CN112557239A

CN112557239A - Device for detecting precipitation amount of dissolved biological capsules

Info

Publication number: CN112557239A
Application number: CN202011576150.9A
Authority: CN
Inventors: 严春香
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-12-28
Filing date: 2020-12-28
Publication date: 2021-03-26

Abstract

The invention relates to a detection device, in particular to a device for detecting the precipitation amount of dissolved biological capsules. The technical problem that solves is to provide a sediment amount detection device for biological capsule after dissolving that can automated inspection sediment amount, independently control the precipitate and drop, deposit drainage simultaneously. A device for detecting the precipitation amount of dissolved biological capsules comprises: the supporting frame is connected to one side of the base; the sedimentation component is arranged between the two sides of the support frame; the stirring component is arranged on the upper part of the supporting frame; the detection assembly is arranged on the upper portion of the base. According to the invention, the rack is driven to move up and down by treading and releasing the pedal, so that the baffle is driven to rotate towards the outer side and the inner side, the effect of simply and freely controlling the opening and closing of the baffle is achieved, the labor and the time are saved, and the efficiency is improved.

Description

Device for detecting precipitation amount of dissolved biological capsules

Technical Field

The invention relates to a detection device, in particular to a device for detecting the precipitation amount of dissolved biological capsules.

Background

Biocapsules were first reported over 50 years ago, and include the biocapsulation of cells, enzymes, drugs, magnetic materials, isotopes, absorbents, hemoglobin, and other materials, and the research on biocapsules has been induced by special interest in biotechnology over the last several decades.

When the biological capsule is tested and tested, the weight of particles in the biological capsule needs to be measured sometimes, the biological capsule needs to be dissolved firstly, after dry precipitates are obtained, the particles are measured again, accurate weight can be obtained, the traditional biological capsule is dissolved, the precipitation amount is detected in multiple steps, the biological capsule is dissolved by water firstly, after water is filtered out, the precipitates are air-dried again, finally, an electronic scale is used for weighing, the process is complicated, long time is consumed, the detection efficiency is low, manual operation is carried out in the whole process, and the physical strength of a user is consumed in a large amount.

In view of the above problems, there is a need to develop a device for detecting the amount of sediment after dissolution of biocapsules, which can automatically detect the amount of sediment, autonomously control the drop of sediment, and drain water during the sedimentation.

Disclosure of Invention

In order to overcome the defects that the detection process is complex and tedious, the manual operation consumes manpower, and the time is wasted in steps in the prior art, the technical problem to be solved is as follows: the device for detecting the precipitation amount after the dissolution of the biological capsule can automatically detect the precipitation amount, autonomously control the precipitation to fall and simultaneously discharge water.

The technical scheme of the invention is as follows: a device for detecting the precipitation amount of dissolved biological capsules comprises: the supporting frame is connected to one side of the base; the sedimentation component is arranged between the two sides of the support frame; the stirring component is arranged on the upper part of the supporting frame; the detection assembly is arranged on the upper portion of the base.

Further, the precipitation component comprises: the loading frame is connected between two sides of one part of the upper side of the supporting frame; the sedimentation frame is connected to the lower side of the charging frame; the filter screen is connected between the precipitation frame and the charging frame; the first connecting rods are symmetrically and rotatably connected between the two sides of the lower part of the support frame; the baffle, the inboard all is connected with the baffle in first connecting rod middle part, contacts each other between the baffle.

Further, the stirring subassembly includes: the servo motor is arranged in the middle of one side of the top of the support frame; the transmission shaft is rotatably connected to the middle of one side of the top of the support frame; the two bevel gears are arranged, one side of an output shaft of the servo motor and the upper side of the transmission shaft are both connected with the bevel gears, and the bevel gears on the front side and the rear side are meshed with each other; stirring vane, transmission shaft middle part and downside all are connected with stirring vane.

Further, the detection assembly comprises: the electronic scale is connected to the middle of one side of the base; the drying frame is connected to the upper side of the middle of the electronic scale; the material loading frame is connected to the upper side of the drying frame and is positioned right below the baffle; the button is arranged in the middle of one side of the base.

