CN114534282B

CN114534282B - Device for preparing traditional Chinese medicine composition for treating heart failure

Info

Publication number: CN114534282B
Application number: CN202210217230.8A
Authority: CN
Inventors: 张洋; 杨琦; 方海亮; 孙思凡; 刘晓宇; 郑金玲
Original assignee: Second Hospital of Dalian Medical University
Current assignee: Second Hospital of Dalian Medical University
Priority date: 2022-03-07
Filing date: 2022-03-07
Publication date: 2023-10-27
Anticipated expiration: 2042-03-07
Also published as: CN114534282A

Abstract

The invention relates to the field of processing of traditional Chinese medicine compositions, in particular to a device for preparing a traditional Chinese medicine composition for treating heart failure. The technical problems are as follows: in the process of evaporating the mixed solution by the existing equipment, part of the mixed solution is carried out together by steam, so that the content of the prepared concentrated solution is lower than a preset value. The technical proposal is as follows: a preparation device of a Chinese medicinal composition for treating heart failure comprises a tank body, a filter assembly, etc.; the upper side of the inner wall of the tank body is provided with a filter component. When the device is used, the mixed solution which is injected from one side to the upper side of the split flow cylinder is automatically stirred into circular distribution, so that the mixed solution flowing through the split flow cylinder is uniformly distributed in a circular shape, a solution film is formed, the mixed solution which remains in steam is automatically filtered and collected, waste is avoided, the problem of poor absorption performance caused by incapability of rebounding the local position of a sponge block due to long-time extrusion is avoided, and the phenomenon of local flow interruption of the mixed solution flowing downwards in a circular shape is avoided.

Description

Device for preparing traditional Chinese medicine composition for treating heart failure

Technical Field

The invention relates to the field of processing of traditional Chinese medicine compositions, in particular to a device for preparing a traditional Chinese medicine composition for treating heart failure.

Background

The Chinese traditional medicine theory is used for guiding collection, processing and preparation, illustrating the action mechanism, and guiding the clinical application of medicines, which are generally called traditional Chinese medicines, wherein the traditional Chinese medicines mainly come from natural medicines and processed products thereof, including plant medicines, animal medicines, mineral medicines and partial chemical and biological products.

In the prior art, one of the traditional Chinese medicine compositions for treating acute heart failure is prepared by the procedures of cleaning, mixing decoction, filtering, evaporating and the like, when the existing equipment is used for evaporating the filtered mixed solution, the mixed solution is firstly injected into an evaporation container through a pipeline, then the mixed solution is scraped into a film shape for heating, excessive moisture in the mixed solution is removed through evaporation, in the evaporation process, steam can bring part of the mixed solution together, the content of the prepared concentrated solution is lower than a preset value, the material is wasted, the solution proportion is seriously affected, meanwhile, part of traditional Chinese medicine residues exist in the mixed solution, the edge of a distributor is blocked, the mixed solution flowing through the edge of the distributor is blocked, the heating and evaporating procedures are seriously affected, and the efficiency is greatly reduced.

Therefore, it is necessary to design a device for preparing a traditional Chinese medicine composition for treating heart failure.

Disclosure of Invention

In order to overcome the defect that the content of the prepared concentrated solution is lower than a preset value because part of mixed solution is carried out together by steam in the process of evaporating the mixed solution by the existing equipment, the invention provides a preparation device of a traditional Chinese medicine composition for treating heart failure.

The technical proposal is as follows: the utility model provides a traditional chinese medicine pharmaceutical composition preparation facilities of treatment heart failure, which comprises a first support frame, the jar body, the top cap, the second support frame, the condenser, first pipeline, the side cap, filter element, evaporating module, drive assembly, edulcoration subassembly and feed supplement subassembly, the jar body is fixedly connected with at first support frame middle part, jar body top fixedly connected with top cap, the second support frame is installed in first support frame left side, the condenser is installed at second support frame inside middle part, condenser top intercommunication has first pipeline, first pipeline is linked together with jar body, the upper portion of jar body right side is pegged graft and is had the side cap, filter element for carrying out filterable to steam is installed to jar body inner wall upside, evaporating module is connected with the top cap, the drive assembly who is used for driving is installed to jar body inside upside, and drive assembly is located filter element below, the right side of the upper part of the tank body is provided with a impurity removing component for removing impurities from the mixed solution, the impurity removing component is connected with a driving component, the upper side of the inner wall of the tank body is provided with a material supplementing component for supplementing materials, the material supplementing component is positioned on the upper side of the driving component, the filtering component comprises a connecting ring, a connecting frame, sponge blocks, a limiting ring, a first motor, a first bevel gear, a first connecting block, a first transmission rod, a second bevel gear, a spur gear, a first connecting ring, an elastic telescopic rod, a first connecting block, a round rod and a hollow cylinder, the upper side of the inner wall of the tank body is fixedly connected with the connecting ring, the middle part of the connecting ring is fixedly connected with the connecting frame, two sponge blocks are arranged between the connecting ring and the connecting frame in a bilateral symmetry manner, the two sponge blocks are respectively positioned on the left side and the right side of the connecting frame, the upper side and the lower side of the connecting frame are fixedly connected with a limiting ring, the two limiting rings are arranged in a vertical symmetry manner, two first motors are installed on jar body front side upper portion, two first motor output shafts pass jar body and rigid coupling have first bevel gear respectively, jar body inner wall upside rigid coupling has two first connecting blocks, two first connecting block rear portions all rotate and are connected with first transfer line, two equal rigid couplings of first transfer line outer end have second bevel gear, adjacent second bevel gear meshes with first bevel gear mutually, two equal rigid couplings of first transfer line inner have the spur gear, jar body inside upside rotates and is connected with two first linkage rings, and two first linkage rings are the symmetry setting from top to bottom, and two first linkage rings are located go-between upside and downside respectively, two first linkage ring anchor ring all are provided with round teeth of a cogwheel, two first linkage rings mesh with the spur gear that corresponds respectively, two left side and right side all rigid couplings of first linkage ring have an elastic telescopic link, two elastic telescopic links that are adjacent from top to bottom set up symmetrically, four elastic telescopic link's telescopic ends all have a first linkage piece, first linkage ring and a corresponding hollow round bar that links up and a hollow round tube, the hollow round tube that corresponds to connect with a hollow round tube that links, all round tube that corresponds to connect with a hollow round tube and link, hollow round tube that corresponds to connect.

