 7 hr, and controlling air flow at 0.26 vvm. Then respectively inoculating Hansenula anomala, lactobacillus acidophilus and lactobacillus paracasei, stirring at 60r/min, culturing at 35 ℃ for 4h, and controlling the ventilation quantity at O.11vvm. Finally stirring at 60r/min, culturing at 25 deg.C for 11h, and controlling ventilation amount at 0.26 wm. The pot pressure is kept between 0.05 and 0.06 MPa. And finally, preparing a finished product of the multi-bacterium compound leavening agent.

However, in order to mix flour and leaven for dough kneading, a pulverizer is required to pulverize the flour into fine powder, but the existing pulverizing device only uses a pulverizing paddle to pulverize the flour singly, so that the flour is easy to pulverize incompletely, block-shaped residues are caused, and the pulverizing effect is not good.

SUMMERY OF THE UTILITY MODEL

The utility model provides a multi-bacterium composite starter production device with good crushing effect in order to overcome the defects of the prior art.

In order to achieve the purpose, the utility model adopts the following technical scheme: a multi-bacteria compound leaven production device comprises a box body, a feeding box arranged on the box body, a cutting and scattering mechanism, a crushing mechanism, a filtering mechanism and a grinding mechanism; the cutting-apart mechanism comprises a cutting groove arranged on the feeding box, a cutting knife rest capable of moving up and down relative to the cutting groove, a plurality of cutting edges arranged on the cutting knife rest, a driving assembly used for driving the cutting knife rest to move up and down, a support rod arranged on the box body, a top plate arranged on the cutting knife rest, adhesive tapes arranged on the top plate, a fixed rod arranged on the cutting knife rest, a scraping plate arranged on the fixed rod, a first torsion piece arranged on the fixed rod and a knocking assembly; a cutting and scattering mechanism is arranged, the cutting knife rest moves up and down to drive a plurality of cutting edges to move synchronously, and materials falling onto the cutting groove are subjected to pre-cutting treatment, so that the materials are cut and scattered into small blocks which can pass through the cutting groove and fall, the subsequent crushing and grinding are facilitated, and the good crushing effect is ensured; cutting knife rest is down, it is down to drive the scraper blade, the scraper blade receives its tip of first torsion spare effort to hug closely the lateral wall of feeding case, scrape the material of adhesion on the lateral wall down, cutting knife rest goes upward, it goes upward to drive the roof, be equipped with an cambered surface on the roof, the cambered surface contacts branch, and slowly toward the upset of scraper blade direction, make the roof tip support on scraper blade one side and push it open, when cutting knife rest is down once more, the roof gyration, the scraper blade receives first torsion spare effort and rotates toward feeding incasement wall direction, its tip strikes and receives vibrations on the wall, can shake the material of adhesion on the scraper blade and fall.

Preferably, the driving assembly comprises a first rotating shaft arranged on the feeding box, a cam arranged on the first rotating shaft, a first driving piece used for driving the first rotating shaft to rotate, a connecting rod arranged on the cutting knife rest and a roller arranged on the connecting rod; the first driving piece is started to drive the first rotating shaft to rotate, the cam rotates synchronously, the roller abuts against the side wall of the cam, and when the cam rotates, the connecting rod is driven to move up and down, namely, the cutting knife rest is driven to move up and down, so that the material is cut and pretreated.

Preferably, the knocking component comprises a first rack arranged on the connecting rod, a second rotating shaft arranged on the feeding box, a first gear arranged on the second rotating shaft, a plurality of first rotating rods arranged on the second rotating shaft, a first fixed shaft arranged on the first rotating rod, a second rotating rod arranged on the first fixed shaft, a second torsion piece arranged on the first fixed shaft and a ball body arranged on the second rotating rod; the connecting rod moves up and down to drive the first rack to synchronously move up and down, the first gear is meshed with the first rack to enable the first gear to rotate, the second rotating shaft synchronously rotates to drive the first rotating rod and the second rotating rod to rotate, and the ball body hits and knocks the frame of the cutting groove to enable the material stopped on the cutting groove to be vibrated and fall down; when the ball body impacts the second rotating shaft on the cutting groove to continue rotating, the second rotating rod can bend around the first fixing shaft relative to the first rotating rod, and damage caused by hard impact of the second rotating rod and the cutting groove is avoided; the second torsion piece is arranged, so that after the second rotating rod is bent around the first fixed shaft relative to the first rotating rod, when the second rotating rod is separated from the cutting groove, the second rotating rod can automatically rotate and reset under the action of the second torsion piece and is in the same straight line state with the first rotating rod.

