CN221111919U - Tremella polysaccharide finished product blank equipment - Google Patents

Abstract

The application relates to the technical field of tremella polysaccharide preparation, and improves the problem of low efficiency of the existing tremella polysaccharide cutting process, and discloses tremella polysaccharide finished product blanking equipment, which comprises a cutting box and a pressing mechanism, wherein a partition plate is arranged in the cutting box; the top surface of the cutting box is provided with a feed inlet communicated with the feed cavity, and the bottom surface of the cutting box is provided with a discharge outlet communicated with the material cutting cavity; the cutting box is connected with the cutter board in discharge gate department cover, and the swager constructs including clamp plate and drive clamp plate and is close to or keep away from the first driving piece that cutter board direction removed. The large tremella polysaccharide material in the feeding cavity enters the cutter plate of the blanking cavity from the channel, and the pressing plate extrudes the material downwards, so that the material is cut into uniform small pieces through the cutter plate, the possibility that tremella polysaccharide is crushed by pressing is reduced, and meanwhile, the production efficiency is improved.

Description

Tremella polysaccharide finished product blank equipment

Technical Field

The application relates to the technical field of tremella polysaccharide preparation, in particular to tremella polysaccharide finished product blanking equipment.

Background

Tremella polysaccharide is acidic heteropolysaccharide with higher nutritive value in tremella, and the demand of tremella polysaccharide is increasing. Separating tremella polysaccharide slurry from tremella through cutting, extruding and other procedures, concentrating tremella polysaccharide slurry, conveying the concentrated tremella polysaccharide slurry into a drying box through a conveying belt for conveying liquid, drying into slices, and conveying the slices into the next procedure; the dried flaky tremella polysaccharide has larger volume, needs to be divided into small pieces, and is finally weighed and packaged into a finished product by a packaging bag. The flaky tremella polysaccharide can be used as an instant brewing health-care food to enter the market.

However, the flaky tremella polysaccharide is very fragile, if the existing food cutting machine is adopted for cutting, the tremella polysaccharide is easily crushed into pieces, so that the quality of a final finished product can be affected, and the waste of materials can be caused. Therefore, in the existing tremella polysaccharide production process, a manual breaking or manual cutting mode is still adopted to ensure that a sheet-shaped finished product conforming to the size can be formed, but the manual cutting mode is time-consuming and labor-consuming, and the production efficiency is reduced.

Disclosure of utility model

In order to overcome the defect of low efficiency of the existing cutting of sheet tremella polysaccharide, the application provides tremella polysaccharide finished product blanking equipment.

The application provides tremella polysaccharide finished product blanking equipment, which adopts the following technical scheme:

The tremella polysaccharide finished product blanking equipment comprises a cutting box and a blanking mechanism, wherein a partition plate is vertically arranged in the cutting box, a feeding cavity and a blanking cavity are respectively formed in the inner cavity of the cutting box at two sides of the partition plate, and a channel for communicating the feeding cavity and the blanking cavity is formed between the bottom end of the partition plate and the bottom wall of the cutting box; the top surface of the cutting box is provided with a feed inlet communicated with the feed cavity, and the bottom surface of the cutting box is provided with a discharge outlet communicated with the blanking cavity; the cutting box is connected with a cutter plate in a covering manner at the discharge hole, the cutter plate comprises a plurality of cutting knives which are arranged in a transverse-longitudinal staggered manner, and the material pressing mechanism comprises a pressing plate and a first driving piece which drives the pressing plate to move towards the direction close to or far away from the cutter plate.

By adopting the technical scheme, the large tremella polysaccharide material is poured into the feeding cavity of the cutting box from the feeding hole, the material at the bottom enters the cutter plate in the cutting cavity from the channel firstly, then the first driving piece drives the pressing plate to move downwards to extrude the material, so that the material is cut into uniform small pieces through the cutter plate, and the thickness of the material cut each time is the height of the channel, namely, the material cut each time is less, so that the condition that the material in the middle part is easily crushed due to the fact that the thickness of the tremella polysaccharide material is larger is reduced; after the material breaks away from the cutting case through the interval of cutter board, first driving piece drives the clamp plate again and upwards keeps away from the cutter board, and the material in the feed chamber can continue to follow the passageway and get into the blank intracavity this moment to continue above-mentioned cutting step, first driving piece adopts automatic automatically controlled drive, interval drive clamp plate reciprocating motion, need not manual operation, has improved the quality of work efficiency and tremella polysaccharide finished product.