As a further preferable scheme, the right part and the left part of the lower side of the upper limiting ring are provided with arc grooves, and the right part and the left part of the upper side of the lower limiting ring are provided with arc grooves.

As a further preferred scheme, the evaporating assembly comprises a second motor, a second transmission rod, a flow distribution cylinder, arc blocks, scraping plates, a third support frame and a heating module, wherein the second motor is installed in the middle of the upper side of the top cover, the third support frame is fixedly connected to the lower side of the inner wall of the tank body, the second transmission rod is rotationally connected between the middle of the third support frame and the top cover and fixedly connected with the output end of the second motor, the second transmission rod is rotationally connected with the connecting frame, the upper portion of the second transmission rod is fixedly connected with the flow distribution cylinder, the upper side of the flow distribution cylinder is fixedly connected with the two arc blocks, the four scraping plates are fixedly connected to the lower portion of the second transmission rod, the four scraping plates are arranged in a circular array, and the heating module is installed on the lower side of the inner part of the tank body.

As a further preferable scheme, the arc-shaped block consists of a cone frustum and a cylindrical barrel, the cone frustum is positioned above the cylindrical barrel, and the cylindrical barrel and the heating module form an annular gap.

As a further preferred scheme, the driving assembly comprises a third motor, a third bevel gear, a fourth support frame, a screw rod, a fourth bevel gear, sliding blocks, first linkage rods, first springs and second linkage rings, wherein the third motor is arranged on the upper part of the front side and the upper part of the rear side of the tank body, the two third motors are symmetrically arranged front and back, output shafts of the two third motors penetrate through the tank body and are fixedly connected with the third bevel gear, the front side and the inner rear side of the inner wall of the tank body are fixedly connected with the fourth support frame, the fourth support frame is positioned below the corresponding third bevel gear, the screw rods are respectively and rotatably connected with the fourth bevel gear, the sliding blocks are respectively and slidably connected with the corresponding screw rods, the first springs are respectively sleeved on the two first support rods, the first linkage rods are respectively and rotatably connected with the corresponding second linkage rings, and the second linkage rings are fixedly connected with the upper ends of the first springs and the second linkage rings.

As a further preferable scheme, the impurity removing component comprises a second pipeline, a third pipeline, a fourth pipeline, a valve, a filter screen, a first adjusting cylinder, a second adjusting cylinder, a third adjusting cylinder, a second connecting block, a second spring, a first rubber ball, a rope, a second rubber ball, a third connecting block and a guide rod, wherein the upper part of the right side of the tank body is communicated with the second pipeline, the second pipeline is positioned above the right side of the distributing cylinder, the upper side of the second pipeline is communicated with the third pipeline, the middle part of the lower side of the second pipeline is communicated with the fourth pipeline, the lower part of the fourth pipeline is provided with the valve, the left part of the inner wall of the second pipeline is fixedly connected with the filter screen, the left part of the inner wall of the second pipeline is fixedly connected with the first adjusting cylinder, the first adjusting cylinder is positioned at the left part of the filter screen, the right part of the inner wall of the second pipeline is fixedly connected with the second adjusting cylinder, the right part of the inner wall of the third pipeline is fixedly connected with the third adjusting cylinder, the right part of the inner wall of the third pipeline is fixedly connected with a second connecting block, the second connecting block is positioned above a third adjusting cylinder, the middle part of the lower side of the second connecting block is fixedly connected with a second spring, the lower end of the second spring is fixedly connected with a first rubber ball, the first rubber ball is contacted with the third adjusting cylinder, the middle part of the lower side of the first rubber ball is fixedly connected with a rope, the right side of the inner wall of the tank body is fixedly connected with a third connecting block, the third connecting block is positioned at the left part of the second pipeline, the rope sequentially passes through the second adjusting cylinder, the filter screen, the first adjusting cylinder and the third connecting block to be fixedly connected with a second linkage ring, the rope is in sliding connection with the filter screen, the left part of the rope is fixedly connected with a third rubber ball, the third rubber ball is positioned at the right part of the first adjusting cylinder, the right part of the rope is fixedly connected with a second rubber ball, the second rubber ball is positioned at the right part of the second adjusting cylinder, the right side of the inner wall of the second pipeline is fixedly connected with a guide rod, the rope passes around and contacts the guide bar.

As a further preferable aspect, the inner diameters of the first regulating cylinder and the second regulating cylinder become gradually larger from left to right.

As a further preferable scheme, the material supplementing assembly comprises a storage box, a fifth pipeline, a third spring, a second linkage block, a blocking ring, a third linkage block, a second linkage rod and a limiting block, wherein the storage box is fixedly connected to the upper portion of the inner wall of the tank body and is positioned above the second linkage ring, the right portion of the upper side of the storage box is communicated with the fifth pipeline, the upper portion of the fifth pipeline penetrates out of the tank body, the left portion of the lower side of the storage box and the right portion of the lower side of the storage box are fixedly connected with the third spring, the lower ends of the two third springs are fixedly connected with the second linkage block, the blocking ring is fixedly connected with the blocking ring between the two second linkage blocks, the front portion of the lower side of the blocking ring and the rear portion of the lower side of the storage box are fixedly connected with the third linkage block, the two third linkage blocks are fixedly connected to the upper ends of the two second linkage rods in a sliding mode, and the lower ends of the two second linkage rods are fixedly connected with the limiting blocks and the corresponding sliding blocks.

As a further preferable scheme, the novel cleaning device further comprises a blocking component, wherein the blocking component is arranged at the left part of the impurity removal component and comprises a fourth adjusting cylinder, a fourth connecting block, a fourth spring and a fourth rubber ball, the fourth adjusting cylinder is fixedly connected to the left part of the inner wall of the third pipeline, the fourth connecting block is fixedly connected to the middle part of the lower side of the fourth adjusting cylinder, the fourth spring is fixedly connected to the middle part of the upper side of the fourth connecting block, the fourth rubber ball is fixedly connected to the upper end of the fourth spring, and the fourth rubber ball is in contact with the fourth adjusting cylinder.

