CN113546442B - Reinforced pinellia ternata of ration soaks pond - Google Patents

Abstract

The invention discloses a pinellia ternate infiltration tank capable of realizing quantitative charging, which comprises a charging box and an infiltration tank, wherein the charging box is arranged at the top of the infiltration tank, a processing box is arranged inside the charging box, a charging opening is arranged at the top of the charging box, a conversion frame is arranged inside the processing box, the conversion frame is V-shaped, a bottom plate is arranged at the bottom of the conversion frame, a first partition plate is arranged at the top of the bottom plate, and a second partition plate is arranged at the bottom of the bottom plate. According to the pinellia ternate infiltration tank with the quantitative feeding function, pinellia ternate can be quantitatively fed through the conversion frame, the first supporting plate and the second supporting plate, the pinellia ternate can be better soaked in the middle and the middle of summer in the subsequent steps, the first partition plate and the second partition plate are respectively lifted and contracted back and forth through the up-and-down movement of the push rod motor, so that the pinellia ternate is quantitatively transferred, the contact surface between the pinellia ternate and water can be increased through the arc-shaped circular plate relative to a flat plate, the contact rate between the pinellia ternate is reduced, and the infiltration efficiency is increased.

Description

Reinforced pinellia ternata of ration soaks pond

Technical Field

The invention relates to the field of traditional Chinese medicine equipment, in particular to a pinellia ternate infiltration tank with quantitative charging.

Background

Raw pinellia ternate is toxic and can be administered to throat to cause vomiting, sore throat and aphonia, generally is not suitable for oral administration and is usually used for external application, but can be decocted as a prescription and is not suitable for pill and powder, so before the pinellia ternate is used, the pinellia ternate needs to be soaked and processed together with water or other medicines, so that the irritation of the pinellia ternate is reduced, the pinellia ternate is soaked and rinsed for a long time in the processing process, toxic components of the pinellia ternate are insoluble or insoluble in water, so the purpose of detoxification cannot be achieved by soaking, and in the soaking process, the loss of water-soluble components is about 88.1%, the loss of alcohol-soluble components is 87.5%, and the loss of alkaloid is 50%, so the water soaking time is considered to be shortened, so that the loss of effective components is avoided.

In the process of soaking pinellia ternate, if a large amount of pinellia ternate is soaked in the half-summer, the soaking effect of the pinellia ternate is insufficient, and the effect deviates from the expected effect, so that the pinellia ternate should be soaked in a small amount for many times, the soaking time of the pinellia ternate is strictly controlled, the loss of effective components of the pinellia ternate is avoided, meanwhile, the pinellia ternate floats on the water surface in the soaking process, the pinellia ternate is stacked in the soaking process due to the limited volume of the soaking pool, and the soaking effect of the pinellia ternate at the top layer and the soaking effect of the pinellia ternate at the lower layer cannot be guaranteed to be the same.

Disclosure of Invention

The invention mainly aims to provide a pinellia ternate soaking pool with quantitative feeding, wherein the soaking time and the soaking amount of pinellia ternate are controlled, when the pinellia ternate is soaked to a certain time degree, the soaked pinellia ternate is moved out, meanwhile, the feeding is carried out for soaking the next batch of pinellia ternate, the soaking degree and the soaking efficiency of the pinellia ternate can be effectively improved, the loss of effective components during the soaking of the pinellia ternate can be avoided, the pinellia ternate at the top layer and the lower layer of the soaking pool can be fully soaked as far as possible, the soaking time and the soaking efficiency are ensured, and the problems in the background technology can be effectively solved.

In order to achieve the purpose, the invention adopts the technical scheme that:

the utility model provides a reinforced tuber of pinellia of ration infiltration pond, includes the charging box and soaks the pond, the top at soaking the pond is installed to the charging box, the inside of charging box is equipped with handles the case, the dog-house is installed at the top of charging box, the inside of handling the case is equipped with the conversion frame, the conversion frame is "V" type, the bottom plate is installed to the bottom of conversion frame, first baffle is installed at the top of bottom plate, the second baffle is installed to the bottom of bottom plate.

