CN114225790B

CN114225790B - Multi freedom clinical laboratory is with blood mixing device

Info

Publication number: CN114225790B
Application number: CN202111541389.7A
Authority: CN
Inventors: 黄俊生; 田莉娜; 黄晓斌
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-12-16
Filing date: 2021-12-16
Publication date: 2023-10-13
Anticipated expiration: 2041-12-16
Also published as: CN114225790A

Abstract

The invention discloses a blood mixing device for a multiple freedom degree clinical laboratory, which comprises a storage box, wherein a driving motor is fixedly arranged in the middle of the upper surface of the storage box, the inner wall of the storage box is fixedly connected with a mounting plate, the left end and the right end of the bottom of the mounting plate are fixedly connected with sliding sleeves, the inner wall of each sliding sleeve is slidably connected with a first sliding rod, one ends of the first two groups of sliding rods, which are close to the driving motor, are fixedly connected with connecting frames, and the left side wall and the right side wall of the storage box are respectively provided with a limiting notch.

Description

Multi freedom clinical laboratory is with blood mixing device

Technical Field

The invention relates to the technical field of blood mixing devices, in particular to a blood mixing device for a multiple-degree-of-freedom clinical laboratory.

Background

In the hospital test, for some specific items, human blood and an anticoagulant are required to be mixed in a blood collection bottle, heparin is the best anticoagulant in the measurement of blood chemical components, but the blood collection bottle is required to be shaken for a long time to fully and uniformly mix the blood and heparin.

The existing blood mixing device can only fuse the blood and heparin in the blood sampling bottle in a manual shaking mode, but when a blood sample is large, the manual shaking mode is adopted, so that the workload of medical staff is increased, the blood and the anticoagulant are easily mixed unevenly, and the accuracy of a test result is affected.

Disclosure of Invention

The invention aims to provide a multi-degree-of-freedom clinical laboratory blood mixing device, which has the advantages of good mixing effect and equal-proportion addition of blood and heparin, and solves the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a multi freedom clinical laboratory is with blood mixing device, includes the storage box, the upper surface intermediate position fixed mounting of storage box has driving motor, the inner wall fixedly connected with mounting panel of storage box, both ends all fixedly connected with sliding sleeve about the bottom of mounting panel, the inner wall sliding connection of sliding sleeve has slide bar one, two sets of one end fixedly connected with linking frame that slide bar is close to driving motor, spacing notch has all been seted up to the left and right sides wall of storage box, the one end and the spacing notch inner wall sliding connection of linking frame of keeping away from of slide bar one, driving motor's output shaft runs through the outer wall fixedly connected with (mixing) shaft of storage box and mounting panel, spout three has been seted up to the inner wall bottom of storage box, the top sliding connection of spout three has the mixing casing, fixedly connected with connecting rod between the top of mixing casing and the bottom of slide bar one, the bottom of (mixing) shaft extends to the inside of mixing casing, the outer wall fixedly connected with sleeve of (mixing) shaft, telescopic outer wall fixedly connected with flabellum is used for stirring the inside solution of mixing casing.

Preferably, the inner walls of the left side and the right side of the storage box are fixedly connected with a second spring, and one end, close to the mixing shell, of the second spring is fixedly connected with a vibrating plate for vibrating the solution inside the mixing shell.

Preferably, a discharging hole for discharging solution is formed in the bottom of the front face of the mixing shell, and a material taking hole is formed in the front face of the storage box at the position opposite to the discharging hole.

Preferably, the outer wall fixedly connected with flange of (mixing) shaft, the (mixing) shaft is in the eccentric position of flange, flange and the inner wall sliding connection of connecting frame.

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

1. when the blood mixing device for the multiple-degree-of-freedom clinical laboratory is used, when the mixed solution of blood and heparin in the mixing shell is required to be mixed, the driving motor is started, the stirring shaft is driven to rotate clockwise through the driving motor, the sleeve and the stirring fan blades are driven to rotate clockwise synchronously, the mixed solution of the blood and the heparin in the mixing shell is stirred, and the mixing rate of the blood and the heparin is enhanced.

2. When the extrusion head rotates clockwise, the convex disc is driven to rotate clockwise synchronously, and because the stirring shaft is located at the eccentric position of the convex disc, the convex disc is driven to slide on the inner wall of the connecting frame when the stirring shaft rotates, and then the connecting frame is driven to periodically move left and right, and then the sliding rod I is driven to periodically slide left and right on the inner wall of the sliding sleeve, and meanwhile the sliding rod I can slide on the inner wall of the limiting notch, so that the mixing rate of blood and heparin is enhanced.