As a further preferable aspect, the inner diameters of the third adjusting cylinder and the fourth adjusting cylinder become gradually larger from top to bottom.

Compared with the prior art, the invention has the following advantages: when the device is used, the mixed solution which is injected from one side to the upper side of the split flow cylinder is automatically stirred into circular distribution, so that the mixed solution flowing through the split flow cylinder is uniformly distributed in a circular shape, a solution film is formed, the mixed solution which remains in steam is automatically filtered and collected, waste is avoided, meanwhile, the problem that the absorption performance is poor due to incapability of rebounding the local position of a sponge block due to long-time extrusion is avoided, the traditional Chinese medicine residues which remain in the mixed solution are automatically filtered, the phenomenon that the mixed solution flowing downwards in a circular shape is partially cut off is avoided, meanwhile, the traditional Chinese medicine residues are automatically cleaned, manual cleaning is not needed, the efficiency is greatly improved, and the overheating phenomenon caused by the fact that the solution does not exist on a heating module in the process of cleaning the residues is avoided.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a cross-sectional view of the present invention;

FIG. 3 is a schematic view of a partial structure of the present invention;

FIG. 4 is a schematic view of the structure of the filter assembly of the present invention;

FIG. 5 is a schematic view of a portion of the structure of a filter assembly of the present invention;

FIG. 6 is a right side view of a portion of the construction of the filter assembly of the present invention;

FIG. 7 is a schematic view of the structure of the vaporization assembly of the present invention;

FIG. 8 is a front view of a portion of the construction of the vaporization assembly of the present invention;

FIG. 9 is a schematic view of the drive assembly of the present invention;

FIG. 10 is a schematic view of a portion of the construction of the drive assembly of the present invention;

FIG. 11 is a schematic view of the configuration of the impurity removal assembly and plugging assembly of the present invention;

FIG. 12 is a schematic view of a first construction of the feed assembly of the present invention;

FIG. 13 is a schematic view of a second construction of the feed assembly of the present invention.

Wherein: 1-first support frame, 2-tank, 3-top cover, 4-second support frame, 5-condenser, 6-first pipe, 7-side cover, 201-connecting ring, 202-connecting frame, 203-sponge block, 204-stop ring, 205-first motor, 206-first bevel gear, 207-first connecting block, 208-first transmission rod, 209-second bevel gear, 2010-spur gear, 2011-first connecting ring, 2012-elastic telescopic rod, 2013-first linkage block, 2014-round rod, 2015-hollow tube, 301-second motor, 302-second transmission rod, 303-shunt tube, 304-arc block, 305-scraper blade, 306-third support frame, 307-heating module, 401-third motor, 402-third bevel gear, 403-fourth support frame, 404-screw rod, 405-fourth bevel gear, 406-slider, 407-first linkage rod, 408-first spring, 409-second linkage ring, 502-second pipe, 502-third valve, 505-second pipe, 506-third valve, 506-second pipe, 5016-third pipe, 103-third valve, 5016-ball, 5016-third pipe, 5016-third connecting block, 5016-ball, 5016-third pipe, 5016-ball, 5016-third connecting block, 5010-ball, 605-blocking ring, 606-third linkage block, 607-second linkage rod, 608-limiting block, 701-fourth adjusting cylinder, 702-fourth connecting block, 703-fourth spring, 704-fourth rubber ball.

Detailed Description

The invention is further described below with reference to the drawings and examples.

Example 1

A preparation device of a traditional Chinese medicine composition for treating heart failure is shown in figures 1-8, and comprises a first support frame 1, a tank body 2, a top cover 3, a second support frame 4, a condenser 5, a first pipeline 6, a side cover 7, a filtering component, an evaporating component, a driving component, a impurity removing component and a feeding component; the middle part of the first support frame 1 is welded with a tank body 2; the top of the tank body 2 is connected with a top cover 3 through bolts; a second support frame 4 is arranged on the left side of the first support frame 1; a condenser 5 is arranged in the middle of the inside of the second supporting frame 4; the top of the condenser 5 is communicated with a first pipeline 6; the first pipeline 6 is communicated with the tank body 2; the upper part of the right side of the tank body 2 is inserted with a side cover 7; a filter component is arranged on the upper side of the inner wall of the tank body 2; an evaporation assembly is arranged in the tank body 2; the evaporation component is connected with the top cover 3; a driving component is arranged on the upper side of the interior of the tank body 2, and the driving component is positioned below the filtering component; the right side of the upper part of the tank body 2 is provided with a impurity removing component; the impurity removing component is connected with the driving component; the feed supplement subassembly is installed to jar body 2 inner wall upside to the feed supplement subassembly is located the drive assembly upside.

The filtering component comprises a connecting ring 201, a connecting frame 202, a sponge block 203, a limiting ring 204, a first motor 205, a first bevel gear 206, a first connecting block 207, a first transmission rod 208, a second bevel gear 209, a spur gear 2010, a first linkage ring 2011, an elastic telescopic rod 2012, a first linkage block 2013, a round rod 2014 and a hollow barrel 2015; a connecting ring 201 is fixedly connected to the upper side of the inner wall of the tank body 2; a connecting frame 202 is welded in the middle of the connecting ring 201; two sponge blocks 203 are arranged between the connecting ring 201 and the connecting frame 202, the two sponge blocks 203 are symmetrically arranged left and right, and the two sponge blocks 203 are respectively positioned at the left side and the right side of the connecting frame 202; the upper side and the lower side of the connecting frame 202 are welded with a limiting ring 204, and the two limiting rings 204 are arranged symmetrically up and down; two first motors 205 are installed at the upper part of the front side of the tank body 2; the output shafts of the two first motors 205 respectively penetrate through the tank body 2 and are fixedly connected with a first bevel gear 206; two first connecting blocks 207 are fixedly connected to the upper side of the inner wall of the tank body 2; the rear parts of the two first connecting blocks 207 are rotatably connected with a first transmission rod 208; the outer ends of the two first transmission rods 208 are fixedly connected with second bevel gears 209; an adjacent second bevel gear 209 meshes with the first bevel gear 206; the inner ends of the two first transmission rods 208 are fixedly connected with spur gears 2010; the upper side of the inside of the tank body 2 is rotationally connected with two first linkage rings 2011, the two first linkage rings 2011 are arranged symmetrically up and down, and the two first linkage rings 2011 are respectively positioned on the upper side and the lower side of the connecting ring 201; the inner ring surfaces of the two first linkage rings 2011 are provided with a circle of gear teeth; the two first linkage rings 2011 are respectively meshed with the corresponding spur gears 2010; an elastic telescopic rod 2012 is fixedly connected to the left side and the right side of the two first linkage rings 2011, and the two elastic telescopic rods 2012 which are vertically adjacent are symmetrically arranged; the telescopic ends of the four elastic telescopic rods 2012 are fixedly connected with a first linkage block 2013, and the first linkage block 2013 is in sliding connection with a corresponding first linkage ring 2011; a round rod 2014 is rotatably connected inside each of the four first linkage blocks 2013, and the round rods 2014 are in contact with the corresponding limiting rings 204; a hollow cylinder 2015 is fixedly connected to each of the four round rods 2014, and the hollow cylinder 2015 is in contact with the corresponding sponge block 203; arc grooves are formed in the right portion and the left portion of the lower side of the upper limiting ring 204, and arc grooves are formed in the right portion and the left portion of the upper side of the lower limiting ring 204.