Further, still including locking Assembly, locking Assembly includes: one side of the lower part of the support frame is symmetrically connected with the fixed groove block; the sliding blocks are symmetrically connected inside the fixed groove blocks in a sliding manner; the first springs are symmetrically connected between the outer sides of the sliding blocks and the inner parts of the fixed groove blocks; the wedge blocks are connected in the sliding blocks, and the lower parts of the wedge blocks are matched with the outer sides of the parts of the baffle plates.

Further, still including the unblock subassembly, the unblock subassembly includes: the first guide rod is connected to the middle of one side of the base; the pedal is connected to the first guide rod in a sliding manner; the second spring is connected between the pedal and the base and sleeved on the first guide rod; one side of the pedal is symmetrically connected with a second connecting rod; the first guide block is symmetrically connected to one side of the base, and the inner part of the upper side of the first guide block is connected with one side of the second connecting rod in a sliding manner; the third springs are connected between the upper side of the first guide block and one side of the second connecting rod and sleeved on the second connecting rod; and the ejector block is connected to the upper part of one side of the second connecting rod and is matched with the wedge-shaped block.

Further, still including ejection of compact subassembly, ejection of compact subassembly is including: the third connecting rod is connected to the first guide rod in a sliding mode and located on the lower side of the second connecting rod, and a second spring is connected between the third connecting rod and the base and sleeved on the first guide rod; the second guide block is symmetrically connected to one side of the base, and the inner part of the upper side of the second guide block is connected with two sides of one part of the third connecting rod in a sliding manner; the upper sides of one parts of the two sides of the third connecting rod are connected with racks; the middle parts of the first gear and the first connecting rod are connected with a first gear, and the first gear is meshed with the rack.

Further, still including putting the water subassembly, it includes to put the water subassembly: the first water outlet pipe is connected to the middle of one side of the lower part of the charging frame; the two sides of the lower part of the first water outlet pipe are connected with the supporting groove blocks; the lower sides of the inner parts of the supporting groove blocks are connected with second guide rods; the plug is connected between the second guide rods in a sliding mode and is matched with the first water outlet pipe; and the fourth spring is connected between the lower parts of the two sides of the plug and the supporting groove block and sleeved on the second guide rod.

Further, still including the timing subassembly, the timing subassembly includes: the water inlet pipe is connected to the middle of one side of the middle part of the first water outlet pipe; the first one-way valve is connected to one side of the water inlet pipe; the piston cylinder is connected to one side of the first check valve; the first piston is connected inside the piston cylinder in a sliding manner; the pull rod is connected to the lower side of the first piston; the handle is connected between the two sides of the upper part of the pull rod; one side of the lower part of the pull rod is symmetrically connected with a push rod; the fifth spring is connected between the lower side of the piston cylinder and the pull rod and sleeved on the first piston; the second check valve is connected to the middle of one side of the lower part of the piston cylinder; the second water outlet pipe is connected between the lower side of the second one-way valve and the lower part of the first water outlet pipe; the lower side of the plug is symmetrically connected with the first groove blocks; the rotating blocks are rotatably connected in the first groove block and are matched with the push rod; the torsion springs are connected between the rotating block and the inner part; the inner sides of the lower parts of the fixed groove blocks are connected with the stop blocks.

The invention has the beneficial effects that: 1. according to the invention, warm water and the biological capsules are poured into the material loading frame, the servo motor is started to drive the stirring blade to rotate, the dissolution of the biological capsules is accelerated, after particles in the biological capsules are completely precipitated, the warm water is discharged, the first connecting rod is rotated to drive the baffle plate to rotate outwards, precipitates fall into the material loading frame, the button is pressed to dry the precipitates, the weight of the precipitates can be obtained through the electronic scale, and the effect of automatically detecting the precipitation amount after the biological capsules are dissolved is realized through simple operation.

