CN217332494U - Liquid transfer device for test tube - Google Patents

Abstract

The utility model provides a liquid transfer device for test tubes, which comprises a bottom plate; and a supporting frame combined and fixed with the bottom plate; the bottom plate comprises a test tube rack for bearing test tubes; the pipetting device also comprises a moving mechanism fixed on the support frame and a pipetting mechanism connected with the moving mechanism; the moving mechanism is configured to drive the pipetting mechanism to move in a first direction or in a second direction perpendicular to the first direction; the pipetting mechanism comprises a clamping assembly and a pipetting assembly; the clamping assembly is used for clamping and driving the tube cover of the test tube to move, and the liquid transfer assembly is used for sucking or discharging liquid in the test tube. The problems of low working efficiency and large occupied space of the conventional equipment are solved.

Description

Liquid transfer device for test tube

Technical Field

The utility model relates to the technical field of medical equipment. And more particularly to a pipetting device for test tubes.

Background

Glycated hemoglobin (GHb) is a product of hemoglobin in red blood cells combined with sugars in serum. It is formed by slow, continuous and irreversible glycation reactions, the content of which depends on the blood glucose concentration and the contact time of blood glucose and hemoglobin, and is independent of factors such as the blood drawing time, whether the patient is fasting, whether insulin is used, and the like. Therefore, GHb effectively reflects the average blood glucose level of the diabetic over the past 8-12 weeks. GHb consists of HbA1a, HbA1b, and HbA1c, wherein HbA1c accounts for about 70%, and is structurally stable, and thus is used as a monitoring index for diabetes control.

In the analysis process of the glycosylated hemoglobin, the time spent in the pretreatment of blood accounts for about 60% of the total time, and is the most important link which is also the most time-wasting, a plurality of automatic sample pretreatment systems are available in the prior art, but most of the automatic sample pretreatment systems are obtained by puncturing with steel needles, the sampling needles need to be frequently cleaned, the time is long, the cross contamination of samples cannot be avoided, and the existing equipment structure is complex and needs to occupy a large table board.

SUMMERY OF THE UTILITY MODEL

To the above problem, the utility model provides a move liquid device for test tube is low in order to solve current equipment work efficiency, problem that occupation space is big.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a move liquid device for test tube, include:

a base plate; and

a support frame combined and fixed with the bottom plate;

the bottom plate comprises a test tube rack for bearing test tubes;

the pipetting device also comprises a moving mechanism fixed on the support frame and a pipetting mechanism connected with the moving mechanism;

the moving mechanism is configured to drive the pipetting mechanism to move in a first direction or in a second direction perpendicular to the first direction;

the pipetting mechanism comprises a clamping assembly and a pipetting assembly;

the clamping component is used for clamping and driving the tube cover of the test tube to move,

the pipetting assembly is used for sucking or discharging liquid in the test tube.

Furthermore, it is preferable that the test tube includes a label having information for identifying the test tube;

the pipetting device also comprises an identification component, and the identification component comprises a scanner and a driving piece;

the scanner is used for scanning labels of the test tubes in the test tube rack;

the driving piece is used for driving the scanner to move towards the direction close to or far away from the test tube rack.

In addition, the preferable scheme is that the bottom plate is provided with a slide rail, the slide rail is arranged along the first direction, the bottom wall of the test tube rack is provided with a slide block correspondingly matched with the slide rail, and the test tube rack is configured to move along the extending direction of the slide rail.

Furthermore, it is preferable that the clamping assembly includes a clamping member and a first driving member;

the clamping piece comprises a clamping jaw part for clamping and fixing the pipe cover and a driving part for driving the clamping jaw part to be in a clamping or loosening state;

the clamping piece is configured to be driven by the first driving piece to reciprocate up and down.

In addition, preferably scheme is that the centre gripping subassembly still includes the steering wheel that combines fixedly with the drive division of holder, the steering wheel includes the drive shaft and combines the hourglass portion of fixing at the drive shaft tip, the steering wheel is configured to be used for the drive to connect hourglass portion and rotate around the drive shaft axis.