Preferably, the filtering mechanism comprises a sliding seat arranged on the box body, a filter plate arranged on the sliding seat, a first elastic piece arranged on the sliding seat, a limiting groove arranged on the sliding seat, a positioning rod arranged on the filter plate, a second elastic piece arranged on the positioning rod, a baffle plate arranged on the filter plate, a third rotating shaft arranged on the box body, an eccentric wheel arranged on the third rotating shaft, a second driving piece used for driving the third rotating shaft to rotate, a third rotating rod arranged on the second driving piece, a second fixed shaft arranged on the third rotating rod, a fourth rotating rod arranged on the second fixed shaft, a third twisting piece arranged on the second fixed shaft, a gasket arranged on the fourth rotating rod, a shifting rod arranged on the sliding seat and a collecting assembly; the second driving piece is started to drive the third rotating shaft and the eccentric wheel to rotate, the filter plate is continuously jacked up to vibrate up and down, and materials are quickly screened out and fall into the lower part of the box body; when the third rotating shaft rotates, the third rotating rod and the fourth rotating rod are driven to synchronously rotate, the deflector rod is shifted to push one sliding seat to slide relative to the box body, and after the first elastic piece is stretched, the sliding seat is pulled to slide in the direction of original state, so that the filter plate can be driven to reciprocate in the horizontal direction, the movement track of the material on the filter plate is lengthened, and the screening effect is good; set up the baffle, avoid the material granule to get into spacing groove and influence the filter plate vibrations from top to bottom.

Preferably, the collecting assembly comprises a collecting groove arranged on the box body, an arc-shaped groove arranged on the collecting groove, an arc-shaped plate arranged on the arc-shaped groove, a third elastic part arranged on the arc-shaped plate, a push plate arranged on the box body, a fourth driving part for driving the push plate to act and a cover plate part; after being filtered by the filter plate, large materials fall into the collecting tank, the fourth driving part is started to drive the push plate to move, the materials in the collecting tank can be pushed out of the box body, and the operation is convenient; the arc-shaped plate is arranged, so that when the filter plate moves up and down, the arc-shaped plate can slide relative to the collecting tank, and the situation that screening is omitted by large materials due to the fact that the materials enter a gap between the collecting tank and the filter plate when falling from the filter plate is avoided.

Preferably, the cover plate component comprises a third fixed shaft arranged on the box body, a pull rod arranged on the third fixed shaft, a fourth elastic piece arranged on the pull rod, a connecting rod arranged on the pull rod and a cover plate arranged on the connecting rod; the cover plate can be pulled away from the side wall of the box body by pulling the pull rod, and the pull rod rotates around the third fixed shaft to rotate the cover plate; after the push plate pushes the materials in the collecting tank out of the box body, the pull rod is reversely rotated, and the pull rod is pulled by the elasticity of the fourth elastic piece to enable the cover plate to be embedded into the side wall of the box body.

Preferably, the grinding mechanism comprises a fixed block arranged on the box body, a grinding block arranged on the box body, a plurality of first protrusions arranged on the grinding block, a plurality of second protrusions arranged on the fixed block, a shaft body arranged on the grinding block, a second rack arranged on the shaft body, a fourth rotating shaft arranged on the box body, a second gear arranged on the fourth rotating shaft, a fifth driving piece for driving the fourth rotating shaft to rotate and a flow guide assembly; the fifth driving piece is started to drive the fourth rotating shaft to rotate forwards and backwards at intervals, the second gear rotates synchronously, the second rack is meshed with the second rotating shaft, the second rack moves horizontally in a reciprocating mode in the horizontal direction relative to the outer side wall of the box body, the grinding block is driven to reciprocate synchronously, the side wall of the grinding block continuously collides with the fixing block, the material is ground into a first protrusion of fine powder to be matched with a second protrusion of the fine powder, and the material is extruded and crushed more completely.