Further, first baffle and second baffle set up the inside at the charging box, the bottom of first baffle is equipped with first backup pad, the bottom of second baffle is equipped with the second backup pad, first backup pad and second backup pad are connected with handling the case lateral wall, the fluting has all been seted up to one side of first baffle and second baffle, the head rod is all installed at the front and the back of first baffle and second baffle, head rod and bottom plate that first baffle and second baffle were equipped with rotate to be connected, the second connecting rod is installed in the front of conversion frame, second connecting rod both ends and charging box link to each other.

Further, the mount pad is installed to the other end of conversion frame, a piece is installed at the top of mount pad, the loop bar is installed through the third connecting rod at the both ends of a piece, the internally mounted who handles the case has the push rod motor, the push rod of push rod motor and the bottom of loop bar are connected.

Further, the dump box is installed to one side of infiltration pond, the second spout is installed to one side of infiltration pond, the surface mounting of second spout has the slider, the axis of rotation is installed to one side of slider, the arc is installed to one side of axis of rotation, the filtration pore has been seted up on the surface of arc, the size in filtration pore is not more than, the surface mounting in filtration pore has the flashboard, the position of arc and the position of dump box are corresponding.

Furthermore, a first sliding groove is arranged inside the second supporting plate, a moving block is arranged inside the first sliding groove, a first rotating rod is arranged on the surface of the moving block, a spring is arranged at one end of the first rotating rod, baffle plates are arranged on two sides of the spring, and one end of each baffle plate is connected with the surface of the moving block.

Furthermore, a third rotating rod is installed inside the second partition plate, a fixture block is installed on the surface of the third rotating rod, the fixture block is triangular, a second rotating rod is installed at the bottom of the fixture block, and the second rotating rod is connected with the other end of the spring.

Furthermore, an elastic rotating shaft is installed on one side of the feeding box, an inclined plate is installed on the surface of the elastic rotating shaft, and the position of the inclined plate corresponds to that of the first partition plate.

Further, the device comprises the following steps:

step A: firstly, pinellia ternate is put into the feeding port, the push rod motor is controlled to move downwards, the push rod motor drives the support block at the moment, the mounting seat and the conversion frame are further driven to move downwards, the second partition plate is forwards offset to the side of the feeding box, the first partition plate is backwards offset, the first connecting rod plays a role in supporting and rotating, the first support plate and the second support plate respectively play a role in supporting the first partition plate and the second partition plate, and a gap is generated between the first partition plate and the side of the inclined plate at the moment, so that the pinellia ternate can fall onto the surface of the second partition plate from the gap between the first partition plate and the inclined plate;

and B: when the tuber of pinellia dropped to the surface of second baffle, make the push rod motor upwards remove this moment, the push rod motor drives loop bar and prop up the piece, and then drive conversion frame and bottom plate and rotate, make first baffle be close to one side of swash plate, the avris of charging box is kept away from to the second baffle simultaneously, at this in-process, second baffle and second backup pad produce relative displacement, the movable block that is equipped with slides on the surface of first spout, when moving to spring deformation when the biggest, the spring can support the second bull stick, promote the fixture block, form slope is released to the fixture block, can push out the tuber of pinellia placed on second baffle surface and make it drop to the arc surface.

And C: when pinellia ternate falls to the surface of the arc-shaped plate, the gate valve is opened, pinellia ternate leaks from the inside of the filter hole, the gate valve on the surface of the filter hole is closed at the moment, the sliding block moves downwards from the second sliding groove, the arc-shaped plate is extruded to the half summer at the moment, pinellia ternate enters water and is soaked in the half summer, when the pinellia ternate is soaked to a certain degree, the gate valve on the surface of the filter hole is opened, the sliding block moves upwards on the surface of the second sliding groove, the arc-shaped plate is driven to rotate through the rotating shaft, the arc-shaped plate and the side of the soaking pool are kept in a vertical state, meanwhile, the sliding block is controlled to drive the arc-shaped plate to move downwards, soaked expanded pinellia ternate is fished in the moving process, at the moment, the bad soaking degree can leak out of the filter hole, the arc-shaped plate is driven to rotate through the rotating shaft at the moment, and the soaked pinellia ternate is transferred to the accumulation box.