Optionally, the cutter board with cutting case swing joint, the cutter board is connected with leveling mechanism, leveling mechanism is used for driving the cutter board activity is so that the flattening gets into material on the cutter board, the height of cutter board is less than the cutting case in the height of feeding intracavity diapire.

By adopting the technical scheme, most of materials can be accumulated at a position close to the channel when entering the blanking cavity from the feeding cavity, so that the cutting efficiency is reduced; the cutter plate is arranged to be movable, and the cutter plate is driven to move through the leveling mechanism, and the height of the cutter plate does not exceed the bottom wall of the feeding cavity when moving, so that the material on the cutter plate is leveled away from the direction of the channel, the channel can be dredged, the material can enter the cutting cavity through the channel and is paved on the surface of the cutter plate, the cutting efficiency is improved, the situation that the tremella polysaccharide material is crushed is further reduced, and the uniformity of the tremella polysaccharide is guaranteed.

Optionally, a movable groove is formed in the bottom of the inner wall of the blanking cavity of the cutting box, the cutter plate is vertically and slidably connected in the movable groove, and a gap is reserved between the inner wall of the movable groove and the cutter plate; the leveling mechanism comprises a stirring piece and a second driving piece which drives the stirring piece to reciprocate vertically, one side of the stirring piece along the vertical direction is abutted to the side wall of the cutter plate, and a plurality of stirring parts are arranged on one surface of the cutter plate along the vertical interval in an abutting mode.

Through adopting above-mentioned technical scheme, cutter board and cutting case adopt to follow vertical sliding connection's mode to be connected, stir piece and cutter board looks butt and be provided with outstanding stirring portion on the butt face, when leveling mechanism drives stirring piece reciprocating motion through the second driving piece, can drive cutter board and vibrate from top to bottom, because leave the clearance between the inner wall of movable groove and the cutter board, can supply stirring portion to pass through when the cutter board moves, thereby realize the flattening to the tremella polysaccharide material on the cutter board, and the mode of vibration from top to bottom improves the flattening effect better; in addition, when the material is cut, the residual material on the cutter plate can be vibrated down through the leveling mechanism, so that the production efficiency and the quality of a finished product are further improved.

Optionally, the stirring portion is spherical, a rolling groove is formed in the stirring piece, and the stirring portion is in rolling connection with the rolling groove.

Through adopting above-mentioned technical scheme, stir the portion and set up to globular and roll connection in the rolling groove to can reduce the resistance of stirring when the piece removes, further be convenient for stir the portion and pass through the cutter board, make the cutter board stirred more smoothly, and then improve the flattening effect.

Optionally, the leveling mechanism further includes an elastic element disposed in the movable slot, one end of the elastic element is connected to the inner wall of the movable slot, the other end of the movable slot is connected to the cutter plate, and the elastic element drives the cutter plate to move upwards.

Through adopting above-mentioned technical scheme, the elastic component is connected cutting case and cutter board, because cutter board itself receives the gravity effect to move down, and the elastic component drive cutter board is upward moved to can increase the amplitude when the cutter board is stirred by stirring the piece, further improve the flattening effect, thereby improve the cutting homogeneity.

Optionally, a cushion pad having elasticity is disposed on a side of the pressing plate facing the cutter plate.

Through adopting above-mentioned technical scheme, the blotter is for having elastic flexible pad, extrudees tremella polysaccharide through the blotter, compares in the clamp plate of stereoplasm, can further reduce the damage to tremella polysaccharide, guarantees that tremella polysaccharide can be cut into the platelet.

Optionally, a guide plate is connected to the inner wall of the feeding cavity far away from the blanking cavity, and the guide plate is inclined downwards towards the direction of the channel.

Through adopting above-mentioned technical scheme, tremella polysaccharide material is poured into the feed chamber from the feed inlet and can fall on the deflector, and the deflector sets up to the slope of toward the passageway direction, can be with the material in the direction of blank chamber, further improves cutting efficiency.

Optionally, the deflector with the inner wall in blank chamber articulates, stir the piece set up in the deflector below is close to the one end of passageway, just stir the top butt of piece in the deflector, the second driving piece passes through stir the piece can drive the deflector upwards rotate to butt in the roof of passageway.