Preferably, the flow guide assembly comprises a plurality of shaft cores arranged on the grinding block, a shaft sleeve arranged on the shaft cores, a buffer spring arranged on the shaft sleeve and a flow guide plate arranged on the shaft sleeve; the materials fall onto the guide plate from the filter plate, and fall between the grinding block and the fixed block along the radian of the top surface of the guide plate to avoid the materials from being accumulated on the grinding block to influence the grinding efficiency; set up buffer spring, on the material whereabouts to the guide plate, the guide plate received to strike buffer spring and is compressed and produce reverse buffering effort to the guide plate, avoids the guide plate to be damaged.

In conclusion, the cutting and scattering mechanism is arranged, the cutting knife rest moves up and down to drive the plurality of cutting edges to move synchronously, and materials falling onto the cutting groove are subjected to pre-cutting treatment, so that the materials are cut and scattered into small pieces which can pass through the cutting groove and fall, subsequent crushing and grinding are facilitated, and a good crushing effect is ensured; cutting knife rest is down, it is down to drive the scraper blade, the scraper blade receives its tip of first torsion spare effort to hug closely the lateral wall of feeding case, scrape the material of adhesion on the lateral wall down, cutting knife rest goes upward, it goes upward to drive the roof, be equipped with an cambered surface on the roof, the cambered surface contacts branch, and slowly toward the upset of scraper blade direction, make the roof tip support on scraper blade one side and push it open, when cutting knife rest is down once more, the roof gyration, the scraper blade receives first torsion spare effort and rotates toward feeding incasement wall direction, its tip strikes and receives vibrations on the wall, can shake the material of adhesion on the scraper blade and fall.

Drawings

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

Fig. 2 is an enlarged view of fig. 1 at D.

Fig. 3 is an enlarged view at G in fig. 1.

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

Fig. 5 is a right side view of fig. 4.

Fig. 6 is a cross-sectional view taken along a-a of fig. 5.

Fig. 7 is an enlarged view at E in fig. 6.

Fig. 8 is an enlarged view at F in fig. 7.

Fig. 9 is an enlarged view at H in fig. 7.

Fig. 10 is an enlarged view at J in fig. 6.

Fig. 11 is an enlarged view at L in fig. 6.

Fig. 12 is a front view of fig. 4.

Fig. 13 is a cross-sectional view taken along B-B of fig. 12.

Fig. 14 is an enlarged view at I in fig. 13.

Fig. 15 is a cross-sectional view taken along line C-C of fig. 12.

Fig. 16 is an enlarged view at K in fig. 15.

Detailed Description

As shown in fig. 1-16, a multi-bacteria compound leaven production device comprises a box body 11, a feeding box 12, a cutting mechanism, a crushing mechanism, a filtering mechanism and a grinding mechanism; the feeding box 12 is fixed on the box body 11.

Further, the scattering mechanism comprises a cutting groove 21, a cutting knife rest 22, a cutting edge 23, a driving assembly, a support rod 24, a top plate 25, a rubber strip 26, a fixing rod 27, a scraping plate 28, a first twisting piece 29 and a knocking assembly; the cutting groove 21 is fixed on the feeding box 12; the cutting knife rest 22 can move up and down relative to the cutting groove 21; a plurality of cutting edges 23 are fixed on the cutting knife rest 22 and matched with the cutting groove 21; the supporting rod 24 is fixed on the feeding box 12; one side of the top plate 25 is hinged on the cutting knife rest 22; the adhesive tape 26 is fixed on the other side of the top plate 25; the fixing rod 27 is fixedly arranged on the cutting knife rest 22 in a penetrating way; the scraper 28 is rotatably sleeved on the fixing rod 27; the first torsion element 29 is an existing torsion spring, and is sleeved on the fixing rod 27, one end of the torsion arm is fixed on the fixing rod 27, and the other end of the torsion arm is fixed on the scraper 28; the cutting knife rest 22 moves up and down to drive the plurality of cutting edges 23 to move synchronously, and the materials falling onto the cutting groove 21 are subjected to pre-cutting treatment, so that the materials are cut into small pieces which can fall through the cutting groove 21, the subsequent crushing and grinding are facilitated, and the good crushing effect is ensured; cutting knife rest 22 is down, it is down to drive scraper blade 28, scraper blade 28 receives its tip of first commentaries on classics piece 29 effort and hugs closely the lateral wall of feeding case 12, scrape the material of adhesion on the lateral wall down, cutting knife rest 22 goes upward, it goes upward to drive roof 25, be equipped with an cambered surface on the roof 25, the cambered surface contacts branch 24, and slowly toward scraper blade 28 direction upset, make roof 25 tip support on scraper blade 28 one side and push it away, when cutting knife rest 22 is down again, roof 25 gyration, scraper blade 28 receives first commentaries on classics piece 28 effort and rotates toward feeding case 12 inner wall direction, receive vibrations on its tip striking the wall, can shake the material of adhesion on scraper blade 28 and fall.