The evaporation assembly comprises a second motor 301, a second transmission rod 302, a diversion barrel 303, an arc-shaped block 304, a scraping plate 305, a third supporting frame 306 and a heating module 307; the middle part of the upper side of the top cover 3 is provided with a second motor 301; a third support frame 306 is fixedly connected to the lower side of the inner wall of the tank body 2; a second transmission rod 302 is rotatably connected between the middle part of the third support frame 306 and the top cover 3; the second transmission rod 302 is fixedly connected with the output end of the second motor 301; the second transmission rod 302 is rotatably connected with the connecting frame 202; the upper part of the second transmission rod 302 is fixedly connected with a diversion cylinder 303; two arc-shaped blocks 304 are welded on the upper side of the shunt barrel 303; four scrapers 305 are welded at the lower part of the second transmission rod 302, and the four scrapers 305 are arranged in a circular array; a heating module 307 is arranged at the lower side of the inner part of the tank body 2; the arc block 304 is composed of a truncated cone and a cylindrical barrel, the truncated cone is located above the cylindrical barrel, and the cylindrical barrel and the heating module 307 form an annular gap.

When the device is ready to work, an external feeding pipeline is communicated to a impurity removing component, an external discharging pipeline is communicated to the lower part of a tank body 2, an external waste water collecting pipeline is communicated to the lower output end of a first pipeline 6, then the external feeding pipeline is used for injecting traditional Chinese medicine mixed solution into the impurity removing component, the impurity removing component is used for injecting the traditional Chinese medicine mixed solution into the tank body 2, the mixed solution flows to the right part of the upper side of a split cylinder 303, a second motor 301 is started, the second motor 301 drives a second transmission rod 302 to rotate, the second transmission rod 302 drives the split cylinder 303 to rotate, the split cylinder 303 drives two arc blocks 304 to perform circular motion, so that the mixed solution is stirred to the lower edge of the arc surface of the split cylinder 303, at the moment, the mixed solution is distributed on the lower edge of the arc surface of the split cylinder 303 in a circular ring shape, then the mixed solution flows into a gap between the vertical surface of the split cylinder 303 and the inner wall of a heating module 307 in a circular shape, the mixed solution passing through the diversion cylinder 303 uniformly flows downwards along the inner wall of the heating module 307, a solution film is formed, the heating module 307 starts self-heating, meanwhile, the second transmission rod 302 drives the four scraping plates 305 to perform circular motion, so that the scraping plates 305 scrape the mixed solution flowing downwards on the inner wall of the heating module 307, namely, the mixed solution is uniformly distributed on the inner wall of the heating module 307 in a film shape, the evaporation area of the mixed solution is greatly increased, the evaporation efficiency is improved, the evaporated concentrated solution flows into an external discharging pipeline through the lower opening of the tank body 2, the steam flows upwards into a cavity at the upper part of the diversion cylinder 303, at the moment, part of the mixed solution is carried out by the steam, the steam continues to flow upwards through the two sponge blocks 203, the mixed solution in the steam is sucked out by the two sponge blocks 203, the filtered steam flows into the condenser 5 through the first pipeline 6, then the condenser 5 condenses the steam to convert the steam into liquid and flow the liquid into an external waste water collecting pipeline, when the mixed solution absorbed on the two sponge blocks 203 reaches a certain amount, the sponge blocks 203 can not meet the filtering requirement, the first motor 205 is started, the first motor 205 drives the first bevel gear 206 to reciprocate, the first bevel gear 206 drives the second bevel gear 209 to rotate, the second bevel gear 209 drives the first transmission rod 208 to rotate, the first transmission rod 208 drives the spur gear 2010 to rotate, the spur gear 2010 drives the first linkage ring 2011 to reciprocate, the first linkage ring 2011 drives the elastic telescopic rod 2012 to reciprocate, the elastic telescopic rod 2012 drives the first linkage block 2013 to reciprocate, the first linkage block 2013 drives the round rod 2014 to reciprocate, the round rod 2014 drives the hollow cylinder 2015 to reciprocate, the limiting ring 204 stops and limits the round rod 2014 in the process of movement, the round bars 2014 are made to move along the track of the lower side surface of the limiting ring 204, namely, the two round bars 2014 which are adjacent up and down move circularly and move oppositely, meanwhile, the corresponding elastic telescopic bars 2012 stretch, the two round bars 2014 drive the two corresponding hollow cylinders 2015 to move oppositely, so that the two hollow cylinders 2015 which are adjacent up and down extrude the sponge block 203, simultaneously, the two hollow cylinders 2015 which are adjacent up and down roll along the upper side surface and the lower side surface of the sponge block 203, so that the mixed solution in the sponge block 203 is extruded, the extruded mixed solution falls to the upper side of the diversion cylinder 303 and then enters the evaporation cycle again, thereby avoiding the waste phenomenon, then the round bars 2014 move back to the groove position of the limiting ring 204, then the elastic telescopic bars 2012 rebound to drive the first linkage blocks 2013 to move back to the original position, the first linkage blocks 2013 drive the round bars 2014 to move back to the original position, the round rod 2014 drives the hollow cylinder 2015 to move back to the original position, namely the hollow cylinder 2015 stops continuously extruding the sponge block 203, the problem that the absorption performance is poor because the local position of the sponge block 203 cannot rebound due to long-time extrusion is avoided, the first motor 205 is closed, then the sponge block 203 rebounds to be original, then the subsequent steam is subjected to filtering operation, the mixed solution injected to the upper side of the split cylinder 303 from one side is automatically stirred into circular distribution during use, the mixed solution flowing through the split cylinder 303 is in circular uniform distribution, a solution film is formed, the mixed solution which remains in the steam is automatically filtered and collected, waste is avoided, and the problem that the absorption performance is poor because the local position of the sponge block 203 cannot rebound due to long-time extrusion is avoided.