By adopting the technical scheme, the guide plate is hinged with the cutting box, the stirring piece is arranged below the guide plate, the stirring piece is positioned at the channel, when the second driving piece drives the stirring piece to move upwards, the stirring piece not only can drive the cutter plate to vibrate, but also can push the guide plate to the closed channel, so that the situation that when the pressing plate extrudes materials, the materials fall on the pressing plate through the channel is avoided, and the waste of tremella polysaccharide is reduced; after the clamp plate upwards breaks away from the cutter board, stir the piece and move down again, can also shake off the material of remaining on the cutter board when opening the passageway, further improve cutting efficiency.

Optionally, a gravity sensor is installed on the cutter plate, when the gravity sensor detects that gravity reaches a threshold value, the second driving piece drives the stirring piece to move upwards until the guide plate abuts against the top wall of the channel, and the first driving piece drives the pressing plate to move downwards.

Through adopting above-mentioned technical scheme, set up gravity sensor again on the cutter board, fall into the weight of tremella polysaccharide on the cutter board through gravity sensor monitoring, when tremella polysaccharide reached appointed weight, stir the piece and promote deflector closed channel again, simultaneously with the material flattening on the cutter board, then the clamp plate extrudees the material again and cuts through the cutter board, has not only improved cutting accuracy, has still improved production efficiency.

In summary, the present application includes at least one of the following beneficial effects:

1. The large tremella polysaccharide material is poured into the feeding cavity of the cutting box from the feeding hole, part of the material at the bottom enters the cutting cavity from the channel and is positioned on the cutter plate, and then the first driving piece drives the pressing plate to move downwards to extrude the material, so that the material is cut into uniform small pieces through the cutter plate, the condition that the material in the middle is crushed easily due to the fact that the tremella polysaccharide material is large in thickness is reduced, and the quality of tremella polysaccharide finished products is improved;

2. After the material leaves the cutting box through the interval of the cutter plates, the first driving piece drives the pressing plate to move upwards away from the cutter plates, and the material in the feeding cavity can enter the material cutting cavity continuously from the channel, so that the cutting step is continued, manual operation is not needed, the working efficiency is improved, and the production cost is reduced;

3. thereby vibrate the cutter board through leveling mechanism and level the material, thereby leveling mechanism can also promote the deflector to closed passageway, has further improved the cutting effect, has still reduced the waste of material.

Drawings

Fig. 1 is a schematic structural diagram of tremella polysaccharide finished product blanking equipment in an embodiment of the application;

fig. 2 is a cross-sectional view of tremella polysaccharide finished product blanking equipment in an embodiment of the application;

FIG. 3 is an enlarged view at A in FIG. 2;

Fig. 4 is a cross-sectional view of the tremella polysaccharide finished product blanking apparatus when the blanking cavity and the channel are closed by the guide plate in the embodiment of the application.

Reference numerals illustrate: 1. a cutting box; 11. a feed chamber; 12. a blanking cavity; 13. a channel; 14. a feed inlet; 15. a discharge port; 16. a movable groove; 17. a relief groove; 2. a partition plate; 3. a material pressing mechanism; 31. a pressing plate; 32. a first driving member; 33. a cushion pad; 4. a cutter plate; 41. a cutting knife; 42. a frame; 43. a partition groove; 5. a leveling mechanism; 51. a toggle member; 511. a movable plate; 512. a toggle part; 513. a rolling groove; 52. a second driving member; 53. an elastic member; 6. a guide plate; 7. a gravity sensor; 8. and (5) a feeding hopper.

Detailed Description

The application is described in further detail below with reference to fig. 1-4.

Referring to fig. 1 and 2, the embodiment of the application discloses tremella polysaccharide finished product blanking equipment, which comprises a cutting box 1 and a material pressing mechanism 3, wherein a partition board 2 is vertically arranged in the cutting box 1, a feeding cavity 11 and a blanking cavity 12 are respectively formed in the inner cavity of the cutting box 1 at two sides of the partition board 2, and a channel 13 for communicating the feeding cavity 11 and the blanking cavity 12 is formed between the bottom end of the partition board 2 and the bottom wall of the cutting box 1; the top surface of the cutting box 1 is provided with a feed inlet 14 communicated with the feed cavity 11, and the bottom surface of the cutting box 1 is provided with a discharge outlet 15 communicated with the cavity of the blanking cavity 12; the cutting box 1 is covered and connected with a cutter plate 4 at a discharge hole 15, the cutter plate 4 comprises a plurality of cutting knives 41 which are transversely and longitudinally staggered, and the material pressing mechanism 3 comprises a pressing plate 31 and a first driving piece 32 which drives the pressing plate 31 to move towards a direction close to or far away from the cutter plate 4.

