CN116272556B - Medicine test medicine mixed loading equipment - Google Patents

Abstract

The utility model relates to the technical field of mixers, in particular to medical test medicine mixing equipment which comprises a tube body, a sleeve and a shaft tube, wherein the sleeve is rotatably arranged in the tube body, one end of the sleeve is connected with a plurality of soft plugs for being plugged into the tube ports for fixing, and the shaft tube is provided with two soft plugs and is coaxially and rotatably arranged in the tube body respectively. According to the utility model, the rotatable sleeve is arranged in the tube body, the soft plug arranged at one side of the sleeve is used for fixing the test tube, the circumferential shaking of the test tube can be realized without additional driving equipment, the movable ring is arranged between the two shaft tubes for driving the sleeve to rotate and can be in fastening fit with any shaft tube, when the movable ring is fixed with the shaft tube capable of elastically rotating in the tube body, the elastic potential energy of the shaft tube can be increased by the rotation of the sleeve, the shaft tube can rotate in the opposite direction after the rotation of the movable ring, the reciprocating shaking effect is realized, and the mixing efficiency of medicines is improved.

Description

Medicine test medicine mixed loading equipment

Technical Field

The utility model relates to the technical field of mixers, in particular to medical test medicine mixing equipment.

Background

In some medical trials, it is desirable to mix together drugs of different compositions, typically by shaking the multiple-component drugs in a test tube to form a mixed drug.

In the prior art, as the application number is CN201621459828.4, the patent name is a test medicine mixing and shaking device, which specifically comprises a square box body with an opening at the front side and a plurality of vertical guide grooves which are arranged in the square box body and are vertically arranged, wherein a lifting cylinder is correspondingly arranged at the bottom of each vertical guide groove, a test tube fixing block is correspondingly fixed at the top end of each lifting cylinder, and the rear side extension part of the test tube fixing block is arranged in the corresponding vertical guide groove; the utility model has the advantages of simple structure, convenient use, convenient mechanical shaking of a plurality of test tubes and improved shaking efficiency.

However, although the above-mentioned technique can realize that a plurality of test tubes shake evenly simultaneously, at first drive through extra electric drive equipment, and in actual test scene, increase drive equipment can bring the increase of cost, secondly, shake evenly the in-process at the liquid medicine, different medicines shake evenly the mode difference, simple rotatory mixing effect of going on a direction is not good, the mixed degree of liquid medicine is not high, need reciprocal shake even, and some mixed solution that mixing speed is fast only need several rotations just can shake even, thereby not only test cost is high, and be unsuitable for all medicine mixes evenly, influence the test efficiency of whole mixed medicine.

Therefore, there is a need for a medical test drug compounding device to solve the above-mentioned problems.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects existing in the prior art, the utility model provides medical test medicine mixing equipment, which can effectively solve the problems that the cost is increased and the shaking efficiency of the whole medicine liquid is low due to a test mode in the prior art.

Technical proposal

In order to achieve the above purpose, the utility model is realized by the following technical scheme:

the utility model provides medical test medicine mixing equipment, which comprises a pipe body, a sleeve and a shaft pipe, wherein one end of the sleeve is rotatably arranged in the pipe body, a plurality of soft plugs used for being plugged into the inside of a test pipe opening are connected to one end of the sleeve, the shaft pipes are provided with two soft plugs and are coaxially rotatably arranged in the pipe body respectively, each shaft pipe is sleeved outside the sleeve, the outer wall of each shaft pipe is connected with the inner wall of the pipe body through an elastic piece, a movable ring capable of rotating along the circumferential direction of the pipe body is further arranged between the two shaft pipes, the movable ring is sleeved outside the sleeve and can axially reciprocate along the sleeve to be matched with any shaft pipe, two sides of the movable ring are respectively provided with a pin block, one end of the shaft pipe facing the movable ring is axially provided with a first rail, one end of the sleeve facing the movable ring is axially provided with a second rail, and the first rail and the second rail are oppositely arranged, and after the pin blocks enter into a space between the first rail and the second rail, the pin blocks are simultaneously fixed with the first rail and the second rail.