Example 2

On the basis of the embodiment 1, as shown in fig. 1-3 and fig. 9-13, the driving assembly comprises a third motor 401, a third bevel gear 402, a fourth supporting frame 403, a screw rod 404, a fourth bevel gear 405, a sliding block 406, a first linkage rod 407, a first spring 408 and a second linkage ring 409; the upper part of the front side and the upper part of the rear side of the tank body 2 are respectively provided with a third motor 401, and the two third motors 401 are symmetrically arranged in the front-back direction; the output shafts of the two third motors 401 pass through the tank body 2 and are fixedly connected with a third bevel gear 402; a fourth supporting frame 403 is fixedly connected to the front side and the inner rear side of the inner wall of the tank body 2, and the fourth supporting frame 403 is positioned below the corresponding third bevel gear 402; a screw rod 404 is rotatably connected to both the fourth supporting frames 403; a fourth bevel gear 405 is fixedly connected to the upper parts of the two screw rods 404, and the fourth bevel gear 405 is meshed with the corresponding third bevel gear 402; a sliding block 406 is slidably connected to the two fourth supporting frames 403, and the two sliding blocks 406 are respectively screwed with the corresponding screw rods 404; the two sliding blocks 406 are connected with a first linkage rod 407 in a sliding way towards the center; a first spring 408 is sleeved on each of the two first linkage rods 407; a second linkage ring 409 is welded between the lower parts of the two first linkage rods 407; the lower ends of the two first springs 408 are welded with the second coupling ring 409, and the upper ends of the two first springs 408 are welded with the corresponding sliders 406.

The impurity removing component comprises a second pipeline 501, a third pipeline 502, a fourth pipeline 503, a valve 504, a filter screen 505, a first adjusting cylinder 506, a second adjusting cylinder 507, a third adjusting cylinder 508, a second connecting block 509, a second spring 5010, a first rubber ball 5011, a rope 5012, a second rubber ball 5013, a third rubber ball 5014, a third connecting block 5015 and a guide rod 5016; the upper right side of the tank body 2 is communicated with a second pipeline 501, and the second pipeline 501 is positioned above the right side of the diversion cylinder 303; a third pipeline 502 is communicated with the upper side of the second pipeline 501; a fourth pipeline 503 is communicated with the middle of the lower side of the second pipeline 501; a valve 504 is arranged at the lower part of the fourth pipeline 503; a filter screen 505 is fixedly connected to the left part of the inner wall of the second pipeline 501; a first adjusting cylinder 506 is fixedly connected to the left part of the inner wall of the second pipeline 501, and the first adjusting cylinder 506 is positioned at the left side of the filter screen 505; a second adjusting cylinder 507 is fixedly connected to the right part of the inner wall of the second pipeline 501; a third adjusting cylinder 508 is fixedly connected to the right part of the inner wall of the third pipeline 502; a second connecting block 509 is fixedly connected to the right part of the inner wall of the third pipeline 502, and the second connecting block 509 is positioned above the third regulating cylinder 508; a second spring 5010 is welded in the middle of the lower side of the second connecting block 509; the lower end of the second spring 5010 is fixedly connected with a first rubber ball 5011; the first rubber ball 5011 is in contact with the third adjustment cylinder 508; a rope 5012 is fixedly connected to the middle part of the lower side of the first rubber ball 5011; a third connecting block 5015 is fixedly connected to the right side of the inner wall of the tank body 2, and the third connecting block 5015 is positioned at the left side of the second pipeline 501; the rope 5012 sequentially passes through the second adjusting cylinder 507, the filter screen 505, the first adjusting cylinder 506 and the third connecting block 5015 to be fixedly connected with the second linkage ring 409; rope 5012 is slidingly connected with filter screen 505; the rope 5012 is slidingly connected with the third connecting block 5015; a third rubber ball 5014 is fixedly connected to the left part of the rope 5012, and the third rubber ball 5014 is positioned on the right side of the first adjusting cylinder 506; a second rubber ball 5013 is fixedly connected to the right part of the rope 5012, and the second rubber ball 5013 is positioned on the right side of the second adjusting cylinder 507; a guide rod 5016 is fixedly connected to the right side of the inner wall of the second pipeline 501, and a rope 5012 bypasses the guide rod 5016 and contacts with the guide rod 5016; the inner diameters of the first and second adjustment cylinders 506 and 507 gradually become larger from left to right.

The feeding component comprises a storage box 601, a fifth pipeline 602, a third spring 603, a second linkage block 604, a blocking ring 605, a third linkage block 606, a second linkage rod 607 and a limiting block 608; a storage box 601 is fixedly connected to the upper part of the inner wall of the tank body 2, and the storage box 601 is positioned above the second linkage ring 409; a fifth pipeline 602 is communicated with the right part of the upper side of the storage box 601; the upper part of the fifth pipeline 602 passes out of the tank body 2; a third spring 603 is welded on the left part and the right part of the lower side of the storage box 601; the lower ends of the two third springs 603 are welded with a second linkage block 604; a blocking ring 605 is fixedly connected between the two second linkage blocks 604; the blocking ring 605 is inserted into the storage box 601; a third linkage block 606 is connected to the front part of the lower side and the rear part of the lower side of the blocking ring 605 through bolts; a second linkage rod 607 is slidably connected to each of the two third linkage blocks 606; a limiting block 608 is welded at the upper ends of the two second linkage rods 607; the lower ends of the two second linkage rods 607 are fixedly connected with the corresponding sliding blocks 406.

