CN114460321A

CN114460321A - Sample analyzer and test tube detection assembly thereof

Info

Publication number: CN114460321A
Application number: CN202210386931.4A
Authority: CN
Inventors: 谢伟; 甘小锋; 刘治志
Original assignee: Shenzhen Dymind Biotechnology Co Ltd
Current assignee: Shenzhen Dymind Biotechnology Co Ltd
Priority date: 2022-04-14
Filing date: 2022-04-14
Publication date: 2022-05-10

Abstract

The invention discloses a sample analyzer and a test tube detection assembly thereof, wherein the test tube detection assembly comprises a tube seat, an expansion piece movably arranged in the tube seat, a position sensor arranged corresponding to the expansion piece and a controller connected with the position sensor, the tube seat is provided with a first accommodating cavity for accommodating a tube to be tested, one end of the expansion piece extends into the first accommodating cavity to abut against the tube to be tested arranged in the first accommodating cavity, when tubes to be tested of different types are arranged in the first accommodating cavity, the expansion piece moves downwards at different heights relative to the tube seat, the position sensor generates different signals according to the positions of the expansion piece after moving downwards at different heights, the controller judges the type of the tube to be tested arranged in the first accommodating cavity according to the signals of the position sensor, and the invention identifies the type of the test tube in advance, the smooth proceeding of the sample detection and the accuracy of the detection result are ensured.

Description

Sample analyzer and test tube detection assembly thereof

Technical Field

The invention relates to the technical field of sample detection, in particular to a sample analyzer and a test tube detection assembly thereof.

Background

In an in vitro diagnostic apparatus such as a blood sample analyzer or a urine sample analyzer, particularly a blood sample analyzer, red blood cells, white blood cells, platelets, hemoglobin and the like in a sample are statistically analyzed through an electrical impedance detection channel or a flow optical detection channel, so that an auxiliary diagnostic basis is provided for diagnosis and treatment of a doctor.

Generally, blood samples are sealed in test tubes after being collected, and the types of the test tubes for storing the blood samples collected from different positions of a human body are different, for example, the collected amount of venous blood is large and the venous blood is usually stored in a common tube; the collected amount of peripheral blood is small and is usually stored in a microtube. In order to make the micro-tube automatically sample on the instrument like a common tube, the shapes of various micro-tubes are designed to be consistent with those of the common tube, and meanwhile, a conical cavity is designed in the micro-tube to gather samples to a certain height so as to facilitate the absorption of a sampling needle. However, there may be some variation in the design of tapered cavities for micro-tubes from different manufacturers, which may result in inconsistent cavity bottom heights for the tapered cavities.

Therefore, the type of the test tube must be accurately identified before sampling, and then the descending height of the sampling needle during sample suction is determined according to the type of the test tube, so that the problem that the accuracy of a detection result is influenced due to insufficient sample suction caused by insufficient descending height of the sampling needle is avoided, and the problem that the sampling needle is damaged or even punctures the test tube due to too large descending height of the sampling needle is also avoided. Most of the existing sample analyzers identify the types of test tubes by reading the bar codes on the test tubes, but the bar codes may fall off or be shielded by the test tube rack to cause misidentification, which affects the detection of the samples.

Disclosure of Invention

In view of the above, a sample analyzer and a test tube detecting assembly thereof are provided, which can accurately identify the type of the test tube.

On one hand, the invention provides a test tube detection assembly, which comprises a tube seat, an expansion piece movably arranged in the tube seat, a position sensor arranged corresponding to the expansion piece and a controller connected with the position sensor, wherein the tube seat is provided with a first accommodating cavity for accommodating a tube to be tested, one end of the expansion piece extends into the first accommodating cavity to abut against the tube to be tested arranged in the first accommodating cavity, when tubes to be tested of different types are arranged in the first accommodating cavity, the expansion piece moves downwards at different heights relative to the tube seat, the position sensor generates different signals according to the positions of the expansion piece after the expansion piece moves downwards at different heights, and the controller judges the type of the tube to be tested arranged in the first accommodating cavity according to the signals of the position sensor.