Further, a shifting sleeve capable of rotating along the circumferential direction of the pipe body is arranged in the middle of the pipe body, and the movable ring is coaxially arranged at the inner end of the shifting sleeve and can reciprocate along the axial direction of the shifting sleeve.

Further, the first track is formed by arranging two fixing strips axially arranged along the shaft tube, the second track is identical to the first track in structure, the distances between the two corresponding fixing strips in the first track and the second track are identical and the lengths are identical, the pin blocks are block-shaped and can be simultaneously embedded into spaces formed in the corresponding end faces of the first track and the second track, and the end faces of the pin blocks are distributed in a staggered manner with the fixing strips in the first track and the second track.

Further, a pushing block capable of axially guiding and moving along the pipe body is further arranged in the pipe body, the pushing block is arranged at one end, far away from the soft plug, of the pipe body, a threaded section is arranged at the outer end of one side of the shaft tube, close to the pushing block, of the pushing block, the pushing block is sleeved at the outer end of the threaded section, and when the shaft tube rotates, the pushing block is in threaded fit with the threaded section to axially reciprocate along the pipe body, and an adjusting block capable of adjusting the distance between the pushing block and the threaded section is arranged at one end, far away from the shaft tube, of the threaded section.

Further, the adjusting block is in threaded fit with the threaded section, and one end of the adjusting block facing the pushing block is parallel to the end face of the pushing block.

Further, the adjusting block is in a tube shape, and scales are arranged on the outer end face of the adjusting block.

Further, the soft plug is in a round table shape, the whole soft plug is made of rubber, a plurality of rubber rings are distributed at the outer end of the soft plug along the axial direction of the soft plug, and one end with a small diameter of the soft plug is arranged outwards.

Further, the end face of the movable ring, which faces the outer side of the pipe body, is provided with anti-skid patterns.

Further, the outer end of the tube body is provided with a marking groove along the axial direction of the tube body, the position of the outer end wall of the tube body corresponding to the marking groove is provided with a visual window along the circumferential direction of the tube body, the outer end of the dial sleeve is provided with a groove body identical to the marking groove, the visual window penetrates through the outer wall of the tube body, and the outer end of the shaft tube is provided with a reset mark parallel to the marking groove along the axial direction of the shaft tube.

Advantageous effects

Compared with the known public technology, the technical scheme provided by the utility model has the following beneficial effects:

according to the utility model, the rotatable sleeve is arranged in the tube body, the soft plug arranged at one side of the sleeve is used for fixing the test tube, the circumferential shaking of the test tube can be realized without additional driving equipment, the movable ring is arranged between the two shaft tubes for driving the sleeve to rotate and can be in fastening fit with any shaft tube, when the movable ring is fixed with the shaft tube capable of elastically rotating in the tube body, the elastic potential energy of the shaft tube can be increased by the rotation of the sleeve, the shaft tube can rotate in the opposite direction after the rotation of the movable ring, the reciprocating shaking effect is realized, and the mixing efficiency of medicines is improved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It is evident that the drawings in the following description are only some embodiments of the present utility model and that other drawings may be obtained from these drawings without inventive effort for a person of ordinary skill in the art.

FIG. 1 is a schematic view of the appearance of a main structure according to an embodiment of the present utility model;

FIG. 2 is a schematic diagram of the structure A in FIG. 1 according to an embodiment of the present utility model;

FIG. 3 is a schematic diagram of the structure of FIG. 1 at B according to an embodiment of the present utility model;

FIG. 4 is a schematic view of a partial cross-sectional structure of a movable ring according to an embodiment of the present utility model;

FIG. 5 is a schematic diagram of an exploded view of a movable ring according to an embodiment of the present utility model;

FIG. 6 is a schematic cross-sectional elevation view of a bottom bracket tube structure in accordance with an embodiment of the present utility model;

FIG. 7 is a schematic view of the structure of FIG. 6C according to an embodiment of the present utility model;

FIG. 8 is a schematic diagram of an exploded construction of a dial sleeve and a cannula according to an embodiment of the present utility model;

FIG. 9 is a schematic view of a partial cross-sectional structure of a dial sleeve according to an embodiment of the present utility model;

fig. 10 is a schematic diagram of the structure D in fig. 9 according to an embodiment of the present utility model.