2. According to the invention, the pedal is stepped to drive the ejector block to move downwards and push the wedge block to move outwards, so that the rear side of the baffle can be released, after precipitates completely fall, the ejector block moves upwards to be away from the wedge block under the action of the second spring, and the wedge block is pushed to clamp and fix the rear side of the baffle again under the action of the first spring, so that the effects of automatically clamping and stabilizing and unlocking the baffle are achieved, water and particles which are not completely precipitated are prevented from falling out due to random rotation of the baffle, detection is prevented from being influenced, and manpower is saved.

3. According to the invention, the rack is driven to move up and down by treading and releasing the pedal, so that the baffle is driven to rotate towards the outer side and the inner side, the effect of simply and freely controlling the opening and closing of the baffle is achieved, the labor and the time are saved, and the efficiency is improved.

4. According to the invention, the handle is pulled upwards to drive the first piston to move upwards, so that warm water flows into the piston cylinder, then the first piston moves downwards under the action of the fifth spring to extrude the warm water back to the first water outlet pipe, the push rod moves downwards to finally drive the plug to move downwards in cooperation with the rotating block, so that the warm water is discharged, the effect of slowly discharging the warm water is achieved, a time difference is provided for discharging water and depositing a biological capsule, the time is saved, and the detection efficiency is greatly improved.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of another angle according to the present invention.

Fig. 3 is a first partial structure diagram and a cross-sectional view of the present invention.

Fig. 4 is a second partial structure diagram and a cross-sectional view of the present invention.

FIG. 5 is a third partial structural diagram of the present invention.

Fig. 6 is a fourth partial structural schematic view and a sectional view of the present invention.

Fig. 7 is a schematic structural view and a sectional view of a fifth part of the present invention.

Description of reference numerals: 1. the device comprises a base, 2, a support frame, 3, a settling assembly, 301, a loading frame, 302, a filter screen, 303, a settling frame, 304, a first connecting rod, 305, a baffle plate, 4, a stirring assembly, 401, a servo motor, 402, a bevel gear, 403, a transmission shaft, 404, a stirring blade, 5, a detection assembly, 501, an electronic scale, 502, a drying frame, 503, a loading frame, 504, a button, 6, a locking assembly, 601, a fixed groove block, 602, a sliding block, 603, a first spring, 604, a wedge block, 7, an unlocking assembly, 701, a first guide rod, 702, a second spring, 703, a pedal, 704, a second connecting rod, 705, a top block, 706, a first guide block, 707, a third spring, 8, a discharging assembly, 801, a third connecting rod, 802, a second guide block, 803, a rack, 804, a first gear, 9, a water discharging assembly, 901, a first water outlet pipe, 902, a support groove block, 903, a first connecting rod, a second spring, the device comprises a plug, 904, a second guide rod, 905, a fourth spring, 10, a timing assembly, 1001, a piston cylinder, 1002, a first piston, 1003, a pull rod, 1004, a handle, 1005, a fifth spring, 1006, a first check valve, 1007, a water inlet pipe, 1008, a second check valve, 1009, a second water outlet pipe, 1010, a first groove block, 1011, a rotating block, 1012, a torsion spring, 1013, a stop block, 1014 and a push rod.

Detailed Description

The following description is only a preferred embodiment of the present invention, and does not limit the scope of the present invention.

Example 1

The utility model provides a be used for biological capsule to dissolve back precipitation volume detection device, as shown in figure 1, figure 2 and figure 3, including base 1, support frame 2, precipitation subassembly 3, stirring subassembly 4 and determine module 5, the base 1 upper portion rear side is connected with support frame 2, is equipped with precipitation subassembly 3 between the 2 left and right sides of support frame, and 2 upper portions of support frame are equipped with stirring subassembly 4, and 1 upper portion of base is equipped with determine module 5.

Precipitation component 3 is including the dress material frame 301, filter screen 302, deposit frame 303, head rod 304 and baffle 305, be connected with dress material frame 301 between the anterior left and right sides of 2 upside of support frame, the frame 301 downside of loading is connected with deposits frame 303, deposit frame 303 and be connected with filter screen 302 between the frame 301 of loading, the 2 lower part bilateral symmetry rotary types of support frame are connected with head rod 304, head rod 304 middle part inboard all is connected with baffle 305, the mutual contact between the baffle 305.

