CN110961178A - Convenient milling equipment for vegetable and fruit ferment of adjusting - Google Patents

Abstract

The invention relates to the technical field of vegetable and fruit enzyme production equipment, in particular to milling equipment for vegetable and fruit enzyme, which is convenient to adjust; a servo motor is adopted to drive a first rotating shaft to rotate, so that a first cylindrical cam rotates along with the first cylindrical cam, a second connecting rod drives a blocking plate to move left and right, and therefore the bottom outlet of the material storage cavity is blocked or opened, and intermittent blanking is carried out; meanwhile, the bending rod moves along with the second connecting rod, and the third connecting rod drives the fourth connecting rod to move along the direction of the sliding chute through the matching of the sliding shaft and the straight hole, so that the upper grinding plate moves in a reciprocating manner and is matched with the lower grinding assembly below to grind the ferment block; the gap between the upper grinding plate and the lower grinding plate is convenient to adjust, the adjusting screw rod is rotated through the hand wheel, the moving nut drives the seven connecting rods to move through the six connecting rods, so that the wedge block moves leftwards or rightwards, the lower grinding plate moves upwards or downwards due to the matching of the inclined surface of the wedge block and the three rollers, the gap between the upper grinding plate and the lower grinding plate is changed, and the size of ground particles is adjusted.

Description

Convenient milling equipment for vegetable and fruit ferment of adjusting

Technical Field

The invention relates to the technical field of vegetable and fruit enzyme production equipment, in particular to grinding equipment for vegetable and fruit enzymes, which is convenient to adjust.

Background

Enzymes are defined as: the product containing specific biological activity is prepared by taking animals, plants, fungi and the like as raw materials and performing microbial fermentation. Its action is similar to that of an "enzyme".

Enzymes (enzymes) are proteins or RNAs produced by living cells with high specificity and high catalytic efficiency for their substrates. The catalytic action of enzymes depends on the integrity of the primary structure and spatial structure of the enzyme molecule. If the enzyme molecule is denatured or the subunits are depolymerized, the enzyme activity may be lost. The enzyme belongs to biological macromolecules, the molecular mass is at least more than 1 ten thousand, and the molecular mass can reach millions.

Enzymes are a very important class of biocatalysts (biochatalysts). Due to the action of enzymes, chemical reactions in organisms can be efficiently and specifically carried out under extremely mild conditions.

The chemical nature of an enzyme is protein or RNA (Ribonucleic acid), and thus it also has a primary, secondary, tertiary, or even quaternary structure. According to their molecular composition, they can be classified into simple enzymes and conjugated enzymes. Proteins alone are called simplex enzymes; the binding enzyme is composed of an enzyme protein and a cofactor. For example, most hydrolases consist solely of proteins; the flavin mononucleotidase consists of an enzyme protein and a cofactor. The enzyme protein in the combined enzyme is a protein part, the cofactor is a non-protein part, and the enzyme protein and the cofactor have catalytic activity only when the enzyme protein and the cofactor are combined into a whole enzyme.

The enzyme has similar action to the enzyme, and most of the enzyme is a mixed fermentation substance which is prepared by taking fresh vegetables, fruits, brown rice, medicinal and edible traditional Chinese medicines and other plants as raw materials, juicing or extracting a series of processes, and then adding yeast, lactobacillus and other fermentation strains for fermentation and contains abundant nutrient components such as saccharides, organic acids, mineral substances, vitamins, phenols, terpenoids and other important biological active substances such as enzymes.

Nowadays, the enzyme market is increasingly developed, and the demand is continuously increased. The ferment generally has two product forms, namely powder and beverage, wherein the ferment is easy to be hardened and agglomerated during production and needs to be crushed into powder so as to be convenient for eating or dissolving into beverage.

Chinese patent No. CN201810018178.7 discloses a two-stage pulverizing device for producing ferment of vegetable and fruit, which comprises a screw conveyor for primarily pulverizing and guiding ferment, an upper grinding plate and a lower grinding plate for guiding the primarily pulverized ferment, and a rotary table rotating to intermittently act on a push plate of the upper grinding plate and the expansion plate, thereby moving the upper grinding plate relative to the lower grinding plate, performing secondary grinding, and automatically guiding to fall down.

In fact, the main reason for determining the size of the ferment particles is concentrated at the secondary grinding position, and the distance between the upper and lower grinding plates in the above patent is fixed, so that the size of the ground particles is also fixed, which results in the problem of single product specification; and the upper grinding plate is only fixed by the slot at the left end, the running stability is also general, and improvement is needed.

Disclosure of Invention

Technical problem to be solved

The invention aims to overcome the defects in the prior art and provide the grinding equipment for the vegetable and fruit ferment, which is convenient to adjust.