Reference numerals in the drawings represent respectively: 1. a tube body; 11. a marking groove; 12. a visual window; 13. a round hole; 2. a sleeve; 21. a soft plug; 211. a rubber ring; 22. a second track; 3. a shaft tube; 31. a first track; 32. a locking ring; 33. a torsion spring; 34. a threaded section; 35. resetting the mark; 4. a movable ring; 41. a pin block; 5. a poking sleeve; 6. a pushing block; 7. an adjusting block; 71. a scale.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The utility model is further described below with reference to examples.

Examples:

in the medical field, in research and development of medicines or medicine property tests, medicines with different components are required to be quantitatively mixed and proportioned, and particularly in medicine mixing with liquid solutes as main components, various medicine components are required to be placed in a test tube for shaking and homogenizing.

However, the mixing frequency required for different medicines is different, and some medicines can be fully mixed only by rotating for a plurality of weeks, but in some medicines with solid contents, the oscillating frequency and the reciprocating shaking are required to be improved so as to improve the mixing speed of the medicines.

Most shaking equipment in the prior art is provided with an electric control device, so that the mode of controlling the oscillation frequency is too complex while the test cost is increased, and the shaking equipment cannot be suitable for medicines with different components.

Therefore, referring to fig. 1 to 10, the present utility model provides a medicine mixing device for medical test, mainly, the rotation of a tube 2 connected with a test tube is realized by the rotation of a dial sleeve 5, and different shaft tubes 3 are locked by a movable ring 4 on the dial sleeve 5, which can reciprocate along the axial direction of the tube 2, wherein one shaft tube 3 elastically rotates in a tube body 1, the other shaft tube 3 rotates in the tube body 1, when the shaft tube 3 is fixed with the elastic rotation, the dial sleeve 5 rotates the shaft tube 3, and simultaneously, elastic potential energy is accumulated, and in the rotation process, the movable ring 4 is fixed with the tube 2, so that the tube 2 rotates, the test tube connected with one side of the tube 2 starts rotating uniformly, and after the dial sleeve 5 is released, the elastic potential energy is instantaneously released, the tube 2 reversely rotates, so that the purpose of reciprocating rotating uniformly is achieved, and the medicine mixing degree is improved.

It is worth noting that the shaft tube 3 in the present case is sleeved on the sleeve 2, and a certain gap exists between the shaft tube and the sleeve.

In addition, the device also has a limiting function, as shown in fig. 3, when only a fixed number of rotations is needed, the distance between the adjusting block 7 and the pushing block 6 is adjusted, the closer the adjusting block 7 is to the pushing block 6, the fewer the number of rotations of the sleeve 2 is, different distances are tested before use, the actual number of rotations of the sleeve 2 can be accurately judged, and the whole scheme does not need additional electric control equipment.

Specifically, referring to fig. 1 and 8, the solution mainly includes three parts, namely a tube body 1, a sleeve 2 and a shaft tube 3, wherein the sleeve 2 is rotatably installed in the tube body 1, one end of the sleeve 2 is connected with a plurality of soft plugs 21 for being plugged into test tube ports for fixing, specifically, one end of the sleeve 2 is connected with a turntable, eight soft plugs 21 are arranged in the solution, each four soft plugs are in a group, and each group of soft plugs 21 is circumferentially distributed by taking the center of the turntable as the center of a circle.

Referring to fig. 5, the soft plug 21 is integrally in a shape of a circular truncated cone, and is made of rubber, a plurality of rubber rings 211 are axially distributed at the outer end of the soft plug 21 along the soft plug 21, one end with a small diameter of the soft plug 21 is arranged outwards, a test tube can be fixed by using larger friction force between the rubber rings 211 and glass, and the peripheral diameters of the rubber rings 211 are different, so that the soft plug is suitable for test tubes with different diameters.