Large tremella polysaccharide material is poured into the feeding cavity 11 from the feeding hole 14, the material at the bottom enters the cutter plate 4 of the blanking cavity 12 from the channel 13, and the first driving piece 32 drives the pressing plate 31 to move downwards to squeeze the material, so that the material is cut into uniform small pieces through the cutter plate 4; after the material breaks away from the cutting box 1 through the interval of cutter board 4, drive clamp plate 31 upwards removes and breaks away from cutter board 4, and the material in the feed chamber 11 continues to follow passageway 13 and get into in the blank chamber 12 to continue above-mentioned cutting step, reduced because of the great circumstances emergence that leads to the material in middle part of tremella polysaccharide material thickness by the crushing, and need not manual operation, improved production efficiency.

Referring to fig. 1, the cutting box 1 and the partition plate 2 can be made of aluminum alloy or stainless steel, and the partition plate 2 is fixedly connected in the cutting box 1 by bolts or welding; the cutting box 1 is preferably square, and correspondingly, the partition plate 2 divides the two feeding cavities 11 and the blanking cavity 12 into square cavities, the feeding cavities 11 vertically penetrate through the top surface of the cutting box 1 to form a feeding opening 14, and the feeding hopper 8 is arranged at the feeding opening 14 so as to facilitate pouring tremella polysaccharide into the feeding cavities 11. Referring to fig. 2, the cutter plate 4 further includes a frame 42, the hollow area in the frame 42 is consistent with the area of the discharge port 15, the cutters 41 are mounted in the frame 42, and a plurality of square separation grooves 43 with consistent areas are formed in the cutters 41 which are staggered horizontally and vertically. The area of the tremella polysaccharide in the large piece is not larger than the areas of the inlet 14 and the outlet 15 and larger than the area of the partition groove 43.

Referring to fig. 2, in order to facilitate the material at the bottom of the feeding cavity 11 to enter the blanking cavity 12, the height of the cutter plate 4 is lower than the height of the bottom wall of the cutting box 1 in the feeding cavity 11, and the inner wall of the feeding cavity 11 is also connected with a guide plate 6; the guide plate 6 is inclined downwards towards the channel 13, the guide plate 6 can be provided as an arc-shaped plate or a plane plate, preferably an arc-shaped plate, the width of the guide plate 6 corresponds to the width of the feed cavity 11, and the guide plate 6 extends into the channel 13 towards one side of the feed cavity 11. The tremella polysaccharide material falls on the deflector 6 after pouring into the feed chamber 11 from feed inlet 14, and the deflector 6 is directed to blank chamber 12 with the material, further improves cutting efficiency.

In one embodiment, the guide plate 6 is provided in a fixed mounting with the cutting box 1. In this embodiment, the guide plate 6 is rotatably connected with the cutting box 1, specifically, the guide plate 6 is hinged on the inner wall of the feeding cavity 11 far away from the blanking cavity 12, one end of the guide plate 6 far away from the hinged end is lapped on the bottom wall of the feeding cavity 11, the cutting box 1 is further provided with a third driving piece for driving the guide plate 6 to rotate, the third driving piece can drive the guide plate 6 to rotate upwards to be abutted against the top wall of the channel 13, so that materials in the feeding cavity 11 are blocked from entering the blanking cavity 12, at the moment, the first driving piece 32 drives the pressing plate 31 to press the materials downwards, and when the pressing plate 31 is separated from the cutting plate 4 upwards, the third driving piece drives the guide plate 6 to rotate until the channel 13 is opened to be communicated with the feeding cavity 11. The third driving member may be provided as a small motor rotatably connected to the guide plate 6.

In other embodiments, the cutter plate 4 is fixedly mounted with the cutting box 1 to simplify the structure of the blanking apparatus.