(II) technical scheme

A grinding device for vegetable and fruit ferment convenient to adjust comprises a frame, a blanking component, an upper grinding component and a lower grinding component;

the frame comprises a bottom plate, a left side plate, a right side plate, a material storage cavity, a first support rod, a grinding cavity, a second support rod and a material receiving box, wherein the left end and the right end of the base are fixedly connected with the left side plate and the right side plate respectively; an upper grinding assembly and a lower grinding assembly are arranged above and below the grinding cavity; the material receiving box is arranged below the milling cavity.

Preferably, the blanking assembly comprises a servo motor, a first rotating shaft, a first cylindrical cam, a first roller, a first connecting rod, a second connecting rod and a plugging plate;

the top of the left side plate is connected with a first support plate rightwards, the right end of the first support plate is connected with a second support plate downwards, a first rotating shaft is arranged between the second support plate and the left side plate, and the left end of the first rotating shaft is externally connected with a servo motor; a first cylindrical cam is arranged on the first rotating shaft, the first cylindrical cam is matched with a first roller, the first roller is downwards connected with a first connecting rod, and the first connecting rod is rightwards connected with a second connecting rod; the left end of the top of the grinding cavity is provided with a third support plate, a second connecting rod horizontally penetrates through the third support plate and is connected with a plugging plate, and the plugging plate is matched with an outlet at the bottom of the storage cavity.

Preferably, the upper grinding assembly comprises a bending rod, a sliding shaft, a third connecting rod, a straight hole, a fourth connecting rod, a fifth connecting rod, a first-class sliding block, a second material guide plate, an upper grinding plate and a supporting rod;

the upper grinding plate is obliquely arranged in the grinding cavity in a manner of being lower at the left side and higher at the right side; the right end of the upper grinding plate is connected with a second material guide plate, and the left side of the second material guide plate is connected with a fourth connecting rod; the bottom of the fourth connecting rod is fixedly connected with the upper grinding plate through a supporting rod, a plurality of fifth connecting rods are uniformly and symmetrically arranged on the front side and the rear side of the fourth connecting rod, and first-class sliding blocks are arranged at the outer ends of the fifth connecting rods; the front side wall and the rear side wall of the grinding cavity are provided with sliding chutes, and the first class sliding blocks are clamped into the sliding chutes and are in sliding fit with the sliding chutes; the sliding chute, the fourth connecting rod and the upper grinding plate are arranged in parallel; the fourth connecting rod is upwards connected with a third connecting rod, and a straight hole is formed in the third connecting rod; the bottom of the second connecting rod is connected with a bending rod, a sliding shaft is arranged on the bending rod, and the sliding shaft is matched with the straight hole.

Preferably, the bottom of the storage cavity is aligned with the right part of the grinding cavity; a first material guide plate with a lower left part and a higher right part is arranged at the right part of the grinding cavity; the left part of the grinding cavity is provided with a baffle plate which is higher than the left end of the upper grinding plate.

Preferably, the lower grinding assembly comprises a hand wheel, an adjusting screw, a moving nut, a number six connecting rod, a number seven connecting rod, a wedge block, a number three roller, a number eight connecting rod, a lower grinding plate, a number two sliding block and a number one sliding rail;

the lower grinding plate is arranged below the upper grinding plate and is parallel to the upper grinding plate; a second sliding block is arranged at the right end of the lower grinding plate and is positioned below the first material guide plate; a first sliding rail is arranged on the right side wall of the grinding cavity, and a second sliding block is connected with the first sliding rail in a sliding manner; an adjusting screw is rotatably arranged between the grinding cavity and the right side plate, and a hand wheel is externally connected at the right end of the adjusting screw; a movable nut is screwed on the adjusting screw rod, the movable nut is downwards connected with a sixth connecting rod, the sixth connecting rod is leftwards connected with a seventh connecting rod, and the seventh connecting rod extends into the milling cavity and is connected with a wedge block; the lower grinding plate is connected with a third roller downwards through an eighth connecting rod, and the third roller is matched with the inclined plane at the top of the wedge-shaped block.

Preferably, the wedge-shaped blocks are arranged at intervals along the seven connecting rods, and the eight connecting rods are correspondingly arranged.

Preferably, the first slide rail is a T-shaped slide rail, and the second slide rail is a corresponding C-shaped slide rail; the opposite surfaces of the upper grinding plate and the lower grinding plate are provided with grinding bulges.

Preferably, the grinding device further comprises a vibration component, wherein the vibration component is arranged on the left side of the grinding cavity and comprises a second rotating shaft, a second cylindrical cam, a second roller, a rocker, a collision end, a first driving wheel, a driving belt and a second driving wheel;

a second rotating shaft is rotatably connected between the grinding cavity and the left side plate; a second driving wheel is arranged at the left section of the second rotating shaft, a first driving wheel is correspondingly arranged on the first rotating shaft, and the first driving wheel and the second driving wheel are in transmission connection through a transmission belt; a second cylindrical cam is arranged at the right section of the second rotating shaft, a second roller is matched with the second cylindrical cam, and the second roller is arranged at the top end of the rocker; crocus chamber left side still is connected with No. three branch, and rocker middle section and No. three branch are articulated, and the rocker bottom is provided with the collision end.