Referring to fig. 5, two shaft tubes 3 are further disposed in the tube 1, the two shaft tubes 3 are coaxially disposed and can rotate in the tube 1, each shaft tube 3 is sleeved outside the sleeve 2 and coaxially disposed, one of the shaft tubes 3 elastically rotates in the tube 1, a torsion spring 33 is disposed between the tube 1 and the tube 3, an elastic member used for elastically rotating the shaft tube 3 is not particularly limited, and other elastic structures can be used instead.

And still be equipped with a movable ring 4 that can follow body 1 circumference pivoted between two central siphon 3, specific, body 1's middle part outer end is equipped with one and can follow body 1 circumference pivoted and dial the cover 5, and movable ring 4 coaxial establish and dial the inner of cover 5, and the outer end of movable ring 4 is connected on dialling the cover 5 through a plurality of connecting rods, when dialling the cover 5 and rotate, drives movable ring 4 and carries out synchronous rotation.

And a plurality of sliding grooves are formed in the outer end face of the shifting sleeve 5 along the axial direction of the shifting sleeve, the length of each sliding groove is larger than that of the connecting rod, and the movable ring 4 can reciprocate along the axial direction of the shifting sleeve 5 to be matched with any shaft tube 3.

Referring to fig. 4 to 6, specifically, two sides of the movable ring 4 are respectively provided with a pin block 41, one end of the shaft tube 3 facing the movable ring 4 is provided with a first track 31 matched with the pin block 41, the outer end of the sleeve 2 is provided with a second track 22 identical to the first track 31 along the axial direction thereof, and after the pin block 41 enters into a space between the first track 31 and the second track 22, (the corresponding end surfaces of the two sleeves 2 are provided with the second track 22), the pin block 41 is fixed with the first track 31 and the second track 22 simultaneously.

The first rail 31 is formed by arranging two fixing strips axially arranged along the shaft tube 3, the second rail 22 is identical to the first rail 31 in structure, the distances between the corresponding two fixing strips in the first rail 31 and the second rail 22 are identical, namely, the spaces between the first rail 31 and the second rail 22 respectively form a concave space with the inner end of the shaft tube 3 and the outer end of the sleeve 2, when the two concave spaces are symmetrical, the pin blocks 41 are inserted and simultaneously matched with the fixing strips connected with the first rail 31 and the second rail 22 for fixing, when the movable ring 4 starts to rotate, the sleeve 2 and the shaft tube 3 are driven to rotate simultaneously, in the scheme, the pin blocks 41 are made of rubber materials, the thickness of the pin blocks 41 is slightly thicker than the concave space between the first rail 31 and the second rail 22 (shown in the figure 7), so that after the pin blocks 41 are clamped in the concave space, a certain resistance is realized, the pin blocks 41 are pulled out, a certain force is required, the number of circles required for shaking the test tube is not too many, the pins are required to rotate reciprocally and the pins 41 can rotate normally, and the pins 41 are not separated from the concave space normally, and the pins 41 can rotate normally, and the pins 3 can rotate normally, and can not rotate.

In addition, two pin blocks 41 on the same side are arranged, friction force is further increased, and in the actual use process, the pin blocks 41 and the corresponding first track 31 and second track 22 can be adjusted by combining the normal required reagent weight, so that friction forces with different sizes are obtained, and the stability of the pin blocks 41 and the shaft tube 3 in fixation is improved.

It is noted that when one of the pin blocks 41 secures the sleeve 2 and the shaft tube 3, the other pin block 41 is disengaged from the other shaft tube 3.

Referring to fig. 6, a locking ring 32 is connected to one end of each shaft tube 3 facing the movable ring 4, the locking ring 32 is concentric with the sleeve 2 and is located at the outer side of the sleeve 2, and the first rail 31 and the second rail 22 are located at the outer side of the sleeve 2 corresponding to the locking ring 32 and the inner end surface of the locking ring 32, respectively, and the pin block 41 can slide into the annular space between the locking ring 32 and the outer end of the sleeve 2 and cooperate with the first rail 31 and the second rail 22 at the same time.

Referring to fig. 8, the pin block 41 is in a block shape and is simultaneously inserted into a space formed in the corresponding end surfaces of the first rail 31 and the second rail 22, and the end surfaces of the pin block 41 are offset from the fixing bars in the first rail 31 and the second rail 22.