Compared with the prior art, the invention has the following beneficial effects:

1. the pinellia ternate can be quantitatively fed through the conversion frame, the first supporting plate and the second supporting plate, pinellia ternate can be better soaked in the subsequent steps, the first partition plate and the second partition plate respectively ascend and contract forwards through the up-and-down movement of the push rod motor, so that the pinellia ternate is quantitatively transferred, meanwhile, the second supporting plate and the second partition plate slide relatively in the transferring process, so that the clamping block can be upwards paid out, the clamping block can generate pressure on the pinellia ternate on the surface of the second partition plate, and the pinellia ternate can be more conveniently transferred;

2. the arc round plate is arranged, so that the contact surface between the pinellia ternate and water can be increased relative to the flat plate, the contact rate between the pinellia ternate is reduced, and the infiltration efficiency is increased; guarantee as far as possible be in the pinellia ternate of fermentation vat top layer and lower floor and can both obtain abundant soaking, guarantee its soak time and soaking efficiency, and simultaneously, after water inflation is met to the pinellia ternate, through foraminiferous arc, conveniently salvage the pinellia ternate, at the in-process of salvaging, also can filter unnecessary moisture, when the pinellia ternate soaks to the certain time degree, the pinellia ternate that finishes will soak shifts out, reinforced the soaking of carrying out next batch pinellia ternate simultaneously, can effectual infiltration degree and the efficiency that improves the pinellia ternate, the loss of effective component when also can avoid the pinellia ternate to soak simultaneously.

Drawings

In order to more clearly illustrate the technical solution of the present invention, the drawings needed to be used in the technical description of the present invention will be briefly introduced below, and it is apparent that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive labor.

FIG. 1 is a schematic view of the overall structure of a pinellia ternata soaking pool with quantitative charging according to the present invention;

FIG. 2 is a schematic view of the internal structure of a pinellia ternata soaking pool with quantitative charging according to the present invention;

FIG. 3 is a schematic structural view of a conversion frame of a pinellia ternata soaking pool for quantitative charging according to the present invention;

FIG. 4 is a schematic structural diagram of an arc-shaped plate of a pinellia tuber infiltration tank for quantitative charging according to the present invention;

FIG. 5 is a schematic structural diagram of a switching rack for feeding pinellia ternate in a dosing pinellia ternate infiltration tank according to the present invention;

FIG. 6 is a schematic structural diagram of the pinellia ternate transferring tank of the quantitatively feeding pinellia ternate infiltration tank of the present invention;

FIG. 7 is a schematic structural view of a fixture block of the pinellia ternata soaking pool with quantitative charging according to the present invention, when the second partition plate and the second supporting plate are in the initial state;

fig. 8 is a schematic structural diagram of a clamping block when the second partition plate and the second supporting plate of the constant-feed pinellia tuber infiltration tank slide relatively.

In the figure: 1. a feed box; 2. soaking in a pool; 3. a stacking box; 4. a feeding port; 5. a treatment tank; 6. a conversion frame; 7. a first support plate; 8. a second support plate; 801. a first chute; 802. a moving block; 803. a first rotating lever; 804. a spring; 805. a baffle plate; 806. a second rotating rod; 807. a third rotating rod; 9. an elastic rotating shaft; 10. a sloping plate; 11. a push rod motor; 12. an arc-shaped plate; 13. filtering holes; 14. a second chute; 15. a slider; 16. a rotating shaft; 17. a first separator; 18. a second separator; 19. a clamping block; 20. grooving; 21. a first connecting rod; 22. a base plate; 23. a second connecting rod; 24. a mounting seat; 25. a third connecting rod; 26. a loop bar; 27. and (7) supporting the blocks.