Stirring subassembly 4 is including servo motor 401, bevel gear 402, transmission shaft 403 and stirring vane 404, and servo motor 401 is installed in the middle of the 2 top rear sides of support frame, and servo motor 401 output shaft front side is connected with bevel gear 402, and the middle rotary type in the top front side of support frame 2 is connected with transmission shaft 403, and transmission shaft 403 upside is connected with bevel gear 402, and the bevel gear 402 intermeshing of front and back both sides, transmission shaft 403 middle part and downside all are connected with stirring vane 404.

The detection assembly 5 comprises an electronic scale 501, a drying frame 502, a material loading frame 503 and a button 504, the electronic scale 501 is connected to the middle of the rear side of the upper portion of the base 1, the drying frame 502 is connected to the upper side of the middle of the electronic scale 501, the material loading frame 503 is connected to the upper side of the drying frame 502, the material loading frame 503 is located right below the baffle 305, and the button 504 is installed in the middle of the front side of the upper portion of the base 1.

When a user needs to detect the deposition amount of the dissolved biological capsules, firstly, the opening at the rear side of the lower part of the material loading frame 301 is blocked, the capsules and warm water are poured into the material loading frame 301, the undissolved biological capsules fall on the filter screen 302, the warm water is blocked and cannot flow out due to the reason that the baffles 305 are closed at two sides, the servo motor 401 is started, the bevel gear 402 at the rear side is driven to rotate under the action of the output shaft of the servo motor 401, the bevel gears 402 at the front side and the rear side are meshed with each other, so that the bevel gear 402 at the front side and the transmission shaft 403 are driven to rotate, the stirring blade 404 is driven to rotate, the biological capsules and the warm water are continuously stirred, the dissolution of the biological capsules is accelerated, after the biological capsules are dissolved, the servo motor 401 is closed, the stirring blade 404 stops rotating, the shell is left on the filter screen 302, the particles in the inner part are deposited in the baffles, the opening at the rear side of the lower part of the material loading frame 301 is opened, warm water flows out completely, then the first connecting rod 304 is rotated to drive the baffle 305 to rotate outwards, particles in the settling frame 303 are not blocked any more, the particles fall into the material loading frame 503, the button 504 is pressed again, the drying frame 502 is started, the particles with moisture in the material loading frame 503 are completely dried, the number displayed on the electronic scale 501 is the precipitation amount after the biological capsule is dissolved, and the effect of automatically detecting the precipitation amount after the biological capsule is dissolved by simple operation is achieved.

Example 2

On the basis of embodiment 1, as shown in fig. 4, 5, 6 and 7, the locking device further comprises a locking assembly 6, wherein the locking assembly 6 comprises a fixed slot block 601, a sliding block 602, a first spring 603 and a wedge block 604, the fixed slot block 601 is symmetrically connected to the left and right of the front side of the lower portion of the support frame 2, the sliding blocks 602 are symmetrically connected to the front and back of the inside of the fixed slot block 601 in a sliding manner, the first springs 603 are symmetrically connected to the left and right of the outside of the sliding block 602 and the inside of the fixed slot block 601 in a sliding manner, the wedge block 604 is connected to the inside of the sliding block 602, and the lower portion of the wedge.

When the baffle 305 needs to be opened to allow the deposited particles to fall off, the wedge block 604 is pushed to move outwards to drive the sliding block 602 to move outwards, the first spring 603 is compressed, the wedge block 604 moves outwards to not clamp the fixed baffle 305, the first connecting rod 304 can be rotated to drive the baffle 305 to rotate outwards, so that the deposited particles can fall off smoothly, and after the deposited particles fall off completely, the first connecting rod 304 is rotated reversely to drive the baffle 305 to rotate inward to the original position, the wedge block 604 is released manually, the wedge block 604 is not pushed to move outward any more, under the action of the first spring 603, the wedge block 604 is pushed to move inwards, the wedge block 604 is clamped and fixed again, the original position is restored, reciprocating like this, reach the effect of pressing from both sides tight firm baffle 305, prevent that baffle 305 from rotating at will and leading to water and not depositing complete granule and fall out, influence the detection.