Referring to fig. 3, the limiting function in this case is mainly realized by the adjusting block 7, a threaded section 34 is disposed at the outer end of one side of the shaft tube 3, a pushing block 6 capable of guiding and moving along the axial direction of the tube 1 is disposed in the tube 1, the pushing block 6 is disposed at one end of the tube 1 away from the soft plug 21, and the pushing block 6 is in threaded fit with the shaft tube 3, and when the shaft tube 3 rotates, is in threaded fit with the shaft tube 3 and moves reciprocally along the axial direction of the tube 1.

The adjusting block 7 is arranged at the outer side of the shaft tube 3, one end of the adjusting block faces the outer side of the tube body 1 and is in threaded fit with the shaft tube 3, one end of the adjusting block 6 facing the pushing block is parallel to the end face of the pushing block 6, the pushing block 6 can reciprocate on the threaded section 34 due to the rotation of the shaft tube 3, when the shaft tube 3 is rotated in the forward direction, the pushing block 6 moves towards one side direction of the adjusting block 7, at the moment, the adjusting block 7 is close to the pushing block 6 by rotating the adjusting block 7 (the position of the adjusting block 7 is adjusted in advance), and therefore after the pushing block 6 is abutted against the adjusting block 7, the adjusting block 7 limits the pushing block 6, and the shaft tube 3 is prevented from continuing to rotate.

Because regulating block 7 is independent of sleeve pipe 2 setting, be screw thread fit between the two, regulating block 7 is hollow cylinder structure, regulating block 7 cover is in sleeve pipe 2's outside and with sleeve pipe 2 screw thread fit (refer to fig. 6), promptly when sleeve pipe 2 rotates, regulating block 7 can rotate (fix sleeve pipe 2 and rotatory regulating block 7 in the time of adjusting), frictional force that produces when sleeve pipe 2 rotates is far less than the snap-in force between screw thread section 34 on regulating block 7 and sleeve pipe 2, and be located the side middle part of body 1 and offered a round hole 13 that the diameter is greater than regulating block 7 diameter, when regulating block 7 rotates on sleeve pipe 2 for body 1, regulating block 7 can pass round hole 13 and remove towards body 1 inside (outside) direction.

Referring to fig. 9 and 10, when the push block 6 contacts the adjusting block 7 along with the rotation of the sleeve 2, the push block 6 cannot move in the pipe body 1, that is, no matter how the dial sleeve 5 is rotated, the push block 6 cannot move because the movement of the push block 6 is limited by the adjusting block 7, and the natural sleeve 2 cannot rotate under the action of the screw force.

Referring to fig. 2, the adjusting block 7 is tubular, and in order to accurately determine the number of rotation cycles required and the shaking standards of different reagents before and after when the adjusting block 7 is adjusted, a scale 71 is specially provided on the outer end surface of the adjusting block 7 along the axial direction of the tubular body 1, where the scale 71 may be the distance between the adjusting block 7 and the pushing block 6, or may be tested in advance, and the reading of the scale 71 corresponds to the number of rotation cycles of the shaft tube 3, which is not limited too much.

When the adjusting block 7 rotates to axially move along the pipe body 1, the adjusting block 7 moves towards the inside of the pipe body 1, so that the scale 71 correspondingly changes, and the current maximum rotatable cycle number can be judged according to the scale 71.

For example, one of the scales 71 is marked as a, the a scale represents that the maximum rotation circle number of the shaft tube 3 can be limited by the current position of the adjusting block 7 to be 5 weeks, namely, when the sleeve 3 rotates for 5 weeks, the pushing block 6 moves to a distance just to enable the pushing block 6 to abut against the end face of the adjusting block 7, at the moment, the shaft tube 3 cannot continue rotating, the generated pushing force is far smaller than the biting force between the adjusting block 7 and the thread section 34, at the moment, the shifting sleeve 5 is loosened, the shaft tube 3 rebounds for 5 weeks under the action of elastic potential energy, and the purpose of controlling the rotation circle number is achieved, so that when different reagents need to be 5 weeks, only the mark A on the adjusting block 7 is flush with the plane where the round hole 13 is located, and when different reagents need to be rotated for different circle numbers, only the adjusting block 7 needs to be adjusted to the mark of the corresponding circle number, and the maximum rotation circle number of the shifting sleeve 5 is controlled by limiting the maximum stroke of the pushing block 6.