Preferably, the material receiving device further comprises a material receiving assembly, wherein the material receiving assembly is arranged below the material receiving box and comprises a second sliding rail, a third sliding block, a moving plate, a first spring, a first wire guide wheel and a first pull rope;

the material receiving box is arranged on the movable plate, the bottom of the movable plate is provided with a third sliding block, the bottom plate is provided with a second sliding rail, and the third sliding block is connected with the second sliding rail in a sliding manner; a first spring is connected between the moving plate and the right side plate; the base corresponds the movable plate left side and is provided with the wire wheel No. one, and the movable plate left end is connected with the stay cord No. one, and the stay cord is walked around the wire wheel No. one and is connected with the rocker.

Preferably, the wire drawing machine further comprises a material passing assembly, wherein the material passing assembly comprises a second pull rope, a second wire guide wheel, an end plate, a moving rod, a dredging end, a second spring, a take-up pulley, a driven gear, a mounting rod and a rack;

the middle part of the first connecting rod is connected with a rack rightwards; the right side of the second support plate is connected with an installation rod, the right end of the installation rod is provided with a driven gear, and the driven gear is matched with the rack; the driven gear is coaxially provided with a take-up pulley which is connected with a second pull rope; the top of the material storage cavity is provided with an opening, an ejector rod is arranged between the openings, and the middle part of the ejector rod is provided with a sleeve; the movable rod penetrates through the sleeve, the top end of the movable rod is provided with an end plate, and the bottom end of the movable rod is provided with a dredging end; a second spring is arranged between the end plate and the top of the sleeve; the left side of the material storage cavity is provided with a second wire guide wheel, and a second pull rope is wound around the second wire guide wheel and connected with the end plate.

(III) advantageous effects

The invention provides milling equipment for vegetable and fruit enzyme, which is convenient to adjust and has the following advantages:

1, a servo motor is adopted to drive a first rotating shaft to rotate, so that a first cylindrical cam rotates along with the first rotating shaft, a second connecting rod drives a blocking plate to move left and right, and therefore an outlet at the bottom of a material storage cavity is blocked or opened, and intermittent blanking is carried out; the bending rod moves along with the second connecting rod, the third connecting rod drives the fourth connecting rod to move along the sliding groove direction through the matching of the sliding shaft and the straight hole, and then the upper grinding plate moves in a reciprocating mode to be matched with the lower grinding assembly below to grind the ferment block.

2, the gap between the upper grinding plate and the lower grinding plate is convenient to adjust, the adjusting screw rod is rotated through the hand wheel, the moving nut drives the seven connecting rods to move through the six connecting rods, so that the wedge block moves leftwards or rightwards, the lower grinding plate moves upwards or downwards due to the matching of the inclined surface of the wedge block and the three rollers, the gap between the upper grinding plate and the lower grinding plate is changed, and the size of ground particles is adjusted.

3, still set up and shake the material subassembly, when utilizing pivot pivoted, still take No. two pivot rotations through the drive wheel transmission, No. two cylinder cams then rotate, make the rocker take place to sway to take the collision end to beat the grinding chamber, make the grinding chamber left part vibrations, unloading with higher speed.

4, still set up the logical material subassembly, utilize the rack to remove along with a connecting rod is controlled, make driven gear receive the rack promptly and take place just reversing to make the take-up pulley also follow just reversing and receive the unwrapping wire, cooperate No. two springs, and then make the carriage release area dredge the end and reciprocate and dredge, take place to block up when preventing the unloading of storage cavity.

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 will be briefly introduced below, and it is obvious that the drawings in the following description are only for the present invention and protect some embodiments, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a block diagram of the present invention;

FIG. 2 is a block diagram of one embodiment of the present invention;

FIG. 3 is a block diagram of a blanking assembly;

FIG. 4 is a structural view of a grinding chamber;

FIG. 5 is a block diagram of the upper grinding assembly;

FIG. 6 is a perspective view of the upper grinding assembly;

FIG. 7 is a block diagram of a lower grinding assembly;

FIG. 8 is a block diagram of the seismic component;

fig. 9 is a structural view of the receiving assembly;

FIG. 10 is a block diagram of the feed assembly;

in the drawings, the components represented by the respective reference numerals are listed below:

1-frame, 101-bottom plate, 102-left side plate, 103-right side plate, 104-first support plate, 105-second support plate, 106-material storage cavity, 1061-ejector rod, 1062-sleeve, 107-first support rod, 108-grinding cavity, 1081-third support plate, 1082-chute, 1083-first guide plate, 1084-baffle plate, 1085-third support rod, 109-second support rod and 110-material receiving box;

2-blanking component, 201-servo motor, 202-first rotating shaft, 203-first cylindrical cam, 204-first roller, 205-first connecting rod, 206-second connecting rod and 207-blocking plate;