Detailed Description

The present invention will be further described with reference to the following detailed description, wherein the drawings are for illustrative purposes only and are not intended to be limiting, wherein certain elements may be omitted, enlarged or reduced in size, and are not intended to represent the actual dimensions of the product, so as to better illustrate the detailed description of the invention.

Example 1

As shown in fig. 1, fig. 2, fig. 3, fig. 5, fig. 6, fig. 7 and fig. 8, a quantitatively feeding pinellia tuber infiltration tank comprises a feeding box (1) and an infiltration tank (2), wherein the feeding box (1) is installed at the top of the infiltration tank (2), a treatment box (5) is arranged inside the feeding box (1), a feeding port (4) is installed at the top of the feeding box (1), a conversion frame (6) is arranged inside the treatment box (5), the conversion frame (6) is of a V shape, a bottom plate (22) is installed at the bottom of the conversion frame (6), a first partition plate (17) is installed at the top of the bottom plate (22), and a second partition plate (18) is installed at the bottom of the bottom plate (22).

First baffle (17) and second baffle (18) set up the inside in addition tank (1), the bottom of first baffle (17) is equipped with first backup pad (7), the bottom of second baffle (18) is equipped with second backup pad (8), first backup pad (7) and second backup pad (8) are connected with handling case (5) lateral wall, fluting (20) have all been seted up to one side of first baffle (17) and second baffle (18), head rod (21) are all installed at the front and the back of first baffle (17) and second baffle (18), head rod (21) and bottom plate (22) through being equipped with rotate to be connected first baffle (17) and second baffle (18), second connecting rod (23) are installed in the front of conversion frame (6), second connecting rod (23) both ends link to each other with addition tank (1).

The other end of conversion frame (6) is installed mount pad (24), and a piece (27) is installed at the top of mount pad (24), and loop bar (26) are installed through third connecting rod (25) at the both ends of a piece (27), and the internally mounted who handles case (5) has push rod motor (11), and the push rod of push rod motor (11) is connected with the bottom of loop bar (26).

A first sliding groove (801) is arranged in the second supporting plate (8), a moving block (802) is arranged in the first sliding groove (801), a first rotating rod (803) is arranged on the surface of the moving block (802), a spring (804) is arranged at one end of the first rotating rod, blocking plates (805) are arranged on two sides of the spring (804), and one end of each blocking plate (805) is connected with the surface of the moving block (802).

A third rotating rod (807) is installed inside the second partition plate (18), a clamping block (19) is installed on the surface of the third rotating rod (807), the clamping block (19) is triangular, a second rotating rod (806) is installed at the bottom of the clamping block (19), and the second rotating rod (806) is connected with the other end of the spring (804).

One side of the feeding box (1) is provided with an elastic rotating shaft (9), the surface of the elastic rotating shaft (9) is provided with an inclined plate (10), and the position of the inclined plate (10) corresponds to the position of the first partition plate (17).

By adopting the technical scheme: the pinellia ternate is quantitatively fed through the arranged conversion frame (6), the first supporting plate (7) and the second supporting plate (8), the pinellia ternate can be better soaked in the middle and the middle of summer in the subsequent steps, the first partition plate (17) and the second partition plate (18) are respectively lifted and contracted back and forth through the up-and-down movement of the push rod motor (11), so that the pinellia ternate is quantitatively transferred, meanwhile, the second supporting plate (8) and the second partition plate (18) slide relatively in the transferring process, so that the clamping block (19) is upwards paid out, the clamping block (19) can generate pressure on the pinellia ternate on the surface of the second partition plate (18), and the pinellia ternate can be transferred more conveniently;