Further, the driving assembly includes a first rotating shaft 41, a cam 42, a first driving member 43, a connecting rod 44 and a roller 45; the first rotating shaft 41 is rotatably arranged on the feeding box 12 in a penetrating way; the cam 42 is fixedly sleeved on the first rotating shaft 41; the first driving member 43 is an existing motor, and is fixedly mounted on the feeding box 12 and used for driving the first rotating shaft 41 to rotate; the connecting rod 44 is fixed to the cutting blade holder 22; the roller 45 can rotate relative to the connecting rod 44; the first driving member 43 is started to drive the first rotating shaft 41 to rotate, the cam 42 synchronously rotates, the roller 45 abuts against the side wall of the cam 42, and when the cam 42 rotates, the connecting rod 44 is driven to move up and down, that is, the cutting knife rest 22 is driven to move up and down, so as to perform cutting pretreatment on the material.

Further, the knocking component comprises a first rack 51, a second rotating shaft 52, a first gear 53, a first rotating rod 54, a first fixed shaft 55, a second rotating rod 56, a second torsion element 57 and a ball 58; the first rack 51 is fixed on the connecting rod 44; the second rotating shaft 52 is rotatably arranged on the side wall of the feeding box 12 in a penetrating way; the first gear 53 is fixedly sleeved on the second rotating shaft 52; 2 first rotating rods 54 are symmetrically fixed on the second rotating shaft 52; the first fixed shaft 55 is fixedly arranged on the first rotating rod 54 in a penetrating way; the second rotating rod 56 is rotatably sleeved on the first fixed shaft 55; the second torsion element 57 is an existing torsion spring, and is sleeved on the first fixed shaft 55, one end of the torsion arm is fixed on the first fixed shaft 55, and the other end of the torsion arm is fixed on the second rotating rod 56; the ball 58 can rotate relative to the second rotating rod 56; the connecting rod 44 moves up and down to drive the first rack 51 to synchronously move up and down, the first gear 53 is meshed with the first gear, so that the first gear 53 rotates, the second rotating shaft 52 synchronously rotates to drive the first rotating rod 54 and the second rotating rod 56 to rotate, the ball 58 hits and knocks the frame of the cutting groove 21, and the material stopped on the cutting groove 21 is vibrated to fall down; when the ball 58 hits the cutting groove 21 and the second rotating shaft 52 continues to rotate, the second rotating rod 56 can bend around the first fixing shaft 55 relative to the first rotating rod 54, so that the second rotating rod 56 is prevented from being damaged due to hard impact with the cutting groove 21; the second torsion member 57 is provided so that after the second rotary lever 56 is bent around the first fixed shaft 55 relative to the first rotary lever 54, and after the second rotary lever 56 is out of contact with the cutting groove 21, the second rotary lever 56 can be automatically returned by the force of the second torsion member 57 to be in the same straight line state as the first rotary lever 54.

Further, the crushing mechanism includes a crushing roller 31, a rotating shaft 32, a sixth driving member 33, a third gear 34, and a swash plate 35; 2 rotating shafts 32 are arranged and can be rotatably arranged on the feeding box 12 in a penetrating manner; the crushing roller 31 is fixed on the rotating shaft 32, is a conventional technology, and is used for crushing materials, and is not described in detail herein; the sixth driving element 33 is an existing motor and is fixedly arranged on the side wall of the feeding box 12; 2 third gears 34 are fixedly sleeved on the rotating shaft 32 and are meshed with each other; the inclined plates 35 are symmetrically fixed on two side walls of the feeding box 12 to guide materials; the sixth driving piece 33 is started to drive the rotating shaft 32 to rotate, the two third gears 34 are meshed with each other to drive the 2 rotating shafts 32 to rotate in opposite directions, and the 2 crushing rollers 31 are driven to synchronously rotate in opposite directions to crush the materials.