3-upper grinding component, 301-bending rod, 302-sliding shaft, 303-third connecting rod, 304-straight hole, 305-fourth connecting rod, 306-fifth connecting rod, 307-first type sliding block, 308-second guide plate, 309-upper grinding plate and 310-grinding projection;

4-a lower grinding assembly, 401-a hand wheel, 402-an adjusting screw rod, 403-a moving nut, 404-a sixth connecting rod, 405-a seventh connecting rod, 406-a wedge block, 407-a third roller, 408-an eighth connecting rod, 409-a lower grinding plate, 410-a second sliding block and 411-a first sliding rail;

5-vibration component, 501-second rotating shaft, 502-second cylindrical cam, 503-second roller, 504-rocker, 505-collision end, 506-first transmission wheel, 507-transmission belt and 508-second transmission wheel;

6-material receiving assembly, 601-second slide rail, 602-third slide block, 603-moving plate, 604-first spring, 605-first guide wheel and 606-first pull rope;

8-a material passing component, 801-a second pull rope, 802-a second wire guide wheel, 803-an end plate, 804-a movable rod, 805-a dredging end, 806-a second spring, 807-a wire take-up wheel, 808-a driven gear, 809-a mounting rod and 810-a rack.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that, as the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. appear, their indicated orientations or positional relationships are based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Moreover, the terms "first," "second," and "third," if any, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" should be interpreted broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1

A milling equipment for vegetable and fruit ferment convenient to adjust comprises a frame 1, a blanking component 2, an upper milling component 3 and a lower milling component 4;

the frame 1 comprises a bottom plate 101, a left side plate 102, a right side plate 103, a material storage cavity 106, a first support rod 107, a grinding cavity 108, a second support rod 109 and a material receiving box 110, wherein the left end and the right end of the base 101 are fixedly connected with the left side plate 102 and the right side plate 103 respectively, the left side of the top of the right side plate 103 is connected with the material storage cavity 106 through the first support rod 107, a blanking assembly 2 is arranged below the material storage cavity 106, the grinding cavity 108 is arranged below the blanking assembly 2, and is fixedly connected with the right side plate 103 through the second support rod 109; the upper grinding component 3 and the lower grinding component 4 are arranged above and below the grinding cavity 108; a hopper 110 is provided below the grinding chamber 108.

Example 2

A milling equipment for vegetable and fruit ferment convenient to adjust comprises a frame 1, a blanking component 2, an upper milling component 3 and a lower milling component 4;

the frame 1 comprises a bottom plate 101, a left side plate 102, a right side plate 103, a material storage cavity 106, a first support rod 107, a grinding cavity 108, a second support rod 109 and a material receiving box 110, wherein the left end and the right end of the base 101 are fixedly connected with the left side plate 102 and the right side plate 103 respectively, the left side of the top of the right side plate 103 is connected with the material storage cavity 106 through the first support rod 107, a blanking assembly 2 is arranged below the material storage cavity 106, the grinding cavity 108 is arranged below the blanking assembly 2, and is fixedly connected with the right side plate 103 through the second support rod 109; the upper grinding component 3 and the lower grinding component 4 are arranged above and below the grinding cavity 108; a hopper 110 is provided below the grinding chamber 108.

The blanking assembly 2 comprises a servo motor 201, a first rotating shaft 202, a first cylindrical cam 203, a first roller 204, a first connecting rod 205, a second connecting rod 206 and a blocking plate 207;

a first support plate 104 is connected to the top of the left side plate 102 rightwards, a second support plate 105 is connected to the right end of the first support plate 104 downwards, a first rotating shaft 202 is arranged between the second support plate 105 and the left side plate 102, and a servo motor 201 is externally connected to the left end of the first rotating shaft 202; a first cylindrical cam 203 is arranged on the first rotating shaft 202, the first cylindrical cam 203 is matched with a first roller 204, the first roller 204 is downwards connected with a first connecting rod 205, and the first connecting rod 205 is rightwards connected with a second connecting rod 206; the left end of the top of the grinding cavity 108 is fixedly connected with a third support plate 1081, a second connecting rod 206 horizontally penetrates through the third support plate 1081 and is connected with a blocking plate 207, and the blocking plate 207 is matched with an outlet at the bottom of the material storage cavity 106.

Specifically, start servo motor 201 drive pivot 202 and rotate, make a cylindrical cam 203 follow and rotate, because the channel cooperation of roller 204 and a cylindrical cam 203 to No. two connecting rods 206 receive No. three extension board 1081's direction, make No. two connecting rods 206 take shutoff board 207 to remove about, thereby realize the shutoff or open to storage cavity 106 bottom export, carry out intermittent type unloading, alleviate the load of follow-up processing.