On the other hand, the invention provides a sample analyzer, which comprises the test tube detection assembly, the blending assembly, the sampling assembly and the sample detection assembly, wherein the controller controls the blending assembly and the sampling assembly to operate according to the type of a tube to be tested.

Compared with the prior art, when the sample analyzer is used, test tubes of different types can be placed on the same pipe frame, the position sensor of the test tube detection assembly generates different induction signals according to different displacements of the telescopic piece under the action of the test tubes of different types, and the controller judges the types of the test tubes and starts the blending assembly and the sampling assembly to perform corresponding operations according to the induction signals, so that the sample analyzer is simple in structure and accurate in detection result on the whole, and the smooth performance of sample detection and the accuracy of the detection result are ensured; meanwhile, the process of manually sorting and classifying different test tubes is omitted, extra time is not required to be occupied in the automatic identification process of the test tubes, operation is simplified, and testing speed is increased.

Drawings

FIG. 1 is a schematic diagram of an embodiment of a sample analyzer of the present invention.

Fig. 2 is a top view of the sample analyzer shown in fig. 1.

FIG. 3 is a schematic view of an embodiment of a cuvette testing assembly of the sample analyzer according to the present invention.

FIG. 4 is a schematic view of the cuvette testing assembly shown in FIG. 3 testing a first cuvette.

FIG. 5 is a schematic view of the cuvette testing assembly shown in FIG. 3 testing a second cuvette.

FIG. 6 is a schematic view of the cuvette testing assembly shown in FIG. 3 testing a third cuvette.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. One or more embodiments of the present invention are illustrated in the accompanying drawings to provide a more accurate and thorough understanding of the disclosed embodiments. It should be understood, however, that the present invention may be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein.

The same or similar reference numbers in the drawings correspond to the same or similar parts; in the description of the present invention, it should be understood that if there is an orientation or positional relationship indicated by the terms "upper", "lower", "left", "right", etc. based on the orientation or positional relationship shown in the drawings, it is only for convenience of describing the present invention and simplifying the description, but it is not intended to indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore, the terms describing the positional relationship in the drawings are only used for illustrative purposes and are not to be construed as limiting the present patent, and the specific meaning of the terms may be understood by those skilled in the art according to specific circumstances.

The invention provides a sample analyzer, which is used for detecting and analyzing a biological sample, in particular a blood sample. Fig. 1-2 illustrate an embodiment of the sample analyzer of the present invention, wherein the sample analyzer 100 comprises a plurality of components, such as an autosampler component 10, a cuvette detector component 20, a mixer component 30, a transporter component 40, a sampler component 50, and a sample detector component.

The autosampler assembly 10 is disposed at the front side of the main body of the sample analyzer 100, and includes an autosampler rail 12 extending along the X direction. In sample testing, a sample to be tested is usually stored in a test tube 60 in a sealed manner, and a plurality of test tubes 60 are placed on the same tube rack 70. The tube rack 70 moves along the automatic sample feeding track 12 under the action of a driving member, such as a motor, etc., so as to realize batch automatic sample feeding of the tubes 60 to be tested. In the illustrated embodiment, the loading platform 14 and the unloading platform 16 are respectively disposed at the left and right ends of the autosampler track 12, and after the tube rack 70 is fed into the autosampler track 12 from the loading platform 14, the tube rack moves along the autosampler track 12 so that the test tubes 60 are sequentially moved to the sample placement positions of the sample analyzer; the blending component 30 grabs the test tube 60 at the sample placement position into the machine for sampling and puts the sampled test tube 60 back to the tube rack 70; finally, the tube rack 70 continues to move with the sampled test tubes 60 to the unloading platform 16 and is unloaded.