Further, the filter mechanism comprises a sliding seat 61, a filter plate 62, a first elastic piece 63, a limiting groove 64, a positioning rod 65, a second elastic piece 66, a baffle 67, a third rotating shaft 68, an eccentric wheel 69, a second driving piece 610, a third rotating rod 611, a second fixed shaft 612, a fourth rotating rod 613, a third twisting piece 614, a gasket 615, a driving rod 616 and a collecting assembly; the number of the sliding seats 61 is 2, and the sliding seats can slide relative to the box body 11; the filter plate 62 can move up and down relative to the sliding seat 61 and is provided with a plurality of holes; the first elastic member 63 is an existing spring, one end of the first elastic member is fixed on the sliding seat 61, and the other end of the first elastic member is fixed on the sliding seat 61; the limiting groove 64 is formed in the sliding seat 61; the positioning rod 65 can slide relative to the limiting groove 64; the second elastic pieces 66 are 2 existing springs and are symmetrically arranged, one end of each second elastic piece is fixed on the limiting groove 64, and the other end of each second elastic piece is fixed on the positioning rod 65; the baffle 67 is fixed on the filter plate 62; the third rotating shaft 68 is rotatably arranged on the box body 11 in a penetrating way; the eccentric wheel 69 is fixedly sleeved on the third rotating shaft 68; the second driving member 610 is an existing motor, and is fixedly mounted on the box body 11, and is used for driving the third rotating shaft 68 to rotate; the third rotating rod 611 is fixed on the third rotating shaft 68; the second fixed shaft 612 is fixed on the third rotating shaft 68; the fourth rotating rod 613 is rotatably sleeved on the second fixed shaft 612; the third torsion element 614 is an existing torsion spring, and is sleeved on the second fixed shaft 612, one end of the torsion arm is fixed on the second fixed shaft 612, and the other end of the torsion arm is fixed on the fourth rotating rod 613; the washer 615 is made of rubber and fixed on one side of the fourth rotating rod 613; the driving lever 616 is fixed on one of the sliding seats 61; a slot is formed in the box body 11 and used for the driving lever 616 to slide; the second driving member 610 is started to drive the third rotating shaft 68 and the eccentric wheel 69 to rotate, so that the filter plate 62 is continuously jacked up to vibrate the filter plate 62 up and down, and the materials are quickly screened out and fall into the lower part of the box body 11; when the third rotating shaft 68 rotates, the third rotating rod 611 and the fourth rotating rod 613 are driven to synchronously rotate, the shifting lever 616 is shifted to push one of the sliding seats 61 to slide relative to the box body 11, and after the first elastic member 63 is stretched, the sliding seat 61 is pulled to slide in the direction of returning to the original state, so that the filter plate 62 can be driven to reciprocate in the horizontal direction, the movement track of the material on the filter plate 62 is lengthened, and the screening effect is good; the baffle 67 is arranged to prevent material particles from entering the limiting groove to influence the up-and-down vibration of the filter plate 62.

Further, the collecting assembly comprises a collecting groove 71, an arc-shaped groove 72, an arc-shaped plate 73, a third elastic member 74, a push plate 75, a fourth driving member 76 and a cover plate part; the collecting tank 71 is fixed on the box body 11; the arc-shaped groove 72 is formed in the collecting groove 71; one side of the arc-shaped plate 73 is hinged to one end of the filter plate 62 and can slide relative to the arc-shaped groove 72; the third elastic element 74 is an existing spring, one end of the third elastic element is fixed on the arc-shaped groove 72, and the other end of the third elastic element is fixed on the arc-shaped plate 73; the push plate 75 can slide relative to the collection groove 71; the fourth driving part 76 is an existing electric push rod, is fixedly arranged on the box body 11, and is used for driving the push plate 75 to move; after being filtered by the filter plate 62, large materials fall into the collecting tank 71, the fourth driving part 76 is started to drive the push plate 75 to move, and the materials in the collecting tank 71 can be pushed out of the box body 11, so that the operation is convenient; the arc-shaped plate 73 is arranged, so that when the filter plate 62 moves up and down, the arc-shaped plate can slide relative to the collecting groove 71, and the situation that screening is omitted due to large materials due to the fact that the materials enter a gap between the collecting groove 71 and the filter plate 62 when falling from the filter plate 62 is avoided.