The upper grinding component 3 comprises a bending rod 301, a sliding shaft 302, a third connecting rod 303, a straight hole 304, a fourth connecting rod 305, a fifth connecting rod 306, a first-class sliding block 307, a second material guide plate 308, an upper grinding plate 309 and a supporting rod 311;

the upper grinding plate 309 is obliquely arranged in the grinding chamber 108 in a manner that the left part is lower than the right part; the right end of the upper grinding plate 309 is connected with a second material guide plate 308, and the left side of the second material guide plate 308 is connected with a fourth connecting rod 305; the bottom of the fourth connecting rod 305 is fixedly connected with an upper grinding plate 309 through a support rod 311, the front side and the rear side of the fourth connecting rod 305 are uniformly and symmetrically connected with a plurality of fifth connecting rods 306, and the outer ends of the fifth connecting rods 306 are fixedly connected with first-class sliding blocks 307; the front and rear side walls of the grinding cavity 108 are provided with sliding grooves 1082, and the first-class sliding block 307 is clamped into the sliding grooves 1082 and is in sliding fit with the sliding grooves 1082; the sliding groove 1082, the four-connecting rod 305 and the upper grinding plate 309 are arranged in parallel; the fourth connecting rod 305 is upwards connected with a third connecting rod 303, and a straight hole 304 is formed in the third connecting rod 303; the bottom of the second connecting rod 206 is connected with a bending rod 301, a sliding shaft 302 is fixedly connected to the bending rod 301, and the sliding shaft 302 is matched with a straight hole 304.

The bottom of the storage cavity 106 is aligned with the right part of the grinding cavity 108; a first material guide plate 1083 with a lower left part and a higher right part is fixedly connected to the right part of the grinding cavity 108; the left part of the grinding cavity 108 is fixedly connected with a material baffle 1084, and the material baffle 1084 is higher than the left end of the upper grinding plate 309.

Specifically, the yeast blocks falling from the storage cavity 106 are guided by the first material guide plate 1083 and the second material guide plate 308 and fall between the upper and lower grinding plate assemblies;

when the second connecting rod 206 moves left and right, the bending rod 302 moves along with the second connecting rod, and the third connecting rod 303 drives the fourth connecting rod 305 to move along the sliding groove 1082 through the matching of the sliding shaft 302 and the straight hole 304, so that the upper grinding plate 309 reciprocates to be matched with the lower grinding assembly 4 below to grind the ferment blocks. Because the connecting mode that the connecting rod is connected with the sliding block, the sliding block and the sliding groove are matched is adopted, the supporting force of the upper grinding plate is uniformly distributed, and the stability is greatly improved.

The lower grinding component 4 comprises a hand wheel 401, an adjusting screw 402, a moving nut 403, a number six connecting rod 404, a number seven connecting rod 405, a wedge block 406, a number three roller 407, a number eight connecting rod 408, a lower grinding plate 409, a number two sliding block 410 and a number one sliding rail 411;

the lower grinding plate 409 is arranged below the upper grinding plate 310 and is parallel to the upper grinding plate 310; a second sliding block 410 is fixedly connected to the right end of the lower grinding plate 409, and the second sliding block 410 is positioned below the first material guide plate 1083; a first slide rail 411 is fixedly connected to the right side wall of the grinding cavity 108, and the second slide block 410 is slidably connected with the first slide rail 411; an adjusting screw 402 is rotatably arranged between the grinding cavity 108 and the right side plate 103, and the right end of the adjusting screw 402 is externally connected with a hand wheel 401; a movable nut 403 is screwed on the adjusting screw 402, a sixth connecting rod 404 is connected to the movable nut 403 downwards, a seventh connecting rod 405 is connected to the sixth connecting rod 404 leftwards, and the seventh connecting rod 405 extends into the grinding cavity 108 and is connected with a wedge block 406; the lower grinding plate 409 is connected with a third roller 407 downwards through an eighth connecting rod 408, and the third roller 407 is matched with the inclined surface at the top of the wedge block 406.

Specifically, a grinding action area is formed between the upper grinding plate and the lower grinding plate, and the ferment blocks are subjected to the self-guiding action of the angle of the grinding plates in the grinding process, enter from the right side, exit from the left side, are blocked by the material retaining plate 1084, are discharged from an outlet below the grinding cavity 108, and fall into the material receiving box 110.

The fineness of grinding is determined by the size of the gap between the upper grinding plate and the lower grinding plate, the adjusting screw 402 is rotated by the hand wheel 401, the moving nut 403 drives the seven connecting rod 405 to move through the six connecting rod 404, so that the wedge block 406 moves left or right, the inclined surface of the wedge block 406 is matched with the three roller 407, the lower grinding plate 409 moves up or down, the gap between the upper grinding plate and the lower grinding plate is changed, and the size of ground particles is adjusted.

Example 3

On the basis of the example 2, the method comprises the following steps of,

because the grinding plate has a certain length, in order to provide effective support, the wedge block 406 is provided with a plurality of wedge blocks at intervals along the seven connecting rods 405, and the eight connecting rods 408 are also provided with a plurality of wedge blocks correspondingly;

the first slide rail 411 is a T-shaped slide rail, and the second slide block 410 is a corresponding C-shaped slide block, so that the separation is avoided; the opposite surfaces of the upper grinding plate 309 and the lower grinding plate 409 are provided with grinding projections 310 to ensure the grinding effect.