The device also comprises a blocking component, wherein the left part of the impurity removal component is provided with the blocking component, and the blocking component comprises a fourth adjusting cylinder 701, a fourth connecting block 702, a fourth spring 703 and a fourth rubber ball 704; a fourth adjusting cylinder 701 is fixedly connected to the left part of the inner wall of the third pipeline 502; a fourth connecting block 702 is welded in the middle of the lower side of the fourth adjusting cylinder 701; a fourth spring 703 is welded in the middle of the upper side of the fourth connecting block 702; the upper end of the fourth spring 703 is fixedly connected with a fourth rubber ball 704; the fourth rubber ball 704 is in contact with the fourth adjustment cylinder 701; the inner diameters of the third adjustment cylinder 508 and the fourth adjustment cylinder 701 become gradually larger from top to bottom.

Firstly, a fifth pipeline 602 is opened, then a proper amount of mixed solution is injected into a storage box 601 through the fifth pipeline 602, the fifth pipeline 602 is closed, then an external storage barrel is placed below a valve 504, when the mixed solution is conveyed to a impurity removing component by an external feeding pipeline, the mixed solution flows into a second pipeline 501 and then flows into the upper side of a diversion cylinder 303 from the second pipeline 501, a filter screen 505 filters the mixed solution flowing through the second pipeline 501 in the process, so that residues of traditional Chinese medicine remained in the solution are filtered, the residues of traditional Chinese medicine are prevented from being blocked into a gap between the diversion cylinder 303 and a heating module 307, the phenomenon of local cutoff of the mixed solution flowing downwards in a ring shape is avoided, when the residues of the traditional Chinese medicine aggregated on the right side of the filter screen 505 are excessive, a third motor 401 is started, the third motor 401 drives a third bevel gear 402 to rotate, the third bevel gear 402 drives a fourth bevel gear 405 to rotate, the fourth bevel gear 405 drives the screw rod 404 to rotate, the screw rod 404 drives the sliding block 406 to slide downwards on the fourth supporting frame 403, the sliding block 406 drives the first spring 408 to move downwards, the first spring 408 drives the second linkage ring 409 to move downwards, the second linkage ring 409 pulls the left end of the rope 5012 to move, the rope 5012 drives the second rubber ball 5013 and the third rubber ball 5014 to move leftwards through the guiding action of the third connecting block 5015, the rope 5012 drives the first rubber ball 5011 to move downwards through the guiding action of the guiding rod 5016, the second rubber ball 5013 moves leftwards to block the second adjusting cylinder 507, the third rubber ball 5014 moves leftwards to block the first adjusting cylinder 506, the first rubber ball 5011 moves downwards to open the third adjusting cylinder 508 and stretch the second spring 5010, then the valve 504 is manually opened, at this time, the mixed solution at the right end of the second pipeline 501 flows into the third pipeline 502, then the mixed solution extrudes the fourth rubber ball 704 to move downwards and extrudes the fourth spring 703, the fourth adjusting cylinder 701 is opened, then the mixed solution flows into the second pipeline 501 through the left part of the third pipeline 502, the left end of the second pipeline 501 is blocked, the mixed solution moves rightwards, flows into the fourth pipeline 503 and flows into the external storage barrel through the valve 504, in the process, the mixed solution flowing rightwards washes the traditional Chinese medicine residues accumulated on the right side of the filter screen 505 into the fourth pipeline 503 and flows into the external storage barrel, thereby realizing automatic cleaning of the traditional Chinese medicine residues, without stopping the manual cleaning, greatly improving the efficiency, simultaneously, the second linkage ring 409 moves downwards to contact with the bulge on the centripetal side of the lower part of the fourth support frame 403, the slide block 406 drives the second linkage rod 607 to move downwards, the second linkage rod 607 drives the limiting block 608 to move downwards to contact the third linkage block 606, the sliding block 406 continues to move downwards, at this time, the second linkage ring 409 is blocked by the fourth supporting frame 403 to keep static, thereby compressing the first spring 408, the limiting block 608 pushes the third linkage block 606 to move downwards, the third linkage block 606 drives the blocking ring 605 to move downwards, the blocking ring 605 drives the second linkage block 604 to move downwards, and stretches the third spring 603, the blocking ring 605 moves downwards away from the storage box 601, so that the mixed solution in the storage box 601 takes on annular downward flow, thereby continuously replenishing the upper side of the splitting cylinder 303, avoiding overheating phenomenon caused by no solution on the heating module 307 in the residue cleaning process, then the third motor 401 drives the third bevel gear 402 to rotate reversely, the sliding block 406 moves upwards to be in the original position, the third motor 401 is closed, the first spring drives the second linkage ring 409 to move upwards to be in the original position, the third spring 603 drives the second linkage block 604 to move back to the original position, the second linkage block 604 drives the blocking ring 605 to move back to the original position upwards to block the storage box 601 again, at the moment, the rope 5012 is in a loose state, the second spring 5010 drives the first rubber ball 5011 to move back to the original position, the first rubber ball 5011 pulls the rope 5012 back to the original position, thereby the second rubber ball 5013 and the third rubber ball 5014 move back to the original position, the valve 504 is closed, at the moment, the mixed solution flows leftwards in the second pipeline 501, during use, the traditional Chinese medicine residues remained in the mixed solution are automatically filtered, the phenomenon of local cutoff of the mixed solution flowing downwards in a ring shape is avoided, meanwhile, the traditional Chinese medicine residues are automatically cleaned, manual cleaning is not needed, the efficiency is greatly improved, the phenomenon of overheating caused by no solution on the heating module 307 in the process of cleaning residues is avoided, and meanwhile, the mixed solution in the storage box 601 is timely added.

The embodiments of the present invention have been described in detail with reference to the drawings, but the present invention is not limited to the above embodiments, and various changes can be made within the knowledge of those skilled in the art without departing from the spirit of the present invention.