In order to ensure that the shifting sleeve 5 can be easily and not slipped when rotating, anti-slip patterns are formed on the end face of the movable ring 4, which faces the outer side of the pipe body 1, so that the friction force when the shifting sleeve 5 is driven to rotate when the movable ring 4 is held by a hand is improved.

Referring to fig. 2, regarding the resetting of the shaft tubes 3, in which one shaft tube 3 (elastically rotatable) has a rebound property, when the shaft tube 3 is completely stationary, the initial position is achieved by aligning the pin blocks 41 only, and the pin blocks 41 can be inserted into the concave space of the shaft tube 3 to be fixed by observing the positions of the approximate pin blocks 41;

in order to facilitate the resetting of the other shaft tube 3 (which cannot elastically rotate), namely, a marking groove 11 is formed at the outer end of the tube body 1 along the axial direction thereof, a visual window 12 which can see the shaft tube 3 (which cannot elastically rotate) is formed at the position corresponding to the marking groove 11, a resetting mark 35 is arranged at the outer end of the shaft tube 3, and the resetting mark 35 is observed from the visual window 12 by rotating the dial sleeve 5 until the relative position between the dial sleeve 5 and the shaft tube 3 at the moment is judged to be the same as the initial position, at the moment, the pin block 41 moves towards one side of the shaft tube 3, and the pin block 41 can be smoothly inserted into the concave space of the shaft tube 3.

The outer end of the sleeve 5 is also provided with a groove body identical to the marking groove 11, so that after the relative positions of the shaft tube 3 and the sleeve 5 are adjusted (the sleeve can not elastically rotate), the pin block 41 and the shaft tube 3 are fixed and rotated until the marking groove 11 is aligned with the groove body at the outer end of the sleeve 5, and the position of the sleeve 5 and the other shaft tube 3 (which can elastically rotate) at the moment is restored as before.

Working principle:

firstly, a poking sleeve 5 is rotated, when the poking sleeve 5 rotates, a sleeve 2 is driven to rotate, so that test tubes connected to one side of the sleeve 2 synchronously rotate, at the moment, movable rings 4 which can reciprocate along the axial direction of the sleeve 2 on the poking sleeve 5 are utilized to lock different shaft tubes 3 respectively, when the poking sleeve 5 is rotated to be fixed with the shaft tubes 3 which elastically rotate in a tube body 1, the shaft tubes 3 can rotate, meanwhile, elastic potential energy is accumulated, in the rotating process, the movable rings 4 can be fixed with the sleeve 2, the sleeve 2 can rotate, the test tubes connected to one side of the sleeve 2 can start rotating and shaking uniformly, after the poking sleeve 5 is released, the elastic potential energy is released instantaneously, the sleeve 2 can reversely rotate, so that the aim of reciprocating rotation and shaking uniformly is achieved, and the degree of medicine mixing is improved;

the other shaft tube 3 rotates in the tube body 1 and is fixed with the sleeve 2, the rotation cycle number is consistent with the rotation frequency of the movable ring 4, and two different shaking mixing modes are provided through the above.

In addition, still have spacing effect in this example, when only needing to rotate fixed week number, adjust the distance between regulating block 7 and the ejector pad 6, the regulating block 7 is nearer to ejector pad 6, and the week number of sleeve pipe 2 rotation is just less, tests different distances before using, and the actual rotation week number of sleeve pipe 2 can accurately judge the rotation week number of sleeve pipe 2 to whole scheme need not extra electrical equipment, and whole device is small, is applicable to environment such as laboratory.

The above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; these modifications or substitutions do not depart from the essence of the corresponding technical solutions from the protection scope of the technical solutions of the embodiments of the present utility model.