Example 4

On the basis of the example 3, the method comprises the following steps,

the grinding powder feeding device further comprises a material vibrating component 5, wherein the material vibrating component 5 is arranged on the left side of the grinding cavity 108 and comprises a second rotating shaft 501, a second cylindrical cam 502, a second roller 503, a rocker 504, a collision end 505, a first driving wheel 506, a driving belt 507 and a second driving wheel 507;

a second rotating shaft 501 is rotatably connected between the grinding cavity 108 and the left side plate 102; a second driving wheel 508 is arranged at the left section of the second rotating shaft 501, a first driving wheel 506 is correspondingly arranged on the first rotating shaft 202, and the first driving wheel 506 and the second driving wheel 508 are in transmission connection through a transmission belt 507; a second cylindrical cam 502 is arranged at the right section of the second rotating shaft 501, a second roller 503 is matched with the second cylindrical cam 502, and the second roller 503 is arranged at the top end of the rocker 504; the left side of the grinding chamber 108 is also connected with a third strut 504, the middle section of the rocker 504 is hinged with the third strut 504, and the bottom end of the first rocker 504 is provided with a collision end 505.

Wherein, when the pivot 202 rotated, still drive No. two pivots 501 rotations through the drive wheel transmission, No. two cylindrical cam 502 follows to rotate, because No. two rollers 503 and No. two cylindrical cam 502's channel cooperation, make rocker 504 take place to sway to take collision end 505 to beat crocus chamber 108, make the vibrations of crocus chamber 108 left part, unloading with higher speed.

Example 5

On the basis of the example 4, the method comprises the following steps of,

the material receiving assembly 6 is arranged below the material receiving box 110 and comprises a second sliding rail 601, a third sliding block 602, a moving plate 603, a first spring 604, a first wire guide wheel 605 and a first pull rope 606;

the material receiving box 110 is arranged on a moving plate 603, a third slide block 602 is fixedly connected to the bottom of the moving plate 603, a second slide rail 601 is arranged on the bottom plate 101, and the third slide block 602 is slidably connected with the second slide rail 601; a first spring 604 is connected between the moving plate 603 and the right side plate 103; the base 603 is provided with a first wire guide wheel 605 corresponding to the left side of the moving plate 603, the left end of the moving plate 603 is connected with a first pull rope 606, and the first pull rope 606 bypasses the first wire guide wheel 605 and is connected with the rocker 504.

Specifically, while the rocker 504 swings, the moving plate 603 is acted by the first pull rope 606: when the rocker 504 rotates counterclockwise, the first pull rope 606 pulls the moving plate 603 to move left, and the first spring 604 stretches; when the rocker 504 rotates clockwise, the first pull rope 606 is loosened, the first spring 604 is deformed and restored, and the moving plate 603 is driven to move right, so that the moving plate 603 drives the material receiving box 110 to move left and right, and the blanking is uniformly distributed in the material receiving box.

Example 6

On the basis of the example 5, the method comprises the following steps of,

the wire feeding device further comprises a material feeding assembly 8, wherein the material feeding assembly 8 comprises a second pull rope 801, a second wire guide wheel 802, an end plate 803, a moving rod 804, a dredging end 805, a second spring 806, a take-up pulley 807, a driven gear 808, an installation rod 809 and a rack 810;

the middle part of the first connecting rod 205 is connected with a rack 810 rightwards; the right side of the second support plate 105 is connected with an installation rod 809, the right end of the installation rod 809 is provided with a driven gear 808, and the driven gear 808 is matched with a rack 810; a take-up pulley 807 is coaxially arranged on the driven gear 808, and the take-up pulley 807 is connected with a second pull rope 801; the top of the material storage cavity 106 is provided with an opening, a top rod 1061 is fixedly connected between the openings, and the middle part of the top rod 1061 is provided with a sleeve 1062; the movable rod 804 penetrates through the sleeve 1062, the top end of the movable rod is fixedly connected with an end plate 803, and the bottom end of the movable rod is fixedly connected with a dredging end 805; a second spring 806 is connected between the end plate 803 and the top of the sleeve 1061; the left side of the material storage cavity 106 is provided with a second wire guide wheel 802, and a second pull rope 801 bypasses the second wire guide wheel 802 and is connected with an end plate 803.

Specifically, the rack 810 for throwing the yeast blocks into the storage cavity 106 through the opening at the top of the storage cavity 106 also moves left and right along with the first connecting rod 205, so that the driven gear 808 receives the rack 810 to rotate positively and negatively, the take-up pulley 807 rotates positively and negatively to take up and pay off the wires, the second spring 806 is matched, the moving rod 804 drives the dredging end 805 to move up and down to dredge, and blockage is prevented from occurring during the blanking of the storage cavity 106.