Furthermore, it is preferable that the pipetting assembly includes a first pipetting member, a second driving member, and a third driving member;

the first pipetting member is configured to be reciprocally movable up and down by the driving of the second driving member, and the second pipetting member is configured to be reciprocally movable up and down by the driving of the third driving member.

In addition, it is preferable that the bottom plate further comprises a tip storage box for replacing the tip of the pipetting assembly and a waste tip recovery box for collecting the used tip.

In addition, preferably, the bottom plate further comprises a vibration device;

the vibrating device comprises a base, a vibrating motor, a vibrating supporting plate and a pore plate, wherein the base is fixedly combined with the bottom plate;

the oscillating supporting plate is configured to drive the orifice plate to vibrate under the driving of an oscillating motor;

the pipetting assembly is also used for pumping out the liquid in the test tube and discharging the liquid into the orifice plate.

In addition, preferably, the bottom plate further comprises a heating device, the heating device comprises a heating base combined and fixed on the bottom plate, a bearing plate combined and fixed on the heating base, and a heating sheet positioned between the heating base and the bearing plate;

the bearing plate bears and is fixed with a target plate;

the heating sheet is used for heating the target plate on the bearing plate;

the liquid-transfering component is also used for pumping out the liquid in the pore plate and discharging the liquid onto the target plate.

Furthermore, it is preferable that a plurality of arc-shaped grooves are provided on an end portion of the claw portion.

The utility model has the advantages that:

the utility model discloses a cooperation between each mechanism can realize in order that bar code scanning, test tube open and shut cover and sample, sample dilute to vibrate and mix and target plate sample application operation, can satisfy the requirement that moves liquid of different volume samples moreover, and high efficiency, do not have cross contamination ground to accomplish whole operation flow moreover, and the accuracy is high, and this liquid-moving device compact structure occupation space is little moreover, has solved current equipment work efficiency low, the big problem of occupation space.

Drawings

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic structural diagram of the test tube rack of the present invention.

Fig. 3 is a side view of the test tube rack of the present invention.

Fig. 4 is a schematic structural diagram of the moving mechanism of the present invention.

Fig. 5 is a schematic structural view of the pipetting mechanism of the present invention.

Fig. 6 is a schematic structural view of the clamping assembly of the present invention.

Fig. 7 is a schematic structural diagram of the oscillation device of the present invention.

Fig. 8 is an assembly view of the heating apparatus of the present invention.

Fig. 9 is a schematic structural diagram of the identification component of the present invention.

Detailed Description

Various exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It should be noted that: unless specifically stated otherwise, the relative arrangement of parts and steps, numerical expressions, and numerical values set forth in these embodiments do not limit the scope of the present invention.

The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the invention, its application, or uses.

Techniques and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail, but are intended to be considered a part of the specification where appropriate.

In all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be discussed further in subsequent figures.

The problem that the existing equipment is low in working efficiency and large in occupied space is solved. The utility model provides a move liquid device for test tube, it is shown with fig. 1 to fig. 9 to combine, specifically a move liquid device for test tube includes: a base plate 10; and a support frame 20 fixed in combination with the base plate 10; the bottom plate 10 comprises a test tube rack 30 for bearing test tubes; the pipetting device also comprises a moving mechanism 40 fixed on the support frame 20 and a pipetting mechanism 50 connected with the moving mechanism 40; the moving mechanism 40 is configured to drive the pipetting mechanism 50 to move in a first direction or in a second direction perpendicular to the first direction; the pipetting mechanism 50 comprises a clamping assembly 51 and a pipetting assembly 52; the holding assembly 51 is used for holding and driving the tube cover of the test tube to move, and the liquid-transferring assembly 52 is used for sucking or discharging liquid in the test tube.

It can be understood that the test tube comprises a tube body and a tube cover, and the holding component clamps and drives the tube cover of the test tube to move so as to realize the separation or buckling of the tube body and the tube cover of the test tube; the test tube may be a blood collection tube for collecting a blood sample.

In this embodiment, the pipetting mechanism 50 further comprises a mounting plate, and the holding assembly 51 and the pipetting assembly 52 are respectively fixed on the mounting plate in a combined manner.