3. When the slide bar periodically moves left and right, can drive the connecting rod synchronous motion, and then drive the mixed casing and periodically slide left and right at three tops of spout, can vibrate the inside blood of mixed casing and heparin mixed solution, simultaneously, can collide with the vibration board when the mixed casing moves left and right, and then strengthen and vibrate the effect, can prevent simultaneously that the solution from gluing and gluing at mixed shells inner wall, inconvenient cleanness, through setting up spring two, can cushion the vibration power that produces during the collision.

4. When the slide bar one periodically moves left and right, can drive two sets of slide bars two at the inner wall left and right sides slip of spout two and spout one, when two sets of slide bars two slide left and right sides slip, can drive two sets of extrusion heads and move left in step, this moment left side extrusion head can gradually to the inside cambered surface dish direction of blood interpolation mechanism be close to, and then gradually upwards extrude the cambered surface dish, and then drive communicating pipe and upwards move, communicating pipe upwards move can drive the baffle upwards extrusion cambered surface dish, simultaneously drive transport box and upwards move gradually for transport box top and the liquid level separation of the inside blood of storage shell, simultaneously, can drive two sets of piston plates when the communicating pipe upwards moves and upwards slide at the connection shells inner wall, the weeping hole of communicating pipe outer wall is close to the mouth of pipe position of transport box gradually, make weeping hole and the mouth of pipe position intercommunication, at this moment transport box inside blood of storage flows into inside communicating pipe owing to the effect of gravity, and outwards ooze to the liquid pipe inside through setting up the piston plate, prevent blood from oozing outside, guide into inside the mixing shell inside, realize the inside automatic function of adding blood to the inside the mixing shell, because of the same structure with the inside heparin extrusion mechanism, when the inside heparin extrusion mechanism is added to the inside the same side, can realize the inside heparin extrusion mechanism.

Drawings

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

FIG. 2 is a schematic view of the structure of the storage box of the present invention;

FIG. 3 is a schematic view of the material taking port structure of the present invention;

FIG. 4 is a schematic view of a mounting plate according to the present invention;

FIG. 5 is a schematic view of a connecting frame structure according to the present invention;

FIG. 6 is a schematic diagram of a cam structure according to the present invention;

FIG. 7 is a schematic diagram of a mixing housing according to the present invention;

FIG. 8 is a schematic view of the structure of the blood feeding mechanism of the present invention.

In the figure: 1. a storage box; 2. a material taking port; 3. a first chute; 4. a limit notch; 5. a driving motor; 6. a stirring shaft; 7. a cam; 8. a sleeve; 9. stirring fan blades; 10. a mounting plate; 11. a second chute; 12. a sliding sleeve; 13. a first slide bar; 14. a connecting rod; 15. a second slide bar; 16. an extrusion head; 17. a connection frame; 18. uniformly mixing the shell; 19. a discharge port; 20. a chute III; 21. a support column; 22. a storage housing; 23. a fluid supplementing pipe; 24. a catheter; 25. a connection housing; 26. a communicating pipe; 27. a transfer box body; 28. a piston plate; 29. a weeping hole; 30. a baffle; 31. a first spring; 32. an arc surface disk; 33. an oscillating plate; 34. a second spring; 35. a blood adding mechanism; 36. heparin adding mechanism.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Embodiment one:

as shown in fig. 1-5, a multiple freedom degree clinical laboratory blood mixing device comprises a storage box 1, a driving motor 5 is fixedly arranged in the middle of the upper surface of the storage box 1, a mounting plate 10 is fixedly connected to the inner wall of the storage box 1, sliding sleeves 12 are fixedly connected to the left end and the right end of the bottom of the mounting plate 10, sliding rods 13 are slidably connected to the inner wall of the sliding sleeves 12, a connecting frame 17 is fixedly connected to one end, close to the driving motor 5, of each of the two groups of sliding rods 13, limiting notches 4 are formed in the left side wall and the right side wall of the storage box 1, one end, far from the connecting frame 17, of each of the sliding rods 13 is slidably connected with the inner wall of the limiting notch 4, an output shaft of the driving motor 5 penetrates through the storage box 1 and the outer wall of the mounting plate 10, a stirring shaft 6 is fixedly connected to the outer wall of the mounting plate 10, a sliding groove III 20 is formed in the bottom of the inner wall of the storage box 1, a mixing shell 18 is slidably connected to the top of the sliding groove III 20, a connecting rod 14 is fixedly connected between the top of the mixing shell 18 and the bottom of the sliding rod 13, the bottom end of the stirring shaft 6 extends to the inside of the mixing shell 18, a sleeve 8 is fixedly connected to the outer wall of the stirring shaft 6, one end of the stirring shaft is far from the connecting sleeve 17, the inner wall of the stirring blade 18 is fixedly connected to the inner wall of the stirring blade 18, and is fixedly connected to the stirring blade 9 inside the stirring solution.

When the mixed solution of the blood and the heparin in the mixing shell 18 is required to be mixed, the driving motor 5 is started, the stirring shaft 6 is driven to rotate clockwise through the driving motor 5, the sleeve 8 and the stirring fan blades 9 are driven to rotate clockwise synchronously, the mixed solution of the blood and the heparin in the mixing shell 18 is stirred, and the mixing rate of the blood and the heparin is enhanced.

As shown in fig. 4, the inner walls of the left and right sides of the storage box 1 are fixedly connected with a second spring 34, and one end of the second spring 34, which is close to the mixing shell 18, is fixedly connected with a vibrating plate 33 for vibrating the solution inside the mixing shell 18.

When the first 13 periodic left and right movement of slide bar, can drive connecting rod 14 synchronous motion, and then drive mixing casing 18 at spout three 20 periodic left and right sliding, can vibrate the inside blood of mixing casing 18 and heparin mixed solution, simultaneously, can collide with vibration board 33 when mixing casing 18 moves about, and then strengthen the vibration effect, can prevent simultaneously that the solution from gluing at mixing casing 18 inner wall, inconvenient cleanness, through setting up spring two 34, can cushion the vibration power that produces during the collision.

As shown in fig. 3-4, a discharging hole 19 for discharging solution is arranged at the bottom of the front surface of the mixing shell 18, and a material taking hole 2 is arranged at the front surface of the storage box 1 opposite to the discharging hole 19.

When the mixed liquid in the mixing shell 18 is required to be taken, the container is only required to be placed in the storage box 1 from the position of the material taking port 2, and the valve of the material discharging port 19 is opened to take the liquid.

Embodiment two:

as shown in fig. 6, on the basis of the first embodiment, further expansion is performed: the outer wall fixedly connected with flange 7 of (mixing) shaft 6, (mixing) shaft 6 is in the eccentric position of flange 7, and flange 7 and the inner wall sliding connection of connecting frame 17.

When the extrusion head 16 rotates clockwise, the convex disc 7 is driven to rotate clockwise synchronously, and when the stirring shaft 6 rotates, the convex disc 7 is driven to slide on the inner wall of the connecting frame 17 due to the fact that the stirring shaft 6 is located at the eccentric position of the convex disc 7.

As shown in fig. 4, the first sliding groove 3 is formed on both left and right sides of the upper surface of the storage box 1, the second sliding groove 11 is formed on the upper surface of the mounting plate 10 opposite to the lower portion of the first sliding groove 3, the second sliding rod 15 is fixedly connected to one side of the first left sliding rod 13, which is close to the connecting frame 17, and one side of the first right sliding rod 13, which is far away from the connecting frame 17, and the second sliding rod 15 is slidably connected with the second sliding groove 11 and the inner wall of the first sliding groove 3, and the extrusion head 16 is fixedly connected to the top of the second sliding rod 15.

And then drive connecting frame 17 periodical left and right movement, and then drive slide bar one 13 periodical left and right sliding at sliding sleeve 12 inner wall, slide bar one 13 can slide at spacing notch 4 inner wall simultaneously, reinforcing blood and heparin's mixing rate.