pinellia ternate is thrown from a feeding port (4), a push rod motor (11) is controlled to move downwards, at the moment, the push rod motor (11) drives a support block (27) to further drive a mounting seat (24) and a conversion frame (6) to move downwards, as shown in figure 5, a second partition plate (18) shifts forwards to the side of a feeding box (1), a first partition plate (17) shifts backwards, a first connecting rod (21) plays a role in supporting and rotating, a first support plate (7) and a second support plate (8) respectively play a role in supporting the first partition plate (17) and the second partition plate (18), at the moment, a gap is generated between the side of the first partition plate (17) and the side of an inclined plate (10), so that pinellia ternate can fall to the surface of the second partition plate (18) from the gap between the first partition plate (17) and the inclined plate (10), and when the pinellia ternate falls to the surface of the second partition plate (18), the push rod motor (11) moves upwards, the push rod motor (11) drives the loop bar (26) and the supporting block (27) to further drive the conversion frame (6) and the bottom plate (22) to rotate, as shown in fig. 6, the first partition plate (17) is close to one side of the inclined plate (10), at the moment, the first partition plate (17) extrudes the inclined plate (10), the inclined plate (10) drives the elastic rotating shaft (9) to rotate, so that additional pinellia ternate is ejected out to be separated from a cavity formed between the conversion frame (6) and the first partition plate (17) and the second partition plate (18), meanwhile, the second partition plate (18) is far away from the side of the charging box (1), in the process, as shown in fig. 7 and 8, the second partition plate (18) and the second supporting plate (8) generate relative displacement, a moving block (802) is arranged to slide on the surface of the first chute (801), and when the spring (804) moves to the maximum deformation, the spring (804) can support the second rotating rod (806), the clamping block (19) is pushed, the clamping block (19) is pushed out to form a slope, and the pinellia ternate placed on the surface of the second partition plate (18) can be pushed out to be dropped onto the surface of the arc-shaped plate (12).

Example 2

As shown in fig. 1 and 4, a reinforced tuber of pinellia of ration infiltration pond, including filling box (1) and infiltration pond (2), the top of infiltrating pond (2) is installed in filling box (1), the inside of filling box (1) is equipped with handles case (5), dog-house (4) are installed at the top of filling box (1), the inside of handling case (5) is equipped with conversion frame (6), conversion frame (6) are "V" type, bottom plate (22) are installed to the bottom of conversion frame (6), first baffle (17) are installed at the top of bottom plate (22), second baffle (18) are installed to the bottom of bottom plate (22).

Stacker (3) are installed to one side of infiltration pond (2), second spout (14) are installed to one side of infiltration pond (2), the surface mounting of second spout (14) has slider (15), axis of rotation (16) are installed to one side of slider (15), arc (12) are installed to one side of axis of rotation (16), filtration pore (13) have been seted up on the surface of arc (12), the size of filtration pore (13) is not more than, the surface mounting of filtration pore (13) has the flashboard, the position of arc (12) and the position of stacker (3) are corresponding.

By adopting the technical scheme: the arc-shaped plate (12) is arranged, so that the contact surface between the pinellia ternate and water can be increased relative to a flat plate, the contact rate between the pinellia ternate is reduced, and the infiltration efficiency is increased; the pinellia ternate is ensured to be fully soaked at the top layer and the lower layer of the soaking pool as much as possible, the soaking time and the soaking efficiency are ensured, meanwhile, after the pinellia ternate swells in water, the pinellia ternate is convenient to salvage through the arc-shaped plate (12) with the holes, in the process of salvage, redundant moisture can be filtered, when the pinellia ternate is soaked to a certain time degree, the soaked pinellia ternate is moved out, meanwhile, the pinellia ternate is added for soaking of the next batch of pinellia ternate, the soaking degree and the efficiency of the pinellia ternate can be effectively improved, meanwhile, the loss of effective components during soaking of the pinellia ternate can be avoided, when the pinellia ternate falls to the surface of the arc-shaped plate (12), the gate valve is opened, the pinellia ternate leaks from the inside of the filtering hole (13), the gate valve on the surface of the filtering hole (13) is closed at the moment, the sliding block (15) moves downwards from the second sliding chute (14), and the arc-shaped plate (12) is extruded in half summer at the moment, make the tuber pinellia get into aqueous, soak half summer, when soaking to a certain extent, open the gate valve on filtration pore (13) surface, move on second spout (14) surface through slider (15), drive arc (12) through axis of rotation (16) and rotate, make arc (12) and soak pond (2) avris and keep vertical state, control slider (15) drive arc (12) downstream simultaneously, the expanded tuber pinellia who will soak in the in-process of removal is dragged for, at this moment, spill in filtration pore (13) can be followed to the not good ability of soaking degree, drive arc (12) through axis of rotation (16) this moment and rotate, it can to shift to accumulation box (3) with the tuber pinellia who soaks.