Because the material gets into behind the blank chamber 12 from feed chamber 11, most can pile up in the position that is close to passageway 13, so this embodiment is, referring to fig. 2, cutter board 4 and cutting case 1 swing joint, cutter board 4 is connected with leveling mechanism 5, leveling mechanism 5 is used for driving cutter board 4 activity so that the flattening gets into the material on the cutter board 4, and cutter board 4 can not exceed deflector 6 in the highest position when the activity, thereby make the material on the cutter board 4 to the direction flattening of keeping away from passageway 13, can also dredge passageway 13, make the material get into blank chamber 12 through passageway 13 and pave cutter board 4 surface, the efficiency of cutting has been improved, further reduce the condition emergence that the tremella polysaccharide material is crushed, guarantee the homogeneity of cutting out the small tremella polysaccharide.

In an embodiment, the leveling mechanism 5 may be set to be fixed to a motor outside the cutting box 1, and the output shaft of the motor is connected to the middle part of the cutter plate 4, at this time, the discharge hole 15 and the cutter plate 4 are all set to be circular, and the cutter plate 4 is driven by the motor to rotate, so that the material on the cutter plate 4 can be gradually flung and leveled.

In this embodiment, a mode of vibrating the cutter plate 4 up and down is preferably adopted to improve the leveling effect, referring to fig. 3, the movable groove 16 is formed at the bottom of the inner wall of the cutting chamber 12 of the cutting box 1, the cutter plate 4 is vertically slidably connected in the movable groove 16, at this time, the discharging chamber vertically penetrates through the bottom surface of the cutting box 1 to form a square discharging hole 15, the frame 42 of the cutter plate 4 is located in the movable groove 16, and the height of the movable groove 16 is preferably 3-5 times the thickness of the frame 42. In one mode, the leveling mechanism 5 is a linear driving cylinder, and an output shaft of the linear driving cylinder is connected to the cutter plate 4 and drives the cutter plate 4 to reciprocate up and down, so as to level the material. In another preferred mode, referring to fig. 3, the leveling mechanism 5 includes a stirring member 51 and a second driving member 52 for driving the stirring member 51 to reciprocate vertically, and a relief groove 17 for the stirring member 51 to fit and pass through is formed in the bottom of the cutting box 1; the poking part 51 comprises a movable plate 511 with the width consistent with that of the cutter plate 4, the second driving part 52 can be a linear driving cylinder such as an air cylinder, an electric cylinder or a hydraulic cylinder, the second driving part 52 is fixedly arranged below the cutting box 1, an output shaft of the second driving part 52 is connected to the middle part of the movable plate 511, or the number of the second driving parts 52 is set to be two and respectively connected to two sides of the movable plate 511, so that the stability of the driving process is improved; the movable plate 511 is abutted on the side wall of the cutter plate 4 along one vertical side, a plurality of poking parts 512 are convexly arranged on one surface of the movable plate 511 abutted on the cutter plate 4, and at the moment, a gap is reserved between the inner wall of the movable groove 16 and the cutter plate 4; when the second driving member 52 drives the poking member 51 to reciprocate, the poking portions 512 arranged at intervals can vibrate the cutter plate 4 up and down when passing through the cutter plate 4, and because a gap is reserved between the inner wall of the movable groove 16 and the cutter plate 4, the poking portions 512 can be provided for passing through when the cutter plate 4 moves, so that the tremella polysaccharide material on the cutter plate 4 is leveled. Optionally, but not limited to, the cutting box 1 is provided with a baffle at the outlet 15, and the baffle extends down to a side of the second driving member 52 near the center of the inlet 14, so as to prevent cut material from falling on the second driving member 52.

In other embodiments, the striking portion 512 may be a hemisphere fixed on the movable plate 511. In order to reduce the obstruction of the vibration process, the stirring part 512 is spherical, a rolling groove 513 is formed in the connecting part, and the stirring part 512 is connected in the rolling groove 513 in a rolling way; further, the toggle portion 512 may be made of a material with deformation force, such as silica gel or rubber. The leveling mechanism 5 further comprises an elastic member 53 disposed in the movable slot 16, the elastic member 53 is a spring or a rubber pad, preferably a spring, the elastic member 53 is plural along the longitudinal array of the movable slot 16, one end of the elastic member 53 is connected to the inner wall of the movable slot 16, the other end of the movable slot 16 is connected to the cutter plate 4, and the elastic member 53 drives the cutter plate 4 to move upwards. Because cutter board 4 itself receives gravity effect to move down, elastic component 53 drive cutter board 4 upwards moves to can increase the amplitude of cutter board 4 when being stirred by stirring piece 51, further improve the flattening effect, thereby improve the cutting homogeneity, elastic component 53 can also avoid cutter board 4 activity to break away from out cutting box 1.