Claims

1. A preparation device of a traditional Chinese medicine composition for treating heart failure comprises a first support frame (1), a tank body (2), a top cover (3), a second support frame (4), a condenser (5), a first pipeline (6) and a side cover (7); the middle part of the first support frame (1) is fixedly connected with a tank body (2); a top cover (3) is fixedly connected at the top of the tank body (2); a second support frame (4) is arranged at the left side of the first support frame (1); a condenser (5) is arranged in the middle of the inside of the second supporting frame (4); the top of the condenser (5) is communicated with a first pipeline (6); the first pipeline (6) is communicated with the tank body (2); the upper part of the right side of the tank body (2) is inserted with a side cover (7); the method is characterized in that: the device also comprises a filtering component, an evaporating component, a driving component, a impurity removing component and a material supplementing component; a filtering component for filtering steam is arranged on the upper side of the inner wall of the tank body (2); an evaporation assembly for evaporating the mixed solution is arranged in the tank body (2); the evaporation component is connected with the top cover (3); a driving component for driving is arranged on the upper side of the interior of the tank body (2), and the driving component is positioned below the filtering component; the right side of the upper part of the tank body (2) is provided with a impurity removing component for removing impurities from the mixed solution; the impurity removing component is connected with the driving component; a feeding component for feeding materials is arranged on the upper side of the inner wall of the tank body (2), and the feeding component is positioned on the upper side of the driving component;

the filtering assembly comprises a connecting ring (201), a connecting frame (202), a sponge block (203), a limiting ring (204), a first motor (205), a first bevel gear (206), a first connecting block (207), a first transmission rod (208), a second bevel gear (209), a spur gear (2010), a first linkage ring (2011), an elastic telescopic rod (2012), a first linkage block (2013), a round rod (2014) and a hollow cylinder (2015); a connecting ring (201) is fixedly connected on the upper side of the inner wall of the tank body (2); a connecting frame (202) is fixedly connected with the middle part of the connecting ring (201); two sponge blocks (203) are arranged between the connecting ring (201) and the connecting frame (202), the two sponge blocks (203) are symmetrically arranged left and right, and the two sponge blocks (203) are respectively positioned at the left side and the right side of the connecting frame (202); the upper side and the lower side of the connecting frame (202) are fixedly connected with a limiting ring (204), and the two limiting rings (204) are arranged symmetrically up and down; two first motors (205) are arranged at the upper part of the front side of the tank body (2); the output shafts of the two first motors (205) respectively penetrate through the tank body (2) and are fixedly connected with a first bevel gear (206); two first connecting blocks (207) are fixedly connected to the upper side of the inner wall of the tank body (2); the rear parts of the two first connecting blocks (207) are rotationally connected with a first transmission rod (208); the outer ends of the two first transmission rods (208) are fixedly connected with second bevel gears (209); an adjacent second bevel gear (209) is meshed with the first bevel gear (206); the inner ends of the two first transmission rods (208) are fixedly connected with spur gears (2010); the upper side of the inside of the tank body (2) is rotationally connected with two first linkage rings (2011), the two first linkage rings (2011) are arranged symmetrically up and down, and the two first linkage rings (2011) are respectively positioned on the upper side and the lower side of the connecting ring (201); the inner ring surfaces of the two first linkage rings (2011) are provided with a circle of gear teeth; the two first linkage rings (2011) are respectively meshed with corresponding spur gears (2010); the left side and the right side of the two first linkage rings (2011) are fixedly connected with an elastic telescopic rod (2012), and the two elastic telescopic rods (2012) which are vertically adjacent are symmetrically arranged; the telescopic ends of the four elastic telescopic rods (2012) are fixedly connected with a first linkage block (2013), and the first linkage block (2013) is in sliding connection with a corresponding first linkage ring (2011); a round rod (2014) is rotatably connected inside each of the four first linkage blocks (2013), and the round rods (2014) are contacted with the corresponding limiting rings (204); a hollow cylinder (2015) is fixedly connected to the four round rods (2014), and the hollow cylinder (2015) is contacted with the corresponding sponge block (203);

the evaporation assembly comprises a second motor (301), a second transmission rod (302), a shunt barrel (303), an arc-shaped block (304), a scraper (305), a third supporting frame (306) and a heating module (307); the middle part of the upper side of the top cover (3) is provided with a second motor (301); a third supporting frame (306) is fixedly connected to the lower side of the inner wall of the tank body (2); a second transmission rod (302) is rotatably connected between the middle part of the third support frame (306) and the top cover (3); the second transmission rod (302) is fixedly connected with the output end of the second motor (301); the second transmission rod (302) is rotationally connected with the connecting frame (202); the upper part of the second transmission rod (302) is fixedly connected with a diversion cylinder (303); two arc-shaped blocks (304) are fixedly connected to the upper side of the shunt barrel (303); four scrapers (305) are fixedly connected to the lower part of the second transmission rod (302), and the four scrapers (305) are arranged in a circular array; a heating module (307) is arranged at the lower side of the interior of the tank body (2);

the driving assembly comprises a third motor (401), a third bevel gear (402), a fourth supporting frame (403), a screw rod (404), a fourth bevel gear (405), a sliding block (406), a first linkage rod (407), a first spring (408) and a second linkage ring (409); the upper part of the front side and the upper part of the rear side of the tank body (2) are respectively provided with a third motor (401), and the two third motors (401) are symmetrically arranged in the front-back direction; the output shafts of the two third motors (401) penetrate through the tank body (2) and are fixedly connected with a third bevel gear (402); a fourth supporting frame (403) is fixedly connected to the front side and the inner rear side of the inner wall of the tank body (2), and the fourth supporting frame (403) is positioned below the corresponding third bevel gear (402); a screw rod (404) is rotatably connected to both the fourth supporting frames (403); a fourth bevel gear (405) is fixedly connected to the upper parts of the two screw rods (404), and the fourth bevel gear (405) is meshed with the corresponding third bevel gear (402); a sliding block (406) is connected to the two fourth supporting frames (403) in a sliding way, and the two sliding blocks (406) are respectively screwed with the corresponding screw rods (404); the two sliding blocks (406) are connected with a first linkage rod (407) towards the center part in a sliding way; a first spring (408) is sleeved on each of the two first linkage rods (407); a second linkage ring (409) is fixedly connected between the lower parts of the two first linkage rods (407); the lower ends of the two first springs (408) are fixedly connected with the second linkage ring (409), and the upper ends of the two first springs (408) are fixedly connected with the corresponding sliding blocks (406);