Specifically, referring to fig. 4, the moving mechanism 40 includes a first driving pair 41 arranged along a first direction and two second driving pairs 42 arranged along a second direction, the pipetting mechanism 50 is fixed on a moving part of the first driving pair 41, and the pipetting mechanism 50 can reciprocate on the first driving pair 41 along the first direction; the two side ends of the first driving pair 41 are respectively connected and fixed on the moving part of the second driving pair 42, and the first driving pair 41 and the pipetting mechanism 50 can reciprocate on the second driving pair 42 along the second direction; the two second driving pairs 42 are respectively combined and fixed with the support frame 20. The combination of the first driving pair 41 and the second driving pair 42 may be a gantry timing belt linear module, which can convert the rotational force of the driving motor into an indirect acting force in the first direction or the second direction indirectly through the moving part without directly acting the driving force on the movement of the liquid transfer mechanism 50, and the indirect acting force makes the movement in the first direction and the second direction easier to control, thereby improving the control accuracy.

The liquid transfer device for test tubes provided by the utility model drives the liquid transfer mechanism 50 connected with the moving mechanism 40 to move along a first direction or a second direction through the moving mechanism 40; after the pipetting mechanism 50 moves to a proper position, the clamping assembly 51 on the pipetting mechanism 50 clamps and drives the tube cover of the test tube to move, so that the tube body and the tube cover of the test tube are separated or buckled, and the pipetting assembly 52 sucks or discharges liquid in the test tube. Centre gripping subassembly 51 cooperates the centre gripping test tube cap with moving mechanism 40, the completion is taken off or is covered the operation of test tube cap, convenient and fast, in time cover the tube cap and can prevent that the sample liquid in the test tube from receiving the pollution, utilize move liquid subassembly 52 and moving mechanism 40 cooperation can absorb the sample liquid in the test tube and transfer to on the orifice plate 74 or shift the mixed liquid on the orifice plate 74 to the target plate 84 application of sample, show and improve work efficiency and stability.

In a specific embodiment, as shown in fig. 9, the test tube includes a label with information for identifying the test tube; the pipetting device further comprises an identification assembly 60, wherein the identification assembly 60 comprises a scanner 61 and a driving member 62; the scanner 61 is used for scanning the labels of the test tubes in the test tube rack 30; the driving member 62 is used for driving the scanner 61 to move towards or away from the test tube rack 30. Each tube is provided with an independent and unique identification label (e.g., bar code, two-dimensional code) at its shaft and is exposed from one side of the tube rack 30. The driving part 62 can be a linear sliding table, the scanner 61 is combined and fixed with the moving part of the linear sliding table through a connecting plate, bar codes on different test tubes are identified through the scanner 61, and the subsequent distinguishing and recording of a large number of detection results are facilitated. This device can dispose a plurality of test-tube racks 30, and removal portion through sharp slip table drives scanner 61 and can realize scanning the scanning scope that the record enlarges scanner 61 to the test tube on the test-tube rack 30, is showing improvement work efficiency.

In a specific embodiment, the bottom plate 10 includes a slide rail 31, the slide rail 31 is disposed along a first direction, the bottom wall of the test tube rack 30 includes a slide block 32 correspondingly matched with the slide rail 31, and the test tube rack 30 is configured to move along an extending direction of the slide rail 31.

The test-tube rack 30 can move on slide rail 31, and at test-tube rack 30 along the gliding in-process of slide rail 31, can utilize identification assembly 60 to scan each test tube on the test-tube rack 30 in proper order, identification assembly 60 inputs the information of each sample test tube automatically, need not carry out individual independent scanning to the sample test tube to improve liquid workstation's work efficiency. Specifically, can drive test-tube rack 30 with the help of clamping component 51, clamping component 51 downstream moves to the suitable position in test-tube rack 30 top, and clamping component 51 closes the claw, grasps the test tube and drives test-tube rack 30 and make identification component 60 scan one by one along slide rail 31 reciprocating motion, accomplishes test tube bar code scanning towards test tube bar code label.