Further, for simplicity of construction, the third driving member and the second driving member 52 may be provided as one and the same component. Specifically, referring to fig. 3 and 4, the relief groove 17 is correspondingly formed below the channel 13, and the stirring member 51 passes through the relief groove 17 from bottom to top and then abuts against the guide plate 6, where it is noted that the stirring portions 512 may be arranged along a vertical array and multiple columns along a transverse array, the relief groove 17 is arranged in a strip shape and is provided with semicircular groove portions at intervals for the stirring portions 512 to pass through, and at the same time, the gap between the relief groove 17 and the stirring member 51 is reduced to avoid the material from falling from the relief groove 17; when the second driving piece 52 drives the stirring piece 51 to move upwards, the stirring piece 51 can drive the cutter plate 4 to vibrate through the stirring part 512 and can push the guide plate 6 to rotate upwards until the guide plate is abutted against the top wall of the channel 13, so that the situation that when the pressing plate 31 extrudes materials, the materials fall on the pressing plate 31 through the channel 13 is avoided, and the waste of tremella polysaccharide is reduced; when the poking piece 51 moves downwards, the material remained on the cutter plate 4 can be shaken off, and the guide plate 6 automatically rotates downwards under the action of gravity to open the channel 13, so that the cutting efficiency and the quality of a finished product are further improved.

Referring to fig. 2, the first driving member 32 may also be configured as a linear driving cylinder, the first driving member 32 is fixedly mounted above the cutter plate 4 in the blanking cavity 12, the output end of the first driving member 32 is fixed on the pressing plate 31, the periphery side of the pressing plate 31 abuts against the periphery inner wall of the blanking cavity 12, the side of the pressing plate 31 facing the cutter plate 4 is provided with an elastic buffer pad 33, the buffer pad 33 may be a rubber pad or a silica gel pad, and the tremella polysaccharide is extruded through the buffer pad 33, so that compared with the hard pressing plate 31, the damage to the tremella polysaccharide can be further reduced, and the tremella polysaccharide can be cut into small pieces.

Referring to fig. 2 and 4, in order to further improve the cutting efficiency, a gravity sensor 7 is further installed on the bottom surface of the cutter plate 4, and the gravity sensor 7 is electrically connected with the first driving member 32 and the second driving member 52; when the gravity sensor 7 detects that the increased gravity on the cutter plate 4 reaches a threshold value, namely, when tremella polysaccharide entering the cutter plate 4 reaches a specified amount, the second driving piece 52 drives the toggle piece 51 to move upwards until the guide plate 6 abuts against the top wall of the channel 13, and then the first driving piece 32 drives the pressing plate 31 to move downwards again; when the pressing plate 31 is separated from the cutter plate 4, the material also falls downwards out of the cutting box 1, and at this time, the second driving member 52 drives the toggle member 51 to move downwards again.

Optionally, but not limited to, a collection box is also placed below the discharge port 15, or a conveyor belt is installed to send to the next process.

The embodiment of the application provides a tremella polysaccharide finished product blanking device, which has the implementation principle that:

Large tremella polysaccharide materials are poured into a feeding cavity 11 of a cutting box 1 from a feeding hole 14, a guide plate 6 guides the materials at the bottom to a channel 13 and enters a cutter plate 4 in the cutting cavity 12, when a gravity sensor 7 detects that the increased gravity on the cutter plate 4 reaches a threshold value, a second driving piece 52 drives a stirring piece 51 to move upwards until the guide plate 6 is abutted to the top wall of the channel 13, the stirring piece 51 drives the cutter plate 4 to vibrate when moving so as to level the materials on the cutter plate 4, then a first driving piece 32 drives a pressing plate 31 to move downwards to squeeze the materials, so that the materials are cut into uniform small pieces through the cutter plate 4, the cut materials are fewer each time, and the condition that the materials in the middle are easily crushed by pressing due to the fact that the tremella polysaccharide materials are large in thickness is reduced; after the material breaks away from the cutting box 1 through the separating groove 43 of the cutter plate 4, the first driving piece 32 drives the pressing plate 31 to move upwards and away from the cutter plate 4, the second driving piece 52 drives the stirring piece 51 to move downwards, the cutter plate 4 is stirred at the moment, so that redundant material shakes down, the guide plate 6 automatically rotates downwards under the action of gravity to open the channel 13, and the material in the feeding cavity 11 continuously enters the blanking cavity 12 from the channel 13 at the moment, so that the cutting step is continued, manual operation is not needed, and the working efficiency and the quality of tremella polysaccharide finished products are improved.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (9)