It should be noted that the electrical components are provided with power supplies, and the control method is the prior art, and is unified here for avoiding the redundancy of description; and the present invention is primarily intended to protect mechanical devices, the control means and circuit connections will not be explained in detail herein.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (10)

1. The grinding equipment for the vegetable and fruit enzyme, which is convenient to adjust, is characterized by comprising a frame (1), a blanking assembly (2), an upper grinding assembly (3) and a lower grinding assembly (4);

the frame (1) comprises a bottom plate (101), a left side plate (102), a right side plate (103), a storage cavity (106), a first support rod (107), a grinding cavity (108), a second support rod (109) and a material receiving box (110), wherein the left end and the right end of the base are fixedly connected with the left side plate (102) and the right side plate (103) respectively, the left side of the top of the right side plate (103) is connected with the storage cavity (106) through the first support rod (107), a blanking assembly (2) is arranged below the storage cavity (106), the grinding cavity (108) is arranged below the blanking assembly (2) and fixedly connected with the right side plate (103) through the second support rod (109); the upper grinding component (3) and the lower grinding component (4) are arranged above and below the grinding cavity (108); the material receiving box (110) is arranged below the grinding cavity (108).

2. The adjustable milling equipment for vegetable and fruit ferment as claimed in claim 1, wherein the blanking assembly (2) comprises a servo motor (201), a first rotating shaft (202), a first cylindrical cam (203), a first roller (204), a first connecting rod (205), a second connecting rod (206) and a blocking plate (207);

a first support plate (104) is connected to the top of the left side plate (102) rightwards, a second support plate (105) is connected to the right end of the first support plate (104) downwards, a first rotating shaft (202) is arranged between the second support plate (105) and the left side plate (102), and a servo motor (201) is connected to the left end of the first rotating shaft (202) in an external mode; a first cylindrical cam (203) is arranged on the first rotating shaft (202), the first cylindrical cam (203) is matched with a first roller (204), the first roller (204) is connected with a first connecting rod (205) downwards, and the first connecting rod (205) is connected with a second connecting rod (206) rightwards; no. three supporting plates (1081) are arranged at the left end of the top of the grinding cavity (108), a second connecting rod (206) horizontally penetrates through the No. three supporting plates (1085) and is connected with a blocking plate (207), and the blocking plate (207) is matched with an outlet at the bottom of the storage cavity (106).

3. The adjustable milling equipment for ferment of vegetables and fruits according to claim 2, wherein the upper milling assembly (3) comprises a bending rod (301), a sliding shaft (302), a third connecting rod (303), a straight hole (304), a fourth connecting rod (305), a fifth connecting rod (306), a first type slide block (307), a second guiding plate (308), an upper milling plate (309) and a supporting rod (311);

the upper grinding plate (309) is obliquely arranged in the grinding cavity (108) in a manner that the left part is lower than the right part; the right end of the upper grinding plate (309) is connected with a second material guide plate (308), and the left side of the second material guide plate (308) is connected with a fourth connecting rod (305); the bottom of the fourth connecting rod (305) is fixedly connected with an upper grinding plate (309) through a support rod (311), a plurality of fifth connecting rods (306) are uniformly and symmetrically arranged on the front side and the rear side of the fourth connecting rod (305), and first-class sliding blocks (307) are arranged at the outer ends of the fifth connecting rods (306); sliding grooves (1082) are formed in the front side wall and the rear side wall of the grinding cavity (108), and the first-class sliding block (307) is clamped into the sliding grooves (1082) and is in sliding fit with the sliding grooves (1082); the sliding groove (1082), the four-connecting rod (305) and the upper grinding plate (309) are arranged in parallel; the fourth connecting rod (305) is upwards connected with a third connecting rod (303), and a straight hole (304) is formed in the third connecting rod (303); the bottom of the second connecting rod (206) is connected with a bending rod (301), a sliding shaft (302) is arranged on the bending rod (301), and the sliding shaft (302) is matched with the straight hole (304).

4. The adjustable vegetable and fruit enzyme grinding equipment as claimed in claim 3, wherein the bottom of the storage chamber (106) is aligned with the right part of the grinding chamber (108); a first material guide plate (1083) with a lower left part and a higher right part is arranged at the right part of the grinding cavity (108); the left part of the grinding cavity (108) is provided with a material baffle plate (1084), and the material baffle plate (1084) is higher than the left end of the upper grinding plate (309).