Embodiment III:

as shown in fig. 8, on the basis of the second embodiment, further expansion is performed: the left side of the upper surface of the storage box 1 is fixedly provided with a blood adding mechanism 35 for adding blood, the blood adding mechanism 35 comprises a support column 21, the bottom end of the support column 21 is fixedly connected with the upper surface of the storage box 1, the top end of the support column 21 is fixedly connected with a storage shell 22, the upper surface of the storage shell 22 is fixedly connected with a liquid supplementing pipe 23 for supplementing liquid to the inside of the storage shell 22, the bottom of the storage shell 22 is fixedly connected with a connecting shell 25, the bottom of the inner wall of the storage shell 22 is provided with a through hole, the inner wall of the through hole is axially and slidably connected with a communicating pipe 26, the top end of the communicating pipe 26 extends to the inside of the storage shell 22 and is fixedly connected with a transfer box 27, and the bottom end of the communicating pipe 26 penetrates through the lower surface of the connecting shell 25 and is fixedly connected with a baffle 30.

When the slide bars 13 move left and right periodically, the two groups of slide bars 15 are driven to slide left and right on the inner walls of the slide grooves 11 and 3, when the two groups of slide bars 15 slide left, the two groups of extrusion heads 16 are driven to move left synchronously, at this time, the left extrusion heads 16 gradually approach the direction of the cambered surface disc 32 inside the blood adding mechanism 35, further gradually upwards extrude the cambered surface disc 32, further drive the communicating pipe 26 to move upwards, the upward movement of the communicating pipe 26 drives the baffle 30 to upwards extrude the cambered surface disc 32, and simultaneously drives the transfer box 27 to move upwards gradually, so that the top of the transfer box 27 is gradually separated from the liquid level of blood stored inside the storage shell 22, and simultaneously, the upward movement of the communicating pipe 26 drives the two groups of piston plates 28 to slide upwards on the inner wall of the connecting shell 25, at this time, the liquid leakage holes 29 of the outer wall of the communicating pipe 26 gradually approach the position of the transfer box 27, so that the liquid leakage holes 29 are communicated with the pipe opening of the liquid guide tube 24, at this time, the blood stored inside the transfer box 27 flows into the communicating pipe 26 due to the action of gravity, flows out into the liquid guide tube 24, and finally flows out into the liquid guide tube 24 through the liquid leakage holes 29, and the piston plates 28 are arranged, so that the blood is prevented from being mixed evenly inside the shell 18, and the blood is automatically and evenly mixed into the shell 18.

As shown in fig. 8, the right outer wall of the communicating tube 26 is provided with a drain hole 29, the upper and lower sides of the outer wall of the communicating tube 26, which is opposite to the drain hole 29, are respectively sleeved with a piston plate 28, the piston plates 28 are slidably connected with the inner wall of the connecting housing 25, the outer wall of the communicating tube 26 is provided with a first spring 31, the first spring 31 is located between the upper surface of the baffle 30 and the lower surface of the connecting housing 25, the upper side of the right side wall of the connecting housing 25 is fixedly connected with a liquid guide tube 24, one end of the liquid guide tube 24 is communicated with the inner wall of the connecting housing 25, the other end of the liquid guide tube 24 penetrates the upper surface of the storage box 1 and extends into the mixing housing 18, and the bottom of the baffle 30 is fixedly connected with a cambered surface disc 32 which can be contacted with the bottom of the extrusion head 16.

When the second slide bar 15 moves rightwards, the extrusion head 16 is gradually separated from the bottom of the cambered surface disc 32, the cambered surface disc 32 and the communicating pipe 26 start to move downwards under the action of elastic potential energy of the first spring 31, the liquid leakage hole 29 is gradually separated from the pipe opening of the liquid guide pipe 24, and meanwhile, the transfer box 27 moves downwards to enter blood, so that an automatic liquid supplementing function is realized, and the function of continuously adding blood into the mixing shell 18 is realized.

As shown in fig. 8, a heparin adding mechanism 36 for adding heparin is fixedly mounted on the upper surface of the storage box 1, the heparin adding mechanism 36 is located at the right side of the driving motor 5, the structure of the heparin adding mechanism 36 is identical to that of the blood adding mechanism 35, the volume of the heparin adding mechanism 36 is smaller than that of the blood adding mechanism 35, and the volume of the transport box body 27 inside the heparin adding mechanism 36 is one tenth of that of the transport box body 27 inside the blood adding mechanism 35.

Because the addition of blood and heparin is performed simultaneously, the volume of the heparin adding mechanism 36 is smaller than that of the blood adding mechanism 35, and the volume of the transport box body 27 inside the heparin adding mechanism 36 is one tenth of that of the transport box body 27 inside the blood adding mechanism 35, the adding ratio is 10:1 when the blood and heparin are added each time, the adding precision of the blood and the heparin is improved, and the phenomenon that the fusion degree of the blood and the heparin is insufficient or the fusion is excessive due to certain error caused by manual adding of staff is prevented.