The pinellia ternate soaking pool with quantitative charging is characterized in that pinellia ternate is firstly thrown from a feeding port (4) when the pinellia ternate soaking pool is used, a push rod motor (11) is controlled to move downwards, at the moment, the push rod motor (11) drives a support block (27) and further drives a mounting seat (24) and a conversion frame (6) to move downwards, so that a second partition plate (18) deflects forwards to the side of a charging box (1), a first partition plate (17) deflects backwards, a first connecting rod (21) plays a role in supporting and rotating, a first support plate (7) and a second support plate (8) respectively play a role in supporting the first partition plate (17) and the second partition plate (18), at the moment, a gap is formed between the first partition plate (17) and the side of an inclined plate (10), so that pinellia ternate can fall to the surface of the second partition plate (18) from the gap between the first partition plate (17) and the inclined plate (10), when pinellia ternate falls to the surface of the second partition plate (18), the push rod motor (11) is enabled to move upwards at the moment, the push rod motor (11) drives the sleeve rod (26) and the support block (27) to further drive the conversion frame (6) and the bottom plate (22) to rotate, the first partition plate (17) is enabled to be close to one side of the inclined plate (10), meanwhile, the second partition plate (18) is far away from the side of the charging box (1), in the process, the second partition plate (18) and the second support plate (8) generate relative displacement, the moving block (802) arranged slides on the surface of the first sliding groove (801), when the spring (804) deforms to the maximum, the spring (804) can support the second rotating rod (806), the fixture block (19) is pushed out to form a slope, pinellia ternate placed on the surface of the second partition plate (18) can be pushed out to enable the pinellia ternate to fall to the surface of the arc-shaped plate (12), when pinellia ternate falls to the surface of the arc-shaped plate (12), a gate valve is opened to enable pinellia ternate to leak from the interior of the filter hole (13), the gate valve on the surface of the filter hole (13) is closed, the sliding block (15) moves downwards from the second sliding groove (14), the arc-shaped plate (12) is extruded in the middle and half summers at the moment, pinellia ternate enters water to be infiltrated in the middle and half summers, when pinellia ternate is infiltrated to a certain degree, the gate valve on the surface of the filter hole (13) is opened, the sliding block (15) moves on the surface of the second sliding groove (14), the arc-shaped plate (12) is driven to rotate through the rotating shaft (16), the arc-shaped plate (12) and the infiltration tank (2) are kept in a vertical state, the sliding block (15) is controlled to drive the arc-shaped plate (12) to move downwards, the infiltrated expanded pinellia ternate is fished up in the moving process, at the moment, poor infiltration degree can leak from the filter hole (13), and the arc-shaped plate (12) is driven to rotate through the rotating shaft (16), transferring the soaked pinellia ternate to a stacking box (3).

The foregoing shows and describes the general principles and broad features of the present invention and advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (2)