In the sample detection, the test tube 60 used is roughly classified into a normal tube and a micro tube, and the micro tube is much smaller in volume than the normal tube. In the detection of blood samples, common tubes are often used to contain relatively large doses of venous blood; a micro-tube is often used to contain a relatively small dose of peripheral blood. Because the amount of the sample to be detected in the tube is different, the micro tube and the common tube preferably adopt different mixing modes. In order to facilitate automatic sample introduction, the common tube and the micro tube preferably have the same shape structure, except that the micro tube forms a tapered cavity at a certain height inside the common tube to collect a sample to be detected, and the tapered cavities of the micro tubes of different manufacturers have certain differences in design, so that the sampling heights of various types of micro tubes and the common tube are different, and the test tube 60 needs to accurately identify the type before sampling.

Fig. 4 to 6 exemplarily show three kinds of test tubes 60, hereinafter referred to as a first test tube 60a, a second test tube 60b, and a third test tube 60c, respectively, wherein the first test tube 60a is a micro tube having a first tapered cavity 62a formed therein; the second test tube 60b is a micro tube, and a second conical cavity 62b is formed inside; the third tube 60c is a normal tube and has a circular bottom 64. The first tapered cavity 62a has a cavity bottom slightly higher than the second tapered cavity 62b, and the circular arc bottom 64 is far lower than the cavity bottoms of the first tapered cavity 62a and the second tapered cavity 62 b. In the sample detection, the first, second, and

third test tubes

60a, 60b, and 60c may be placed in different tube holders 70, or the first, second, and

third test tubes

60a, 60b, and 60c may be placed in a single tube holder 70 in a mixed manner. It should be understood that the types of the test tubes 60 used in the sample test are not limited to 3.

The blending assembly 30 includes a gripper that can move in three directions X, Y, Z to grasp the test tube 60 at the sample station and transfer it to the other assemblies. The gripper is in its initial position, just above the sample placement position, and moves up and down to grip the test tube 60 on the tube rack 70. After gripping the test tube 60, the gripper first transfers it to the test tube detection assembly 20 for test tube type detection; then, according to the confirmed test tube type, the blending assembly 30 starts its corresponding mechanism to blend the test tube 60, and the blended test tube 60 is transferred to the sampling position by the transfer assembly 40 for sampling. The sampling assembly 50 includes a sampling needle 52, and according to the type of the test tube confirmed, the sampling needle 52 descends to a corresponding height to suck the sample to be detected in the test tube 60, and the sucked sample to be detected is injected into the sample detection assembly, and is fully mixed with a corresponding reagent to obtain a final detection result through an electrical impedance detection channel or a flow optical detection channel.

As shown in fig. 3, the test tube detecting assembly 20 includes a tube holder 22, a telescopic mechanism 24 disposed in the tube holder 22, a position sensor 26 disposed corresponding to the telescopic mechanism 24, and a controller electrically connected to the position sensor 26, wherein the controller determines the type of the test tube 60 according to a signal of the position sensor 26, and then generates a corresponding signal to control the operations of the blending assembly 30 and the sampling assembly 50.

The tube holder 22 is disposed inside the main body of the sample analyzer 100, preferably right behind the sample position, and the grip moves the test tube 60 back and forth in the Y direction after gripping the test tube 60, thereby transferring the test tube 60 into the tube holder 22. The top center of the tube seat 22 is recessed inward by a certain depth to form a first accommodating cavity 221 for accommodating the test tube 60, the caliber of the first accommodating cavity 221 is equal to the outer diameter of the test tube 60, and the depth is not greater than the height of the test tube 60. When the test tube 60 is placed in the first receiving cavity 221, the top of the test tube 60 is exposed out of the first receiving cavity 221. Preferably, the tube holder 22 is provided with a positioning member 28, and the positioning member 28 is used for pressing down the test tube 60 to maintain the height of the top thereof at the reference position H0. The height difference between the reference level H0 and the bottom of the first accommodating cavity 221 is not less than the height of the test tube 60, so that the test tube 60 is prevented from touching the bottom of the first accommodating cavity 221 during the pressing process, and the test tube 60 is prevented from being damaged.