The working principle of the scheme is as follows: when the blood mixing device for the multiple-degree-of-freedom clinical laboratory is used, when the mixed solution of the blood and the heparin in the mixing shell 18 is required to be mixed, the driving motor 5 is started, the stirring shaft 6 is driven to rotate clockwise through the driving motor 5, the sleeve 8 and the stirring fan blades 9 are driven to rotate clockwise synchronously, the mixed solution of the blood and the heparin in the mixing shell 18 is stirred, and the mixing rate of the blood and the heparin is enhanced;

meanwhile, when the extrusion head 16 rotates clockwise, the convex disc 7 is driven to rotate clockwise synchronously, and as the stirring shaft 6 is positioned at the eccentric position of the convex disc 7, the stirring shaft 6 drives the convex disc 7 to slide on the inner wall of the connecting frame 17 so as to drive the connecting frame 17 to move left and right periodically, and further drive the first slide rod 13 to slide left and right periodically on the inner wall of the sliding sleeve 12, and meanwhile, the first slide rod 13 can slide on the inner wall of the limiting notch 4, so that the mixing rate of blood and heparin is enhanced;

meanwhile, when the first slide bar 13 periodically moves left and right, the connecting rod 14 is driven to synchronously move, so that the mixing shell 18 is driven to periodically slide left and right at the top of the third slide groove 20, the mixed solution of blood and heparin in the mixing shell 18 can be oscillated, meanwhile, when the mixing shell 18 moves left and right, the mixed solution collides with the oscillation plate 33, so that the oscillation effect is enhanced, meanwhile, the solution can be prevented from being stuck to the inner wall of the mixing shell 18, the cleaning is inconvenient, and the vibration force generated during collision can be buffered by arranging the second spring 34;

meanwhile, when the slide bars 13 move left and right periodically, the two groups of slide bars 15 are driven to slide left and right on the inner walls of the slide grooves 11 and 3, when the two groups of slide bars 15 slide left, the two groups of extrusion heads 16 are driven to move left synchronously, at the moment, the left extrusion heads 16 gradually approach the direction of the cambered surface disc 32 in the blood adding mechanism 35, further gradually upwards extrude the cambered surface disc 32, further drive the communicating pipe 26 to move upwards, the upward movement of the communicating pipe 26 drives the baffle 30 to upwards extrude the cambered surface disc 32, and simultaneously drives the transfer box 27 to gradually move upwards, so that the top of the transfer box 27 is gradually separated from the liquid level of blood stored in the storage shell 22, and simultaneously, the upward movement of the communicating pipe 26 drives the two groups of piston plates 28 to slide upwards on the inner wall of the connecting shell 25, at the moment, the liquid leakage holes 29 of the outer wall of the communicating pipe 26 are gradually approach the pipe orifice position of the transfer box 27, so that the liquid leakage holes 29 are communicated with the pipe orifice position of the liquid guide tube 24, at the moment, the blood stored in the transfer box 27 flows into the liquid guide tube 24 due to the action of gravity, flows out of the liquid guide tube 24, and automatically flows into the inner part of the liquid guide tube 24 through the liquid leakage holes 29, and the liquid guide plate 28 is automatically mixed into the inner part 18 through the storage shell 18, and the inner part is evenly mixed evenly;

when the second slide bar 15 moves rightwards, the extrusion head 16 is gradually separated from the bottom of the cambered surface disc 32, the cambered surface disc 32 and the communicating pipe 26 start to move downwards under the action of elastic potential energy of the first spring 31, the liquid leakage hole 29 is gradually separated from the pipe orifice of the liquid guide pipe 24, and meanwhile, the transfer box 27 moves downwards to enter blood, so that an automatic liquid supplementing function is realized, and the function of continuously adding blood into the uniformly mixed shell 18 is realized in a reciprocating manner;

because the structure of the heparin adding mechanism 36 is the same as that of the blood adding mechanism 35, when the second right slide bar 15 moves leftwards, the right extrusion head 16 is driven to extrude the cambered surface disc 32 inside the heparin adding mechanism 36, and the function of continuously adding heparin inside the uniformly mixed shell 18 can be realized in the same way;

because the addition of blood and heparin is performed simultaneously, the volume of the heparin adding mechanism 36 is smaller than that of the blood adding mechanism 35, and the volume of the transport box body 27 inside the heparin adding mechanism 36 is one tenth of that of the transport box body 27 inside the blood adding mechanism 35, the adding proportion is 10:1 when the blood and the heparin are added each time, the adding precision of the blood and the heparin is improved, and the phenomenon that the fusion degree of the blood and the heparin is insufficient or the fusion is excessive due to certain error caused by manual adding of staff is prevented;