Also comprises an unlocking component 7, the unlocking component 7 comprises a first guide rod 701, a second spring 702 and a pedal 703, the middle of the front side of the upper portion of the base 1 is connected with a first guide rod 701, the first guide rod 701 is connected with a pedal 703 in a sliding mode, a second spring 702 is connected between the pedal 703 and the base 1, the second spring 702 is sleeved on the first guide rod 701, the rear side of the pedal 703 is connected with a second connecting rod 704 in a bilateral symmetry mode, the rear side of the upper portion of the base 1 is connected with a first guide block 706 in a bilateral symmetry mode, the inside of the upper side of the first guide block 706 is connected with the rear side of the second connecting rod 704 in a sliding mode, a third spring 707 is connected between the upper side of the first guide block 706 and the rear side of the second connecting rod 704, the third spring 707 is sleeved on the second connecting rod 704, the upper portion of the rear side of the second connecting rod 704 is connected with a top block 705, and the top block 705 is matched with the wedge block 604.

The pedal 703 is stepped down, the second spring 702 is compressed to drive the second connecting rod 704 to move downwards, the third spring 707 is compressed to drive the ejector block 705 to move downwards to eject the wedge block 604 to move outwards to drive the locking assembly 6 to finally loosen the baffle 305 to rotate freely, after the deposited particles completely fall off, the first connecting rod 304 is manually rotated to drive the baffle 305 to move inwards to return to the original position without stepping on the pedal 703, the pedal 703 is pushed to move upwards under the action of the second spring 702, the second connecting rod 704 and the ejector block 705 are pushed to move upwards under the action of the pedal 703 and the third spring 707, the ejector block 705 is far away from the wedge block 604, the wedge block 604 is not pushed outwards any longer, thereby driving the locking assembly 6 to perform the resetting movement, the baffle 305 is fixed and locked again to return to the original state, and the reciprocating is performed in this way, the effect of automatically driving the locking assembly 6 to move is achieved, the baffle 305 is automatically unlocked, and manpower is saved.

Still including ejection of compact subassembly 8, ejection of compact subassembly 8 is including third connecting rod 801, second guide block 802, rack 803 and first gear 804, sliding connection has third connecting rod 801 on first guide bar 701, third connecting rod 801 is located second connecting rod 704 downside, be connected with second spring 702 between third connecting rod 801 and the base 1 this moment, second spring 702 overlaps on first guide bar 701, base 1 upper portion rear side bilateral symmetry is connected with second guide block 802, inside and the third connecting rod 801 rear portion left and right sides sliding connection of second guide block 802 upside, third connecting rod 801 left and right sides rear portion upside all is connected with rack 803, first gear 804 all is connected with first gear 804 in the middle part of first connecting rod 304, first gear 804 and rack 803 intermeshing.

When the pedal 703 is pressed downwards, the second spring 702 is compressed, and will also drive the third connecting rod 801 to move downwards, so as to drive the rack 803 to move downwards, because the rack 803 is meshed with the first gear 804, the first gear 804 and the first connecting rod 304 will be driven to rotate, so as to drive the baffle 305 to rotate outwards, so as to make the deposited particles fall downwards, after the deposited particles completely fall off, the pedal 703 is no longer pressed, under the action of the second spring 702, the pedal 703 is pushed to move upwards, so as to drive the third connecting rod 801 and the rack 803 to move upwards, so as to drive the first gear 804 and the first connecting rod 304 to rotate reversely, so that the baffle 305 rotates inwards, closes again, and returns to the original state, and repeats the above actions, so as to achieve the effect of conveniently driving the first connecting rod 304 to rotate, simply and freely control the opening and closing of the baffle 305, thereby saving manpower and time, the efficiency is improved.

Still including the subassembly 9 that drains, the subassembly 9 that drains is including first outlet pipe 901, support channel block 902, stopper 903, second guide bar 904 and fourth spring 905, be connected with first outlet pipe 901 in the middle of the 301 lower part rear side of loading frame, first outlet pipe 901 lower part left and right sides all is connected with support channel block 902, the inside downside of support channel block 902 all is connected with second guide bar 904, sliding connection has stopper 903 between the second guide bar 904, stopper 903 and first outlet pipe 901 mutually support, all be connected with fourth spring 905 between stopper 903 left and right sides lower part and the support channel block 902, fourth spring 905 overlaps on second guide bar 904.