The telescopic mechanism 24 includes an elastic member 241 and a telescopic member 243 connected to the elastic member 241. In the illustrated embodiment, the elastic member 241 is a coil spring that can be extended and contracted in the vertical direction (i.e., the axial direction of the test tube 60). In other embodiments, the elastic element 241 may also be a spring plate. The telescopic member 243 is a shaft rod vertically disposed, and has a bottom end connected to the elastic member 241, and a top end extending into the first accommodating cavity 221 to abut against the bottom of the test tube 60 placed in the first accommodating cavity 221. The diameter of the extension member 243 is smaller than the inner diameter of the test tube 60, and the top end of the extension member 243 can be extended into the interior of the test tube by a micro tube, such as the bottom openings of the first and

second test tubes

60a, 60b, to abut against the bottom of the

tapered cavities

62a, 62b, so that the contact position of the extension member 243 with different types of test tubes 60 is different, and the contact position corresponds to the bottom position of the sample to be tested in the test tube 60.

In this embodiment, a second accommodating cavity 223 for accommodating the elastic element 241 is formed in the tube seat 22, and the length of the elastic element 241 in the natural stretching state may be equal to or slightly less than the height of the second accommodating cavity 223, so that the elastic element 241 keeps the natural stretching state when not being subjected to an external force. The second accommodating cavity 223 is located below the first accommodating cavity 221, and preferably, the two accommodating cavities are coaxially arranged at an interval, the tube seat 22 is formed with a through hole 225 communicating the first accommodating cavity 221 and the second accommodating cavity 223, and the aperture of the through hole 225 is preferably matched with the diameter of the expansion part 243, so that the expansion part 243 can movably penetrate through the through hole 225 and move up and down relative to the tube seat 22. The perforation 225 guides the up-and-down movement of the telescopic member 243, so that the test tube 60 and the tube holder 22 are kept in a coaxial state, and the deflection is prevented from influencing the accuracy of the detection result.

The position sensors 26 are provided in plurality and spaced apart in the vertical direction, wherein one of the position sensors is an initial position sensor for sensing the position of the extensible member 243 in an initial state; other position sensors are used to sense the position of the telescopic member 243 under the action of the different types of test tubes 60, respectively, in a number corresponding to the number of types of test tubes used. In the illustrated embodiment, the number of the position sensors 26 is 4, and the position sensors include an initial position sensor 260, a first sensor 261, a second sensor 262 and a third sensor 263, which are sequentially arranged from top to bottom, and the first, second and

third sensors

261, 262 and 263 respectively sense the position of the telescopic member 243 under the action of the first, second and

third test tubes

60a, 60b and 60 c. Preferably, the bottom end of the telescopic member 243 is provided with a sensing portion 245 matched with the position sensor 26, and the sensing portion 245 can be a protruding blocking piece and the like, and can extend into the detection groove of each position sensor 260-263.

As shown in fig. 3, in the initial state of the test tube detecting assembly 20, the test tube 60 is not placed on the tube seat 22, the elastic member 241 is substantially in a freely extending state, the telescopic member 243 has the maximum length in the first accommodating cavity 221, the sensing portion 245 of the telescopic member 243 is close to the top end of the second accommodating cavity 223 and faces the initial position sensor 260, at this time, the initial position sensor 260 generates a signal S0 to the controller, and the controller determines that the test tube 60 is not placed on the tube seat 22 according to the signal S0. When the gripper puts the test tube 60 into the first accommodating cavity 221, the test tube detecting assembly 20 is started, the test tube 60 moves downward under the action of the positioning member 28, so that the height of the top of the test tube is kept at the reference position H0, and the bottom of the test tube 60 pushes the telescopic member 243 to move downward along with the test tube, so as to compress the elastic member 241.