1. A tremella polysaccharide finished product blank equipment, its characterized in that: the cutting machine comprises a cutting box (1) and a pressing mechanism (3), wherein a partition plate (2) is vertically arranged in the cutting box (1), a feeding cavity (11) and a blanking cavity (12) are respectively formed in the inner cavity of the cutting box (1) at two sides of the partition plate (2), and a channel (13) for communicating the feeding cavity (11) with the blanking cavity (12) is formed between the bottom end of the partition plate (2) and the bottom wall of the cutting box (1); a feed inlet (14) communicated with the feed cavity (11) is formed in the top surface of the cutting box (1), and a discharge outlet (15) communicated with the cavity of the blanking cavity (12) is formed in the bottom surface of the cutting box (1); the cutting box (1) is connected with a cutter plate (4) in a covering mode at the discharge hole (15), the cutter plate (4) comprises a plurality of cutting knives (41) which are arranged in a transverse-longitudinal staggered mode, and the material pressing mechanism (3) comprises a pressing plate (31) and a first driving piece (32) which drives the pressing plate (31) to move towards or away from the cutter plate (4).

2. The tremella polysaccharide finished product blanking device as claimed in claim 1, wherein: cutter board (4) with cutting case (1) swing joint, cutter board (4) are connected with leveling mechanism (5), leveling mechanism (5) are used for driving cutter board (4) activity is so that the flattening gets into material on cutter board (4), the height of cutter board (4) is less than cutting case (1) in the height of diapire in feed chamber (11).

3. A tremella polysaccharide finished product blanking device as claimed in claim 2, characterized in that: the cutting box (1) is provided with a movable groove (16) at the bottom of the inner wall of the blanking cavity (12), the cutter plate (4) is vertically and slidably connected in the movable groove (16), and a gap is reserved between the inner wall of the movable groove (16) and the cutter plate (4); the leveling mechanism (5) comprises a stirring piece (51) and a second driving piece (52) which drives the stirring piece (51) to reciprocate vertically, one side of the stirring piece (51) vertically abuts against the side wall of the cutter plate (4), and a plurality of stirring parts (512) are arranged on one surface of the cutter plate (4) vertically at intervals in an abutting manner.

4. A tremella polysaccharide finished product blanking apparatus as claimed in claim 3, wherein: the stirring part (512) is spherical, a rolling groove (513) is formed in the stirring piece (51), and the stirring part (512) is in rolling connection with the rolling groove (513).

5. A tremella polysaccharide finished product blanking apparatus as claimed in claim 3, wherein: the leveling mechanism (5) further comprises an elastic piece (53) arranged in the movable groove (16), one end of the elastic piece (53) is connected to the inner wall of the movable groove (16), the other end of the movable groove (16) is connected to the cutter plate (4), and the elastic piece (53) drives the cutter plate (4) to move upwards.

6. The tremella polysaccharide finished product blanking device as claimed in claim 1, wherein: a cushion pad (33) with elasticity is arranged on one side of the pressing plate (31) facing the cutter plate (4).

7. A tremella polysaccharide finished product blanking apparatus as claimed in claim 3, wherein: the feeding cavity (11) is far away from the inner wall of the blanking cavity (12) and is connected with a guide plate (6), and the guide plate (6) inclines downwards towards the direction of the channel (13).

8. The tremella polysaccharide finished product blanking device as claimed in claim 7, wherein: the guide plate (6) is hinged with the inner wall of the blanking cavity (12), the stirring piece (51) is arranged below the guide plate (6) and close to one end of the channel (13), the top end of the stirring piece (51) is abutted to the guide plate (6), and the second driving piece (52) can drive the guide plate (6) to rotate upwards to be abutted to the top wall of the channel (13) through the stirring piece (51).

9. The tremella polysaccharide finished product blanking device as claimed in claim 8, wherein: install gravity sensor (7) on cutter board (4), when gravity sensor (7) detects that gravity reaches the threshold value, second driver (52) drive stir piece (51) and upwards remove to after deflector (6) butt in passageway (13) roof, first driver (32) drive clamp plate (31) down remove.