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a multi freedom clinical laboratory is with blood mixing device, includes storage box (1), its characterized in that: the utility model discloses a stirring device, which is characterized in that a driving motor (5) is fixedly arranged in the middle of the upper surface of a storage box (1), a mounting plate (10) is fixedly connected to the inner wall of the storage box (1), sliding sleeves (12) are fixedly connected to the left and right ends of the bottom of the mounting plate (10), sliding rods (13) are slidably connected to the inner wall of the sliding sleeves (12), connecting frames (17) are fixedly connected to one ends of the sliding rods (13) close to the driving motor (5), limit notches (4) are formed in the left and right side walls of the storage box (1), one end of the sliding rods (13) far away from the connecting frames (17) is connected with the inner wall of the limit notches (4) in a sliding manner, an output shaft of the driving motor (5) penetrates through the storage box (1) and the outer wall of the mounting plate (10) to be fixedly connected with a stirring shaft (6), sliding grooves (20) are formed in the bottom of the inner wall of the storage box (1), a mixing shell (18) is slidably connected to the top of the sliding grooves (20), a stirring sleeve (18) is fixedly connected to the top of the sliding rods (13), a stirring shaft (6) is fixedly connected to the bottom of the sliding sleeve (13), the outer wall of the sleeve (8) is fixedly connected with a stirring fan blade (9) for stirring the solution in the mixing shell (18);

the left side of the first sliding rod (13) is close to one side of the connecting frame (17) and the right side of the first sliding rod (13) is far away from one side of the connecting frame (17) and fixedly connected with a second sliding rod (15), the second sliding rod (15) is in sliding connection with the second sliding rod (11) and the inner wall of the first sliding rod (3), and the top of the second sliding rod (15) is fixedly connected with an extrusion head (16);

the left side of the upper surface of the storage box (1) is fixedly provided with a blood adding mechanism (35) for adding blood, the blood adding mechanism (35) comprises a support column (21), the bottom end of the support column (21) is fixedly connected with the upper surface of the storage box (1), the top end of the support column (21) is fixedly connected with a storage shell (22), the upper surface of the storage shell (22) is fixedly connected with a fluid supplementing pipe (23) for supplementing fluid for the inside of the storage shell (22), the bottom of the storage shell (22) is fixedly connected with a connecting shell (25), the bottom of the inner wall of the storage shell (22) is provided with a through hole, the inner wall of the through hole is axially and slidably connected with a communicating pipe (26), and the top end of the communicating pipe (26) extends to the inside of the storage shell (22) and is fixedly connected with a transfer box (27);

the bottom end of the communicating pipe (26) penetrates through the lower surface of the connecting shell (25) and is fixedly connected with a baffle plate (30), a liquid leakage hole (29) is formed in the outer wall of the right side of the communicating pipe (26), piston plates (28) are sleeved on the upper side and the lower side of the outer wall of the communicating pipe (26) relative to the liquid leakage hole (29), and the piston plates (28) are in sliding connection with the inner wall of the connecting shell (25); the outer wall fixedly connected with flange (7) of (6) stirring axle, (6) are in the eccentric position of flange (7), the inner wall sliding connection of flange (7) and connecting frame (17).

2. The multiple degree of freedom clinical laboratory blood blending device of claim 1, wherein: the inner walls of the left side and the right side of the storage box (1) are fixedly connected with a second spring (34), and one end, close to the mixing shell (18), of the second spring (34) is fixedly connected with a vibrating plate (33) for vibrating the solution in the mixing shell (18).

3. The multiple degree of freedom clinical laboratory blood blending device of claim 1, wherein: the front bottom of the mixing shell (18) is provided with a discharge hole (19) for discharging solution, and the front of the storage box (1) is provided with a material taking hole (2) relative to the position of the discharge hole (19).