As shown in fig. 4, when the first test tube 60a is placed into the first receiving cavity 221 of the tube holder 22 by the hand, the bottom of the first tapered cavity 62a abuts against the telescopic member 243. Since the height of the first tapered cavity 62a is higher relative to the positions of the second tapered cavity 62b of the second test tube 60b and the circular-arc bottom 64 of the third test tube 60c, the downward displacement L1 of the telescopic member 243 under the pushing of the first test tube 60a is minimum, and the sensing part 245 of the telescopic member 243 moves to face the first sensor 261. At this time, the first sensor 261 generates a signal S1 to the controller, which accordingly determines that the first test tube 60a is the first test tube. The elastic member 241 is slightly compressed by the compression of the first test tube 60a by the telescopic member 243. When the test is completed and the first test tube 60a is removed by the gripper, the elastic member 241 recovers elasticity and pushes the telescopic member 243 to move upwards for resetting.

As shown in fig. 5, when the second test tube 60b is placed into the first receiving cavity 221 of the tube holder 22 by the hand, the bottom of the second conical cavity 62b abuts against the telescopic member 243. Since the height of the second conical cavity 62b is slightly lower relative to the first conical cavity 62b, the downward displacement L2 of the telescopic member 243 pushed by the second test tube 60b is greater than L1, and the sensing part 245 of the telescopic member 243 moves to face the second sensor 262. At this point, the second sensor 262 generates a signal S2 to the controller, which in turn determines that the second test tube 60b is present. The elastic member 241 is further compressed by the compression of the second test tube 60b by the telescopic member 243. When the detection is completed and the second test tube 60b is removed by the gripper, the elastic member 241 recovers elasticity and pushes the telescopic member 243 to move upwards for resetting.

As shown in fig. 6, when the third test tube 60c is placed into the first receiving cavity 221 of the tube holder 22 by the hand, the arc bottom 64 thereof abuts against the telescopic member 243. Since the height of the arc bottom 64 is lower relative to the positions of the first conical cavity 62a and the second conical cavity 62b, the downward displacement L3 of the telescopic member 243 under the pushing of the third test tube 60c is maximum, and the sensing part 245 of the telescopic member 243 moves to be opposite to the third sensor 263. At this time, the third sensor 263 generates a signal S3 to the controller, and the controller determines that the third test tube 60c is based on the signal. The elastic member 241 is maximally compressed by the compression of the third test tube 60c by the telescopic member 243. When the detection is completed and the third test tube 60c is removed by the gripper, the elastic member 241 recovers elasticity and pushes the telescopic member 243 to move upwards for restoration.

In a specific embodiment, the position sensor 26 may be an optoelectronic position sensor, such as a correlation optical coupler, a reflection optical coupler, etc., and a transmitter and a receiver of the correlation optical coupler may be respectively disposed on the socket 22 and the expansion member 243; the transmitter and receiver of the reflective optocoupler may be both disposed on the stem 22, while the reflector may be disposed on the telescoping member 243 to enhance light reflection. In other embodiments, the position sensor 26 may also be a magnetic position sensor, such as a Hall device, and a magnet matching the Hall device may be disposed on the expansion member 243; alternatively, the position sensor 26 may be a contact position sensor or the like, which is not specifically illustrated here.

For each type of test tube 60, one of the position sensors 26 may generate a signal or one of the group of position sensors 26 may generate a signal, and the controller may determine the type of test tube according to the different signals generated as long as different signals can be generated for different types of test tubes 60. Preferably, each test tube 60 is labeled with a two-dimensional code, a bar code, etc. for recording the type of test tube and the corresponding information of the patient, including name, age, contact information, etc. Correspondingly, be provided with code reader on autoinjection track 12, at test tube 60 autoinjection's in-process, read the information in the test tube 60 label, not only can make the testing result can automatically with patient phase-match, can also with test tube detection subassembly 20's testing result mutual evidencing, ensure the accuracy to the judgement of test tube type.