5. The vegetable and fruit enzyme grinding equipment convenient to adjust as claimed in claim 4, wherein the lower grinding assembly (4) comprises a hand wheel (401), an adjusting screw (402), a moving nut (403), a six-size connecting rod (404), a seven-size connecting rod (405), a wedge block (406), a three-size roller (407), an eight-size connecting rod (408), a lower grinding plate (409), a two-size sliding block (410) and a one-size sliding rail (411);

the lower grinding plate (409) is arranged below the upper grinding plate (309) and is parallel to the upper grinding plate (309); a second sliding block (410) is arranged at the right end of the lower grinding plate (409), and the second sliding block (410) is positioned below the first material guide plate (1083); a first sliding rail (411) is arranged on the right side wall of the grinding cavity (108), and a second sliding block (410) is connected with the first sliding rail (411) in a sliding manner; an adjusting screw rod (402) is rotatably arranged between the grinding cavity (108) and the right side plate (103), and the right end of the adjusting screw rod (402) is externally connected with a hand wheel (401); a movable nut (403) is screwed on the adjusting screw rod (402), a sixth connecting rod (404) is connected to the movable nut (403) downwards, a seventh connecting rod (405) is connected to the sixth connecting rod (404) leftwards, and the seventh connecting rod (405) extends into the grinding cavity (108) and is connected with a wedge block (406); the lower grinding plate (409) is connected with a third roller (407) downwards through an eighth connecting rod (408), and the third roller (407) is matched with an inclined surface at the top of the wedge block (406).

6. The adjustable milling equipment for ferment of vegetables and fruits according to claim 5, wherein the wedge-shaped block (406) is provided with a plurality of seven connecting rods (405) at intervals, and the eight connecting rods (408) are correspondingly provided with a plurality of wedges.

7. The adjustable milling equipment for ferment of vegetables and fruits according to claim 6, wherein the first sliding rail (411) is a T-shaped sliding rail, and the second sliding block (410) is a corresponding C-shaped sliding block; and grinding protrusions (310) are arranged on the opposite surfaces of the upper grinding plate (309) and the lower grinding plate (409).

8. The adjustable milling equipment for the ferment of vegetables and fruits according to claim 7, further comprising a material vibrating component (5), wherein the material vibrating component (5) is disposed at the left side of the milling cavity (108) and comprises a second rotating shaft (501), a second cylindrical cam (502), a second roller (503), a rocker (504), an impact end (505), a first driving wheel (506), a driving belt (507) and a second driving wheel (508);

a second rotating shaft (501) is rotatably connected between the grinding cavity (108) and the left side plate (102); a second driving wheel (508) is arranged at the left section of the second rotating shaft (501), a first driving wheel (506) is correspondingly arranged on the first rotating shaft (202), and the first driving wheel (506) is in transmission connection with the second driving wheel (508) through a transmission belt (507); a second cylindrical cam (502) is arranged at the right section of the second rotating shaft (501), a second roller (503) is matched with the second cylindrical cam (502), and the second roller (503) is arranged at the top end of the rocker (504); the left side of the grinding cavity (108) is further connected with a third supporting rod (1085), the middle section of the rocker (504) is hinged with the third supporting rod (1085), and the bottom end of the rocker (504) is provided with a collision end (505).

9. The adjustable milling equipment for the ferment of vegetables and fruits according to claim 8, further comprising a material receiving assembly (6), wherein the material receiving assembly (6) is arranged below the material receiving box (110) and comprises a second sliding rail (601), a third sliding block (602), a moving plate (603), a first spring (604), a first guide wheel (605) and a first pull rope (606);

the material receiving box (110) is arranged on the moving plate (603), the bottom of the moving plate (603) is provided with a third sliding block (602), the bottom plate (101) is provided with a second sliding rail (601), and the third sliding block (602) is in sliding connection with the second sliding rail (601); a first spring (604) is connected between the moving plate (603) and the right side plate (103); the left side of the base corresponding to the moving plate (603) is provided with a first wire guide wheel (605), the left end of the moving plate (603) is connected with a first pull rope (606), and the first pull rope (606) bypasses the first wire guide wheel (605) and is connected with the rocker (504).

10. The adjustable milling equipment for the ferment of vegetables and fruits according to claim 9, further comprising a material passing component (8), wherein the material passing component (8) comprises a second pull rope (801), a second wire guide wheel (802), an end plate (803), a moving rod (804), a dredging end (805), a second spring (806), a wire take-up wheel (807), a driven gear (808), a mounting rod (809) and a rack (810);

the middle part of the first connecting rod (205) is connected with a rack (810) rightwards; the right side of the second support plate (105) is connected with an installation rod (809), the right end of the installation rod (809) is provided with a driven gear (808), and the driven gear (808) is matched with a rack (810); the driven gear (808) is coaxially provided with a take-up pulley (807), and the take-up pulley (807) is connected with a second pull rope (801); the top of the material storage cavity (106) is provided with an opening, a top rod (1061) is arranged between the openings, and the middle part of the top rod (1061) is provided with a sleeve (1062); the movable rod (804) penetrates through the sleeve (1062), the top end of the movable rod is provided with an end plate (803), and the bottom end of the movable rod is provided with a dredging end head (805); a second spring (806) is arranged between the end plate (803) and the top of the sleeve (1062); the left side of the material storage cavity (106) is provided with a second wire guide wheel (802), and a second pull rope (801) is connected with an end plate (803) by bypassing the second wire guide wheel (802).

Images