1. A pinellia ternata infiltration tank capable of realizing quantitative charging comprises a feeding box and an infiltration tank, wherein the feeding box is mounted at the top of the infiltration tank, a processing box is arranged inside the feeding box, and a feeding port is mounted at the top of the feeding box; the first partition plate and the second partition plate are arranged inside the feeding box, a first supporting plate is arranged at the bottom of the first partition plate, a second supporting plate is arranged at the bottom of the second partition plate, the first supporting plate and the second supporting plate are connected with the side wall of the treatment box, slots are formed in one sides of the first partition plate and the second partition plate, first connecting rods are arranged on the front surface and the back surface of the first partition plate and the back surface of the second partition plate, the first partition plate and the second partition plate are rotatably connected with the bottom plate through the first connecting rods, a second connecting rod is arranged on the front surface of the conversion frame, and two ends of the second connecting rod are connected with the feeding box; the other end of the conversion frame is provided with an installation seat, the top of the installation seat is provided with a support block, two ends of the support block are provided with loop bars through third connecting rods, a push rod motor is arranged in the treatment box, and a push rod of the push rod motor is connected with the bottom of the loop bar; a stacking box is installed on one side of the infiltration tank, a second chute is installed on one side of the infiltration tank, a sliding block is installed on the surface of the second chute, a rotating shaft is installed on one side of the sliding block, an arc-shaped plate is installed on one side of the rotating shaft, a filtering hole is formed in the surface of the arc-shaped plate, a flashboard is installed on the surface of the filtering hole, and the position of the arc-shaped plate corresponds to the position of the stacking box; a first sliding groove is arranged in the second supporting plate, a moving block is arranged in the first sliding groove, a first rotating rod is arranged on the surface of the moving block, a spring is arranged at one end of the first rotating rod, baffle plates are arranged on two sides of the spring, and one end of each baffle plate is connected with the surface of the moving block; a third rotating rod is arranged in the second partition plate, a fixture block is arranged on the surface of the third rotating rod, the fixture block is triangular, a second rotating rod is arranged at the bottom of the fixture block, and the second rotating rod is connected with the other end of the spring; an elastic rotating shaft is installed on one side of the feeding box, an inclined plate is installed on the surface of the elastic rotating shaft, and the position of the inclined plate corresponds to the position of the first partition plate.

2. The dosing pinellia ternata infiltration tank according to claim 1, wherein: the device comprises the following steps:

step A: firstly, pinellia ternate is put into the feeding port, the push rod motor is controlled to move downwards, the push rod motor drives the support block at the moment, the mounting seat and the conversion frame are further driven to move downwards, the second partition plate is forwards offset to the side of the feeding box, the first partition plate is backwards offset, the first connecting rod plays a role in supporting and rotating, the first support plate and the second support plate respectively play a role in supporting the first partition plate and the second partition plate, and a gap is generated between the first partition plate and the side of the inclined plate at the moment, so that the pinellia ternate can fall onto the surface of the second partition plate from the gap between the first partition plate and the inclined plate;

and B, step B: when pinellia ternate falls to the surface of the second partition plate, the push rod motor is enabled to move upwards at the moment, the push rod motor drives the sleeve rod and the support block, the conversion frame and the bottom plate are further driven to rotate, the first partition plate is enabled to be close to one side of the inclined plate, meanwhile, the second partition plate is far away from the side of the charging box, in the process, the second partition plate and the second support plate generate relative displacement, the moving block is arranged to slide on the surface of the first sliding groove, when the spring is moved to the maximum deformation, the spring can support the second rotating rod to push the clamping block, the clamping block is pushed out to form a slope, and pinellia ternate placed on the surface of the second partition plate can be pushed out to fall onto the surface of the arc-shaped plate;

and C: when pinellia ternate falls to the surface of the arc-shaped plate, the gate valve is opened, pinellia ternate leaks from the inside of the filter hole, the gate valve on the surface of the filter hole is closed at the moment, the sliding block moves downwards from the second sliding groove, the arc-shaped plate is extruded to the half summer at the moment, pinellia ternate enters water and is soaked in the half summer, the gate valve on the surface of the filter hole is opened, the sliding block moves upwards on the surface of the second sliding groove, the arc-shaped plate is driven to rotate through the rotating shaft, the arc-shaped plate and the side of the soaking pool are kept in a vertical state, meanwhile, the sliding block is controlled to drive the arc-shaped plate to move downwards, soaked expanded pinellia ternate is fished up in the moving process, at the moment, the bad soaking degree can be leaked from the filter hole, at the moment, the arc-shaped plate is driven to rotate through the rotating shaft, and the soaked pinellia ternate is transferred to the accumulation box.

Images