In a specific embodiment, as shown in fig. 5 and 6, the clamping assembly 51 includes a clamping member 511 and a first driving member 512; the clamping piece 511 comprises a clamping jaw part 5111 for clamping and fixing the pipe cover and a driving part 5112 for driving the clamping jaw part 5111 to be in a clamping or loosening state; the clamping member 511 is configured to be reciprocally movable up and down by the first driving member 512. The first driving member 512 may be a ball screw, and the clamping member 511 is fixed to a nut of the ball screw through a nut seat. In one specific example, the driving part 5112 may be an electric claw that drives the jaw part 5111 to clamp the tube cover; the gripping claw portions 5111 are driven by the electric claws to move outward or inward to grip the test tube cap. The ball screw is fixed on the assembly plate, and the movable nut can drive the clamping piece 511 to reciprocate up and down.

Further, when the tube cap of the fixed test tube is held by the holding member 511, the holding member 511 is moved upward by the ball screw, so that the tube cap is moved upward to be separated from the tube body. When the tube cap of the fixed test tube of holder 511 centre gripping, make holder 511 remove downwards through ball to drive the tube cap and remove downwards and the pipe shaft lock.

Further, the holding member 51 is moved to a proper position above the test tube rack 30 by the moving mechanism 40, and the left and right jaw engagement claws of the jaw portion 5111 grip the cap and move upward or the jaw portion 5111 moves downward and opens, completing the opening and closing of the cap. It once can realize that a plurality of sample test tubes uncap (for example once can realize the automatic of 12 samples and open and close the lid), treat to get the sample liquid after, can close the lid to a plurality of sample test tubes simultaneously, prevent that the test tube from uncapping for a long time and causing environmental pollution.

In this embodiment, the clamping assembly 51 further includes a steering engine 513 fixedly coupled to the driving portion 5112 of the clamping member 511, the steering engine 513 includes a driving shaft and a leakage receiving portion 5131 fixedly coupled to an end portion of the driving shaft, and the steering engine 513 is configured to drive the leakage receiving portion 5131 to rotate around an axis of the driving shaft. Through the setting, the leakage receiving part 5131 can assist the clamping of the clamping jaw part 5111 to fix the pipe cover, and after the pipe cover is clamped by the clamping jaw part 5111, the leakage receiving part 5131 can rotate to the lower part of the clamping jaw part 5111 under the driving of the steering engine 513, so that the pipe cover is prevented from dropping in the moving process.

In this embodiment, a plurality of arc-shaped grooves 5113 are provided on the end portion of the claw portion 5111. The arc groove 5113 is matched with the tube cover, and the arc groove 5113 is formed by the bottom wall surface of the clamping jaw portion 5111 sinking inwards and penetrates through the inner side wall of the clamping jaw portion 5111. Through a plurality of arc walls 5113 that set up on the clamping jaw portion 5111, can with meet the fixed sample test tube cap of hourglass portion 5131 cooperation to can press from both sides simultaneously and get a plurality of tube caps, it is swift convenient, improve work efficiency, save the cost of labor.

In order to realize the quick replacement of the pipette tip of the pipetting assembly 52 and improve the working efficiency, the base plate 10 further comprises a tip storage box 11 for replacing the pipette tip of the pipetting assembly 52 and a waste tip recovery box 12 for collecting the used pipette tip.

In a specific embodiment, as shown with reference to fig. 5, the pipetting assembly 52 includes a first pipetting member 521, a second pipetting member 522, a second driving member 523 and a third driving member 524; the first transfer element 521 is configured to be vertically movable by the second driving element 523, and the second transfer element 522 is configured to be vertically movable by the third driving element 524.

The second driving member 523 may be a ball screw, and the first pipetting member 521 is fixed to a nut of the ball screw by a nut holder. The third driving member 524 may be a ball screw, and the second pipetting member 522 is fixed to a nut of the ball screw by a nut holder.