At first, the plug 903 plugs the first water outlet pipe 901, then the biological capsule and the warm water are poured into the loading frame 301, after the dissolved biological capsule is completely precipitated, the plug 903 is pulled to move downwards, the fourth spring 905 is compressed, the plug 903 leaves the first water outlet pipe 901, the outlet of the first water outlet pipe 901 is not plugged, the warm water in the loading frame 301 and the precipitating frame 303 flows out along the first water outlet pipe 901 and is discharged, precipitated biological capsule particles are finally left, and the effect of automatically controlling the discharge of the warm water is achieved.

The timing assembly 10 comprises a piston cylinder 1001, a first piston 1002, a pull rod 1003, a handle 1004, a fifth spring 1005, a first check valve 1006, a water inlet pipe 1007, a second check valve 1008, a second water outlet pipe 1009, a first groove block 1010, a rotating block 1011, a torsion spring 1012, a stop 1013 and a push rod 1014, wherein the middle of the rear side of the middle part of the first water outlet pipe 901 is connected with the water inlet pipe 1007, the rear side of the water inlet pipe 1007 is connected with the first check valve 1006, the rear side of the first check valve 1006 is connected with the piston cylinder 1001, the interior of the piston cylinder 1001 is connected with the first piston 1002 in a sliding manner, the lower side of the first piston 1002 is connected with the pull rod 1003, the handle 1004 is connected between the left side and the right side of the upper part of the pull rod 1003, the push rod 1014 is symmetrically connected on the left side and the right side of the lower part of the pull rod 1003, the fifth spring 1005 is connected between the lower side of the piston, be connected with second outlet pipe 1009 between second check valve 1008 downside and first outlet pipe 901 lower part, stopper 903 downside bilateral symmetry is connected with first groove block 1010, and the inside equal rotary type of first groove block 1010 is connected with rotatory piece 1011, and rotatory piece 1011 and push rod 1014 mutually support, all is connected with torsion spring 1012 between rotatory piece 1011 and the inside, and fixed groove block 601 lower part inboard all is connected with dog 1013.

After pouring the biocapsules and the warm water into the material loading frame 301, the handle 1004 is held while the biocapsules are dissolved and precipitated, the handle 1004 is pulled to move upwards to drive the pull rod 1003 and the first piston 1002 to move upwards, the fifth spring 1005 is compressed, so that the warm water can flow into the piston cylinder 1001 along the water inlet pipe 1007 continuously through the first check valve 1006, the pull rod 1003 moves upwards to drive the push rod 1014 to move upwards, when the push rod 1014 moves to be in contact with the rotating block 1011, the rotating block 1011 is pushed to rotate clockwise, the torsion spring 1012 deforms, then when the push rod 1014 moves upwards to be far away from the rotating block 1011, the rotating block 1011 is pushed to rotate anticlockwise under the action of the torsion spring 1012 to return to the original state, when the warm water in the piston cylinder 1001 reaches a certain amount, the handle 1004 is loosened, and the pull rod 1003 and the first piston 1002 are pushed to move downwards under the action of the fifth spring 1005, the warm water in the piston cylinder 1001 is squeezed into the second water outlet pipe 1009 through the second check valve 1008, and finally flows back to the first water outlet pipe 901, as the pull rod 1003 also drives the push rod 1014 to move downwards, when the push rod 1014 moves downwards again to be in contact with the rotating block 1011, the rotating block 1011 is pushed to rotate anticlockwise, the torsion spring 1012 deforms, so as to push the first slot block 1010 and the plug 903 to move downwards, the fourth spring 905 is compressed, so that the plug 903 no longer plugs the opening of the first water outlet pipe 901, the warm water flowing into the first water outlet pipe 901 from the second water outlet pipe 1009 is discharged, then the pull rod 1014 drives the push rod 1014 to continue to move downwards, the push rod 1014 is far away from the rotating block 1011, the rotating block 1011 is pulled to rotate clockwise under the action of the torsion spring 1012, the first slot block 1010 and the plug 903 no longer receive the downward pushing force, and the first slot block 1010 and the plug 903 are pushed to move upwards under the action of the fourth spring 905, plug the opening of first outlet pipe 901 again, resume original state, so reciprocal reaches the slow exhaust effect of warm water, for drainage and biological capsule deposit provide the time difference for biological capsule all discharges the warm water when depositing and finishing, save time has improved the efficiency that detects greatly.