Claims (7)

1. A medical test drug compounding device, comprising:

a tube body;

the sleeve is rotatably arranged in the tube body, and one end of the sleeve is connected with a plurality of soft plugs for being plugged into the test tube ports to be fixed;

the two shaft tubes are coaxially arranged in the tube body in a rotating way respectively, one shaft tube elastically rotates in the tube body, the other shaft tube elastically rotates in the tube body, each shaft tube is sleeved on the outer side of the sleeve, and the outer wall of the shaft tube elastically rotating with the tube body is connected with the inner wall of the tube body through an elastic piece;

the movable ring is sleeved on the outer side of the sleeve and can reciprocate along the axial direction of the sleeve to be matched with any shaft tube, two sides of the movable ring are respectively provided with a pin block, one end, facing the movable ring, of the shaft tube is provided with a first track along the axial direction of the movable ring, one end, facing the movable ring, of the sleeve is provided with a second track along the axial direction of the movable ring, the first track and the second track are arranged oppositely, and after the pin blocks enter a space between the first track and the second track, the pin blocks, the first track and the second track are fixed simultaneously;

the middle part of the tube body is provided with a poking sleeve capable of rotating along the circumferential direction of the tube body, and the movable ring is coaxially arranged at the inner end of the poking sleeve and can reciprocate along the axial direction of the poking sleeve;

the first track is formed by arranging two fixing strips axially arranged along the shaft tube, the second track has the same structure as the first track, and the distances between the two corresponding fixing strips in the first track and the second track are the same and the lengths of the two fixing strips are the same;

the pin blocks are in a block shape and can be simultaneously embedded into spaces formed in the corresponding end faces of the first rail and the second rail, and the end faces of the pin blocks and fixing strips in the first rail and the second rail are distributed in a staggered manner;

when the poking sleeve rotates, the sleeve is driven to rotate, test tubes connected to the sleeve synchronously rotate, the poking sleeve is locked with different shaft tubes respectively by utilizing a movable ring capable of axially and reciprocally moving along the sleeve, when the poking sleeve is fixed with the shaft tube which elastically rotates in the tube body, elastic potential energy is accumulated while the shaft tube rotates, the movable ring is fixed with the sleeve, the sleeve rotates, after the poking sleeve is loosened, the elastic potential energy is released, and the sleeve reversely rotates;

the other shaft tube rotates in the tube body and is fixed with the sleeve, and the rotation cycle number is consistent with the rotation frequency of the movable ring, so that two different shaking mixing modes are provided.

2. The medical test drug mixing device according to claim 1, wherein a push block capable of guiding movement along the axial direction of the tube body is further arranged in the tube body, the push block is arranged at one end of the tube body far away from the soft plug, a threaded section is arranged at the outer end of one side of the shaft tube close to the push block, and the push block is sleeved at the outer end of the threaded section and is in threaded fit with the threaded section to reciprocate along the axial direction of the tube body when the shaft tube rotates;

wherein, be located the screw thread section and keep away from the one end of central siphon and be equipped with an adjustable and ejector pad between distance's the ejector pad.

3. A medical testing drug mixing device according to claim 2, wherein the adjustment block is threadedly engaged with the threaded section and one end facing the push block is parallel to an end face of the push block.

4. A medical test drug mixing device according to claim 3, wherein the regulating block is tubular and has graduations on its outer end face.

5. The medical test drug mixing and loading device according to claim 4, wherein the soft plug is in a shape of a circular table, the whole soft plug is made of rubber, and a plurality of rubber rings are axially distributed at the outer end of the soft plug along the soft plug;

wherein, the small diameter end of the soft plug is arranged outwards.

6. A medical test drug compounding device as defined in claim 5, wherein: the end face of the movable ring, which faces the outer side of the pipe body, is provided with anti-skid patterns.

7. A medical test drug compounding apparatus as defined in claim 1, wherein: the outer end of the tube body is provided with a marking groove along the axial direction of the tube body, the position of the outer end wall of the tube body corresponding to the marking groove is provided with a visual window along the circumferential direction of the tube body, the outer end of the poking sleeve is provided with a groove body identical to the marking groove, the visual window penetrates through the outer wall of the tube body, and the outer end of the shaft tube is provided with a reset mark parallel to the marking groove along the axial direction of the shaft tube.