In this embodiment, the first pipetting element 521 and the second pipetting element 522 are both pipettors, and the pipettors need to be equipped with tips for further work, and the pipettors may be small-range pipettors or large-range pipettors. Taking a sample to be detected as blood as an example, when blood in a blood sampling tube is sucked and transferred into the pore plate 74, a large-range pipettor can be adopted, the large-range pipettor moves to a proper position above the pipetting tip box, moves downwards to prick the pipette tip, and in the state that the blood sampling tube is uncovered, the large-range pipettor moves to a proper position of the blood sampling tube and drives the pipette tip to move downwards until the bottom of the blood sampling tube sucks 5 μ L of blood, the large-range pipettor moves upwards and is driven by the moving mechanism 40, and the pipetting assembly 52 can move to different positions; through computer instructions, the liquid-moving assembly 52 can move to the oscillating device 70, the ion water diluent is preset in the pore plate 74, 5 mu L of blood is discharged into the pore plate 74 by the wide-range liquid-moving machine, the liquid moving is completed, and the used suction head is discarded at the waste suction head recovery box 12;

when the liquid in the pore plate 74 needs to be transferred to the target plate 84 for spotting, a small-range pipettor can be adopted, the small-range pipettor moves to a proper position above the pipetting tip box and moves downwards, after the pipette tips are pricked, the pipettor moves to the oscillating device 70 through an instruction to suck 1-3 mu L of mixed liquid, the mixed liquid moves to the position above the target plate 84 through the moving mechanism 40, and the mixed liquid is spotted on the target plate 84.

In a specific embodiment, referring to fig. 7, the base plate 10 further includes a vibrating device 70; the oscillating device 70 comprises a base 71 fixed on the bottom plate 10, an oscillating motor 72 positioned on the base 71, an oscillating support plate 73 correspondingly matched with the oscillating motor 72, and a pore plate 74 fixed on the oscillating support plate 73; the oscillating supporting plate 73 is configured to drive the orifice plate 74 to oscillate under the driving of the oscillating motor 72; the pipetting assembly 52 is also used to aspirate and discharge fluids from the test tube into the well plate 74. Vibrate device 70 and be used for vibrating the mixture to the liquid in the orifice plate 74, vibrate motor 72 cooperation and vibrate layer board 73, including the shell fragment that is used for fixed orifice plate 74 in four faces of vibrating layer board 73, after vibrating motor 72 starts, the accessible normal position location photoelectric switch sensor fixes a position, ensures that orifice plate 74 stops in same position, makes the sampling position accurate. Specifically, after the oscillating motor 72 receives the oscillating mixing instruction, the oscillating motor 72 rotates, the oscillating supporting plate 73, the orifice plate 74 and the blood diluent in the orifice perform oscillating motion with an amplitude of 2-3mm under the action of the cam, after oscillating for 30-45s, the oscillating motor 72 receives a stop instruction to stop rotating, and in order to ensure that the orifice plate 74 stops at the same position, the positioning is performed by an in-situ positioning photoelectric switch sensor.

In a specific embodiment, referring to fig. 8, the bottom plate 10 further includes a heating device 80, and the heating device 80 includes a heating base 81 fixed on the bottom plate 10, a bearing plate 82 fixed on the heating base 81, and a heating sheet 83 located between the heating base 81 and the bearing plate 82; the bearing plate 82 bears and fixes a target plate 84; the heating plate 83 is used for heating the target plate 84 on the bearing plate 82; the pipetting assembly 52 is also used to aspirate liquid from the well plate 74 and discharge it onto the target plate 84. The top wall surface of the heating base 81 is provided with a heat insulation plate 85, the heat insulation plate 85 comprises a groove formed by inwards sinking the top surface of the heat insulation plate, a heating sheet 83 is assembled in the groove, the target plate 84 is positioned on the bearing plate 82, and a temperature sensor capable of adjusting the heating temperature is arranged in the bearing plate 82. Heating base 81 is fixed in on bottom plate 10, heat insulating board 85 can prevent that heating plate 83 from heating base 81, influence heating efficiency, generate heat when heating plate 83 circular telegram, because heating plate 83 and loading board 82 contact of closely laminating, the heat conducts on loading board 82 well, loading board 82 continues on conducting the heat to target plate 84, realize target plate 84's heat drying, furthermore, set up temperature sensor in the loading board 82, heat on conducting target plate 84 through the sensor adjustment, can adjust target plate 84 heating temperature, realize the heat drying of different temperatures. When the heating sheet 83 receives a heating instruction, the heating sheet is electrified to generate heat, and simultaneously the heat is conducted to the target plate 84 through the bearing plate 82, the temperature can be set at 30-45 ℃, after the mixed liquid is completely crystallized and dried, the power is cut off and the heating and drying are completed.