The above-mentioned embodiments are merely preferred embodiments of the present invention, which are not intended to limit the scope of the present invention, and therefore, all equivalent changes made by the contents of the claims of the present invention should be included in the claims of the present invention.

Claims

1. A device for detecting the precipitation amount of dissolved biological capsules is characterized by comprising:

the supporting frame (2) is connected to one side of the base (1);

the sedimentation component (3), the sedimentation component (3) is arranged between the two sides of the support frame (2);

the stirring component (4), the stirring component (4) is arranged on the upper part of the support frame (2);

the detection component (5), the detection component (5) is arranged on the upper part of the base (1).

2. The apparatus for measuring the amount of precipitate after dissolution of biocapsules as claimed in claim 1, wherein the precipitation unit (3) comprises:

the loading frame (301), the loading frame (301) is connected between two sides of one part of the upper side of the support frame (2);

the sedimentation frame (303), the sedimentation frame (303) is connected to the lower side of the material loading frame (301);

a filter screen (302), wherein the filter screen (302) is connected between the precipitation frame (303) and the charging frame (301);

the first connecting rods (304) are symmetrically and rotatably connected between the two sides of the lower part of the support frame (2);

the baffle plates (305) are connected to the inner sides of the middle parts of the first connecting rods (304), and the baffle plates (305) are in contact with each other.

3. The apparatus for measuring the amount of precipitate formed after dissolution of biocapsules according to claim 2, wherein the stirring member (4) comprises:

the servo motor (401), the servo motor (401) is installed in the middle of one side of the top of the support frame (2);

the transmission shaft (403), the transmission shaft (403) is rotatably connected to the middle of one side of the top of the support frame (2);

the number of the bevel gears (402) is two, the bevel gears (402) are connected to one side of an output shaft of the servo motor (401) and the upper side of the transmission shaft (403), and the bevel gears (402) on the front side and the rear side are meshed with each other;

stirring vane (404), transmission shaft (403) middle part and downside all are connected with stirring vane (404).

4. The device for detecting the amount of precipitate formed after dissolution of a biocapsule according to claim 3, wherein the detecting unit (5) comprises:

the electronic scale (501), the electronic scale (501) is connected to the middle of one side of the base (1);

the drying frame (502), the drying frame (502) is connected to the upper side of the middle of the electronic scale (501);

the material loading frame (503), the material loading frame (503) is connected to the upper side of the drying frame (502), and the material loading frame (503) is positioned under the baffle (305);

the button (504), button (504) are installed in the middle of one side on base (1).

5. The apparatus for measuring the amount of precipitate formed after dissolution of a biocapsule according to claim 4, further comprising a locking assembly (6), wherein the locking assembly (6) comprises:

one side of the lower part of the support frame (2) is symmetrically connected with the fixed groove block (601);

the sliding blocks (602) are symmetrically and slidably connected inside the fixed groove blocks (601);

the first springs (603) are symmetrically connected between the outer side of the sliding block (602) and the inner part of the fixed groove block (601);

the wedge block (604) is connected in the sliding block (602), and the lower part of the wedge block (604) is matched with the outer side of one part of the baffle (305).