Further, the cover plate component comprises a third fixed shaft 46, a pull rod 47, a fourth elastic member 48, a connecting rod 49 and a cover plate 410; the cover plate component comprises a third fixed shaft 46 fixedly arranged on the side wall of the box body 11 in a penetrating way; the pull rod 47 is slidably and rotatably sleeved on the third fixed shaft 46; the fourth elastic element 48 is an existing spring, one end of which is fixed on the box body 11, and the other end of which is fixed on the pull rod 47; the connecting rod 49 is fixed on the pull rod 47; the cover plate 410 is fixed on the connecting rod 49; the pull rod 47 is pulled to pull the cover plate 410 away from the side wall of the box body 11, and the pull rod rotates around the third fixed shaft 46 to rotate the cover plate 410 away; after the push plate 75 pushes the material in the collecting tank 71 out of the box body 11, the pull rod 47 is rotated reversely, and the pull rod 47 is subjected to the elastic force of the fourth elastic member 48 to pull the cover plate 410 to be embedded into the side wall of the box body 11.

Further, the grinding mechanism comprises a fixed block 81, a grinding block 82, a first protrusion 83, a second protrusion 84, a shaft body 85, a second rack 86, a fourth rotating shaft 87, a second gear 88, a fifth driving member 89 and a flow guide assembly; 2 fixed blocks 81 are symmetrically fixed on the box body 11; the grinding block 82 can slide in the horizontal direction relative to the box body 11; a plurality of first protrusions 83 are arranged and fixed on the grinding block 82; a plurality of second protrusions 84 are fixed on one side of the fixing block 81; the shaft 85 is fixedly arranged on the grinding block 82 in a penetrating way and can slide relative to the box body 11; the second rack 86 is fixed on the shaft 85; the fourth rotating shaft 87 is rotatably arranged on the box body 11 in a penetrating way; the second gear 88 is fixedly sleeved on the fourth rotating shaft 87; the fifth driving element 89 is an existing motor, is fixedly mounted on the box body 11, and is used for driving the fourth rotating shaft 87 to rotate; the fifth driving member 89 is started to drive the fourth rotating shaft 87 to rotate forwards and backwards at intervals, the second gear 88 rotates synchronously, the second rack 86 is meshed with the second rotating shaft, so that the second rack 86 moves horizontally in a reciprocating manner in the horizontal direction relative to the outer side wall of the box body 11 to drive the grinding block 82 to move in a reciprocating manner synchronously, the side wall of the grinding block constantly collides with the fixed block 81, the material is ground into fine powder, and the first protrusion 83 and the second protrusion 84 are matched with each other, so that the material is extruded and crushed more completely.

Further, the flow guide assembly comprises a shaft core 91, a shaft sleeve 92, a buffer spring 93 and a flow guide plate 94; a plurality of shaft cores 91 are arranged and fixed on the grinding block 82 at intervals; the shaft sleeve 92 can slide relative to the shaft core 91; the buffer spring 93 is an existing spring, one end of the buffer spring is fixed on the shaft core 91, and the other end of the buffer spring is fixed on the shaft sleeve 92; the guide plate 94 is fixed on the shaft sleeve 92 and is arc-shaped; the materials fall onto the guide plate 94 from the filter plate 62 and fall between the grinding block 82 and the fixed block 81 along the radian of the top surface of the guide plate 94 to avoid the materials from being accumulated on the grinding block 82 to influence the grinding efficiency; set up buffer spring 93, on the material whereabouts to guide plate 94, guide plate 94 received to strike buffer spring 93 and is compressed and produce reverse buffering effort to guide plate 94, avoids guide plate 94 to be damaged.