It should be noted that the test tube rack 30 can clamp the test tube on the test tube rack 30 through a clamping structure, as shown in fig. 2 and fig. 3, the clamping structure includes a cam rod 33 fixed on the test tube rack 30 through a hinge shaft, a pressing plate 34 for pressing the test tube, and a pressing rod 35 penetrating through the pressing plate 34; the pressing plate 34 is correspondingly matched with the cam rod 33 through a pressing rod 35, the pressing rod 35 is connected with the cam rod 33 through a rotating shaft, a spring 36 is sleeved on the pressing rod 35, one end of the spring 36 abuts against the pressing plate 34, and the other end of the spring 36 abuts against the test tube rack 30; the cam lever 33 is rotatable about a rotation shaft to clamp the test tube between the test tube rack 30 and the inner side surface of the pressing plate 34. Utilize above-mentioned setting to realize the stable fixed while easy operation of test tube swiftly save operating time greatly, place the test tube in test-tube rack 30, can once only place a plurality of test tubes, for example once can place 12 test tubes. The pressing rod 35 penetrates through the pressing plate 34 and the test tube rack 30 and then is connected with the cam rod 33, the cam rod 33 is connected with the pressing rod 35 through a rotating shaft, the cam rod 33 rotates by taking the rotating shaft as a central shaft, a cam structure is arranged at the shaft hole of the cam rod 33, when the cam rod 33 rotates, due to the effect of the cam structure, the pressing rod 35 pulls the pressing plate 34 to move towards a sample test tube, and then the test tube is pressed through a silica gel pad on the pressing plate 34, so that the test tube is clamped; when the cam lever 33 is rotated to the position where the cam radius is minimum, the pressing plate 34 is pushed to a position away from the test tube by the elastic force of the compression spring 36, so that the test tube is loosened and can be easily taken out from the test tube rack 30. Can play the effect of protection test tube simultaneously through the effect that silica gel pad can be more firm of centre gripping prevents that pressure strip 34 from damaging the test tube.

It can be understood that a mass spectrometer is a scientific instrument that uses the electromagnetic principle to separate ions according to different mass-to-charge ratios, and further measures the mass and content of a substance. The matrix-assisted laser desorption ionization time-of-flight mass spectrometer (MALDI-TOF) is a branch of the mass spectrometer, and can quickly and accurately analyze and identify various samples at the same time, wherein the samples are usually fixed on a target point on a target plate and then sent into the matrix-assisted laser desorption ionization time-of-flight mass spectrometer (MALDI-TOF) for analysis and identification. The current operation of fixing the sample on the target plate is generally completed manually, and the working mode has low efficiency, and the spotting precision is not high, so that the final analysis result of the mass spectrometer is affected.

In addition, the existing automatic sample applicator can not be matched with a matrix-assisted laser desorption ionization time-of-flight mass spectrometer for analyzing and identifying samples. In the prior art, equipment in the domestic market mainly takes an imported brand as a main part, is high in price, low in degree of cut with specific application in the domestic market, low in compatibility and poor in product pertinence, is mainly universal equipment, is mainly used for pretreatment of some molecular diagnosis platforms, such as liquid transfer, plate moving, vibration and the like, and is relatively simple in function.

The utility model discloses a cooperation between each mechanism can realize in order that bar code scanning, test tube open and shut cover and sample, sample dilute and vibrate mix and target plate sample application operation to fuse above-mentioned various functions in an organic whole, improved compatibility greatly, and can satisfy the liquid-moving requirement of different volume samples, moreover high efficiency, accomplish whole operation flow without cross contamination, this liquid-moving device compact structure occupation space is little moreover, it is low to have solved current equipment work efficiency, problem that occupation space is big.