the impurity removal assembly comprises a second pipeline (501), a third pipeline (502), a fourth pipeline (503), a valve (504), a filter screen (505), a first adjusting cylinder (506), a second adjusting cylinder (507), a third adjusting cylinder (508), a second connecting block (509), a second spring (5010), a first rubber ball (5011), a rope (5012), a second rubber ball (5013), a third rubber ball (5014), a third connecting block (5015) and a guide rod (5016); the upper part of the right side of the tank body (2) is communicated with a second pipeline (501), and the second pipeline (501) is positioned above the right side of the diversion cylinder (303); a third pipeline (502) is communicated with the upper side of the second pipeline (501); a fourth pipeline (503) is communicated with the middle part of the lower side of the second pipeline (501); a valve (504) is arranged at the lower part of the fourth pipeline (503); a filter screen (505) is fixedly connected to the left part of the inner wall of the second pipeline (501); a first adjusting cylinder (506) is fixedly connected to the left part of the inner wall of the second pipeline (501), and the first adjusting cylinder (506) is positioned at the left side of the filter screen (505); a second adjusting cylinder (507) is fixedly connected to the right part of the inner wall of the second pipeline (501); a third adjusting cylinder (508) is fixedly connected to the right part of the inner wall of the third pipeline (502); a second connecting block (509) is fixedly connected to the right part of the inner wall of the third pipeline (502), and the second connecting block (509) is positioned above the third adjusting cylinder (508); a second spring (5010) is fixedly connected to the middle part of the lower side of the second connecting block (509); the lower end of the second spring (5010) is fixedly connected with a first rubber ball (5011); the first rubber ball (5011) is contacted with the third adjusting cylinder (508); a rope (5012) is fixedly connected to the middle part of the lower side of the first rubber ball (5011); a third connecting block (5015) is fixedly connected to the right side of the inner wall of the tank body (2), and the third connecting block (5015) is positioned at the left side of the second pipeline (501); the rope (5012) sequentially passes through the second adjusting cylinder (507), the filter screen (505), the first adjusting cylinder (506) and the third connecting block (5015) to be fixedly connected with the second linkage ring (409); the rope (5012) is in sliding connection with the filter screen (505); the rope (5012) is in sliding connection with the third connecting block (5015); a third rubber ball (5014) is fixedly connected to the left part of the rope (5012), and the third rubber ball (5014) is positioned on the right side of the first adjusting cylinder (506); the right part of the rope (5012) is fixedly connected with a second rubber ball (5013), and the second rubber ball (5013) is positioned on the right side of the second adjusting cylinder (507); a guide rod (5016) is fixedly connected to the right side of the inner wall of the second pipeline (501), and a rope (5012) bypasses the guide rod (5016) and is contacted with the guide rod;

the feeding component comprises a storage box (601), a fifth pipeline (602), a third spring (603), a second linkage block (604), a blocking ring (605), a third linkage block (606), a second linkage rod (607) and a limiting block (608); a storage box (601) is fixedly connected to the upper part of the inner wall of the tank body (2), and the storage box (601) is positioned above the second linkage ring (409); a fifth pipeline (602) is communicated with the right part of the upper side of the storage box (601); the upper part of the fifth pipeline (602) penetrates out of the tank body (2); a third spring (603) is fixedly connected to the left part and the right part of the lower side of the storage box (601); the lower ends of the two third springs (603) are fixedly connected with a second linkage block (604); a blocking ring (605) is fixedly connected between the two second linkage blocks (604); the blocking ring (605) is inserted into the storage box (601); a third linkage block (606) is fixedly connected to the front part of the lower side and the rear part of the lower side of the blocking ring (605); the two third linkage blocks (606) are connected with a second linkage rod (607) in a sliding way; the upper ends of the two second linkage rods (607) are fixedly connected with a limiting block (608); the lower ends of the two second linkage rods (607) are fixedly connected with the corresponding sliding blocks (406).

2. The device for preparing the traditional Chinese medicine composition for treating heart failure according to claim 1, wherein the device is characterized in that: arc grooves are formed in the right portion and the left portion of the lower side of the upper limiting ring (204), and arc grooves are formed in the right portion and the left portion of the upper side of the lower limiting ring (204).

3. The device for preparing the traditional Chinese medicine composition for treating heart failure according to claim 1, wherein the device is characterized in that: the arc-shaped block (304) consists of a truncated cone and a cylindrical barrel, the truncated cone is positioned above the cylindrical barrel, and the cylindrical barrel and the heating module (307) form an annular gap.

4. The device for preparing the traditional Chinese medicine composition for treating heart failure according to claim 1, wherein the device is characterized in that: the inner diameters of the first adjusting cylinder (506) and the second adjusting cylinder (507) gradually increase from left to right.

5. The device for preparing the traditional Chinese medicine composition for treating heart failure according to claim 1, wherein the device is characterized in that: the device also comprises a blocking component, wherein the left part of the impurity removal component is provided with the blocking component, and the blocking component comprises a fourth adjusting cylinder (701), a fourth connecting block (702), a fourth spring (703) and a fourth rubber ball (704); a fourth adjusting cylinder (701) is fixedly connected to the left part of the inner wall of the third pipeline (502); a fourth connecting block (702) is fixedly connected to the middle part of the lower side of the fourth adjusting cylinder (701); a fourth spring (703) is fixedly connected in the middle of the upper side of the fourth connecting block (702); a fourth rubber ball (704) is fixedly connected to the upper end of the fourth spring (703); the fourth rubber ball (704) is contacted with the fourth adjusting cylinder (701).

6. The device for preparing the traditional Chinese medicine composition for treating heart failure according to claim 5, wherein the device is characterized in that: the inner diameters of the third adjusting cylinder (508) and the fourth adjusting cylinder (701) become larger gradually from top to bottom.