Claims (8)

1. A multi-bacteria compound fermentation agent production device comprises a box body (11), a feeding box (12) arranged on the box body (11), a cutting and scattering mechanism, a crushing mechanism, a filtering mechanism and a grinding mechanism; the method is characterized in that: cut scattered mechanism including locating cutting groove (21), can be relative on feeding case (12) cutting knife rest (22) of cutting groove (21) up-and-down motion, locate a plurality of cutting edges (23) on cutting knife rest (22), be used for the drive cutting knife rest (22) up-and-down motion's drive assembly, locate branch (24) on box (11), locate roof (25) on cutting knife rest (22), locate adhesive tape (26) on roof (25), locate dead lever (27) on cutting knife rest (22), locate scraper blade (28) on dead lever (27), locate first torsion member (29) on dead lever (27) and strike the subassembly.

2. The multi-bacteria compound leaven production device according to claim 1, characterized in that: the driving assembly comprises a first rotating shaft (41) arranged on the feeding box (12), a cam (42) arranged on the first rotating shaft (41), a first driving piece (43) used for driving the first rotating shaft (41) to rotate, a connecting rod (44) arranged on the cutting knife rest (22) and a roller (45) arranged on the connecting rod (44).

3. The multi-bacteria compound leaven production device according to claim 2, characterized in that: the knocking component comprises a first rack (51) arranged on a connecting rod (44), a second rotating shaft (52) arranged on the feeding box (12), a first gear (53) arranged on the second rotating shaft (52), a plurality of first rotating rods (54) arranged on the second rotating shaft (52), a first fixed shaft (55) arranged on the first rotating rod (54), a second rotating rod (56) arranged on the first fixed shaft (55), a second torsion piece (57) arranged on the first fixed shaft (55) and a ball body (58) arranged on the second rotating rod (56).

4. The multi-bacteria compound leaven production device according to claim 1, characterized in that: the filter mechanism comprises a sliding seat (61) arranged on the box body (11), a filter plate (62) arranged on the sliding seat (61), a first elastic piece (63) arranged on the sliding seat (61), a limit groove (64) arranged on the sliding seat (61), a positioning rod (65) arranged on the filter plate (62), a second elastic piece (66) arranged on the positioning rod (65), a baffle plate (67) arranged on the filter plate (62), a third rotating shaft (68) arranged on the box body (11), an eccentric wheel (69) arranged on the third rotating shaft (68), a second driving piece (610) used for driving the third rotating shaft (68) to rotate, a third rotating rod (611) arranged on an output shaft of the second driving piece (610), a second fixed shaft (612) arranged on the third rotating rod (611), a fourth rotating rod (613) arranged on the second fixed shaft (612), A third torsion element (614) arranged on the second fixed shaft (612), a gasket (615) arranged on the fourth rotating rod (613), a shift lever (616) arranged on the sliding seat (61) and a collection assembly.

5. The multi-bacteria compound leaven production device according to claim 4, characterized in that: the collecting assembly comprises a collecting groove (71) arranged on the box body (11), an arc-shaped groove (72) arranged on the collecting groove (71), an arc-shaped plate (73) arranged on the arc-shaped groove (72), a third elastic piece (74) arranged on the arc-shaped plate (73), a push plate (75) arranged on the box body (11), a fourth driving piece (76) used for driving the push plate (75) to move and a cover plate component.

6. The multi-bacteria compound leaven production device according to claim 5, characterized in that: the cover plate component comprises a third fixed shaft (46) arranged on the box body (11), a pull rod (47) arranged on the third fixed shaft (46), a fourth elastic piece (48) arranged on the pull rod (47), a connecting rod (49) arranged on the pull rod (47) and a cover plate (410) arranged on the connecting rod (49).

7. The multi-bacteria compound leaven production device according to claim 1, characterized in that: grind mechanism including locating fixed block (81) on box (11), locate grinding piece (82) on box (11), locate a plurality of first archs (83) on grinding piece (82), locate protruding (84) of a plurality of second on fixed block (81), locate shaft body (85) on grinding piece (82), locate second rack (86) on shaft body (85), locate fourth pivot (87) on box (11), locate second gear (88) on fourth pivot (87), be used for the drive fourth pivot (87) pivoted fifth driving piece (89) and water conservancy diversion subassembly.

8. The multi-bacteria compound leaven production device according to claim 7, characterized in that: the flow guide assembly comprises a plurality of shaft cores (91) arranged on the grinding block (82), a shaft sleeve (92) arranged on the shaft cores (91), a buffer spring (93) arranged on the shaft sleeve (92) and a flow guide plate (94) arranged on the shaft sleeve (92).

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