Additionally, the utility model provides a move liquid device need not loaded down with trivial details operating procedure, fool places the blood sample test tube, and full-automatic processing before the glycated hemoglobin detection of accomplishing, operation process is simple, and the time of waiting for the result is shorter, and factor influence such as no manual operation has moreover guaranteed the accuracy of result, has improved the accuracy.

Obviously, the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention, and it is obvious for those skilled in the art to make other variations or changes based on the above descriptions, and all the embodiments cannot be exhausted here, and all the obvious variations or changes that belong to the technical solutions of the present invention are still in the protection scope of the present invention.

Claims (10)

1. Pipetting device for test tubes, comprising:

a base plate; and

a support frame combined and fixed with the bottom plate;

the bottom plate comprises a test tube rack for bearing test tubes;

the pipetting device also comprises a moving mechanism fixed on the support frame and a pipetting mechanism connected with the moving mechanism;

the moving mechanism is configured to drive the pipetting mechanism to move in a first direction or in a second direction perpendicular to the first direction;

the pipetting mechanism comprises a clamping assembly and a pipetting assembly;

the clamping component is used for clamping and driving the tube cover of the test tube to move,

the pipetting assembly is used for sucking or discharging liquid in the test tube.

2. Pipetting device according to claim 1,

the test tube comprises a label with information for identifying the test tube;

the pipetting device also comprises an identification component, and the identification component comprises a scanner and a driving piece;

the scanner is used for scanning labels of the test tubes in the test tube rack;

the driving piece is used for driving the scanner to move towards the direction close to or far away from the test tube rack.

3. The pipette device according to claim 1, wherein the bottom plate includes a slide rail arranged along the first direction, the bottom wall of the test tube rack includes a slider correspondingly engaged with the slide rail, and the test tube rack is configured to move along an extending direction of the slide rail.

4. A pipetting device as recited in claim 1 wherein the gripper assembly comprises a gripper member and a first drive member;

the clamping piece comprises a clamping jaw part for clamping and fixing the pipe cover and a driving part for driving the clamping jaw part to be in a clamping or loosening state;

the clamping piece is configured to be driven by the first driving piece to reciprocate up and down.

5. The pipetting device according to claim 4, wherein the holding assembly further comprises a steering engine fixedly combined with the driving part of the holding member;

the steering wheel includes the drive shaft and combines to fix the hourglass portion at the drive shaft tip, the steering wheel is configured to be used for the drive to leak the portion and rotate around the drive shaft axis.

6. Pipetting device according to claim 1, characterized in that the pipetting assembly comprises a first pipetting member, a second drive member and a third drive member;

the first pipetting member is configured to be reciprocally movable up and down by the driving of the second driving member, and the second pipetting member is configured to be reciprocally movable up and down by the driving of the third driving member.

7. The pipette device according to claim 1, wherein a tip storage cassette for replacing a tip with a pipette assembly and a waste tip recovery cassette for collecting a used tip are further included on the bottom plate.

8. The pipette device according to claim 1, wherein the bottom plate further comprises a shaking device thereon;

the vibrating device comprises a base, a vibrating motor, a vibrating supporting plate and a pore plate, wherein the base is fixedly combined with the bottom plate;

the oscillating supporting plate is configured to drive the orifice plate to vibrate under the driving of an oscillating motor;

the pipetting assembly is also used for pumping out the liquid in the test tube and discharging the liquid into the orifice plate.

9. The pipetting device of claim 1, wherein the base plate further comprises a heating device thereon, the heating device comprising a heating base fixedly coupled to the base plate, a carrier plate fixedly coupled to the heating base, and a heating plate positioned between the heating base and the carrier plate;

the bearing plate bears and is fixed with a target plate;

the heating sheet is used for heating the target plate on the bearing plate;

the pipetting assembly is also used for pumping out the liquid in the pore plate and discharging the liquid onto the target plate.

10. A pipetting device as recited in claim 5 wherein the end of the jaw portion is provided with a plurality of arcuate slots.

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