6. The apparatus for detecting the amount of precipitate after dissolution of biological capsule according to claim 5, further comprising an unlocking assembly (7), wherein the unlocking assembly (7) comprises:

the first guide rod (701), the first guide rod (701) is connected to the middle of one side of the base (1);

the pedal (703) is connected to the first guide rod (701) in a sliding manner;

the second spring (702), the second spring (702) is connected between the pedal (703) and the base (1), the second spring (702) is sleeved on the first guide rod (701);

one side of the pedal (703) is symmetrically connected with the second connecting rod (704);

the first guide block (706) is symmetrically connected to one side of the base (1), and the inner part of the upper side of the first guide block (706) is connected with one side of the second connecting rod (704) in a sliding manner;

the third spring (707) is connected between the upper side of the first guide block (706) and one side of the second connecting rod (704), and the third spring (707) is sleeved on the second connecting rod (704);

the top block (705), the top block (705) is connected to the upper portion of one side of the second connecting rod (704), and the top block (705) is matched with the wedge block (604).

7. The apparatus for detecting the amount of precipitate after dissolution of biocapsules according to claim 6, further comprising an ejection assembly (8), wherein the ejection assembly (8) comprises:

the third connecting rod (801) is connected to the first guide rod (701) in a sliding mode, the third connecting rod (801) is located on the lower side of the second connecting rod (704), a second spring (702) is connected between the third connecting rod (801) and the base (1) at the moment, and the second spring (702) is sleeved on the first guide rod (701);

the second guide block (802) is symmetrically connected to one side of the base (1), and the inner part of the upper side of the second guide block (802) is connected with two sides of one part of the third connecting rod (801) in a sliding manner;

the upper sides of two sides of the third connecting rod (801) are respectively connected with a rack (803);

the middle parts of the first gear (804) and the first connecting rod (304) are connected with the first gear (804), and the first gear (804) is meshed with the rack (803).

8. The apparatus for detecting the amount of precipitate formed after dissolution of a biocapsule according to claim 7, further comprising a water discharging assembly (9), wherein the water discharging assembly (9) comprises:

the first water outlet pipe (901), the first water outlet pipe (901) is connected to the middle of one side of the lower part of the charging frame (301);

the supporting groove blocks (902) are connected to the two sides of the lower part of the first water outlet pipe (901);

the lower sides of the insides of the supporting groove blocks (902) are connected with second guide rods (904);

the plug (903), the plug (903) is connected between the second guide rods (904) in a sliding mode, and the plug (903) is matched with the first water outlet pipe (901);

and a fourth spring (905) is connected between the lower parts of the two sides of the plug (903) and the support groove block (902), and the fourth spring (905) is sleeved on the second guide rod (904).

9. The apparatus for detecting the amount of precipitate after dissolution of biocapsules according to claim 8, further comprising a timing assembly (10), wherein the timing assembly (10) comprises:

the water inlet pipe (1007), the water inlet pipe (1007) is connected to the middle of one side of the middle part of the first water outlet pipe (901);

the first one-way valve (1006), the first one-way valve (1006) is connected to one side of the water inlet pipe (1007);

the piston cylinder (1001), the piston cylinder (1001) is connected to one side of the first check valve (1006);

the first piston (1002), the first piston (1002) is connected in a sliding way inside the piston cylinder (1001); a pull rod (1003), wherein the pull rod (1003) is connected to the lower side of the first piston (1002);

a handle (1004), wherein the handle (1004) is connected between the two sides of the upper part of the pull rod (1003);

one side of the lower part of the pull rod (1003) is symmetrically connected with the push rod (1014);

the fifth spring (1005), the fifth spring (1005) is connected between underside of the piston cylinder (1001) and the tie rod (1003), the fifth spring (1005) is sleeved on the first piston (1002);

the second check valve (1008), the second check valve (1008) is connected to the middle of one side of the lower part of the piston cylinder (1001);

a second water outlet pipe (1009), wherein the second water outlet pipe (1009) is connected between the lower side of the second one-way valve (1008) and the lower part of the first water outlet pipe (901);

the lower side of the plug (903) is symmetrically connected with the first groove block (1010);

the rotating blocks (1011) are rotatably connected inside the first groove block (1010), and the rotating blocks (1011) are matched with the push rod (1014);

the torsion spring (1012) is connected between the rotating block (1011) and the inner part;

the inner sides of the lower parts of the fixed groove blocks (601) are connected with the stop blocks (1013).