After the sample analyzer 100 performs type detection on the test tube 60 through the test tube detection assembly 20, the blending assembly 30 starts a corresponding mechanism to perform blending operation on the test tube 60 according to a detection result, wherein after a gripper of a common tube (such as a third test tube 60 c) is lifted to a certain height, a rotating motor is started to drive the gripper and the gripped test tube 60 to perform blending in a mode of reversing, swinging, rotating and the like, so that a large amount of samples to be detected, such as venous blood and the like, can be rapidly blended; to the micro tube (such as the first test tube 60a and the second test tube 50 b), the blending component 30 is provided with a special blending mechanism, after the gripper is lifted to a certain height, the gripper moves in the XY plane to transfer the micro tube to the special blending mechanism, and blending is performed in modes such as high-frequency vibration, so that a sample to be tested with a small dosage, such as peripheral blood and the like, can be rapidly and fully blended, the cell morphology in the blood cannot be damaged, meanwhile, the sample to be tested is prevented from being stained on the tube wall as much as possible, and the availability of the sample to be tested is improved.

In a specific embodiment, the special blending mechanism includes a blending seat 34, and the blending seat 34 is disposed in the host machine and staggered with the initial position of the gripper in both the X direction and the Y direction. Preferably, the mixing base 34 and the tube holder 22 of the test tube detecting assembly 20 are arranged in the left-right direction along the X direction. After the test tube 60 is confirmed to be in the tube seat 22, if the test tube 60 is a micro tube, the controller enables the gripper to move along the X direction to transfer the test tube 60 from the tube seat 22 to the blending seat 34, meanwhile, a vibration motor of the special blending mechanism is started to blend the test tube 60 in the blending seat 34 in a high-frequency vibration mode and the like, after blending, the gripper drives the test tube 60 to move reversely along the X direction and then move backwards for a certain distance along the Y direction, and the blended test tube 60 is transferred to the transferring component 40; if the tube is a common tube, the test tube 60 is carried by the gripper to be uniformly mixed, and then the gripper moves backwards for a certain distance along the Y direction, and the uniformly mixed test tube 60 is transferred to the transfer component 40.

The transfer assembly 40 continues to move backwards along the Y direction, the test tube 60 after being uniformly mixed is moved to a sampling position for sampling, and the problem that the accuracy of a final detection result is influenced due to layering generated after a sample to be detected is placed for a period of time is effectively avoided. During sampling, the controller lowers the sampling needle 52 by different heights according to different types of test tubes. Initially, the sampling needle 52 is at a height H1. For the first test tube 60a, as shown in fig. 4, the sampling needle 52 is lowered by a minimum height h1 just enough to reach the bottom of the first conical cavity 62a to aspirate the sample to be measured; for the second test tube 60b, as shown in fig. 5, the descending height h2 of the sampling needle 52 is slightly larger than h1, and the sampling needle just can reach the bottom of the second test tube 60b to suck the sample to be measured; for the third tube 60c, as shown in fig. 6, the sampling needle 52 is lowered by a maximum height h3 just enough to reach the bottom of the third tube 60c to aspirate the sample to be measured. It should be understood that the lowered heights of the

different test tubes

60a, 60b, 60c sampled by the sampling pins 52 are only schematically shown in fig. 4-6, rather than placing the

test tubes

60a, 60b, 60c in the tube holders 22 of the test tube testing assembly 20 for sampling.

The detection assembly is disposed below the sampling assembly 50 and includes a plurality of reaction measurement cells distributed along the X-direction, and each reaction measurement cell is filled with a reagent required for sample detection. The sampling needle 52 has a sample dividing path along the X direction, and a plurality of sample dividing positions are provided on the sample dividing path, and each sample dividing position is provided corresponding to one of the reaction measurement cells. After a sufficient amount of sample to be measured is sucked into the test tube 60, the sampling needle 52 moves sequentially to each sample dividing position along the sample dividing path, and dispenses the sucked sample to be measured into each reaction measurement cell. And mixing the sample to be detected with a detection reagent in the reaction measuring cell, reacting, and then obtaining a final detection result by using optical, electric and other detection elements to finish the whole sample detection process. It should be understood that the movement paths of the transfer assembly 40 and the sampling needle 52 of the sampling assembly 50 may be set as desired and are not limited to the illustrated embodiment.

When the sample analyzer of the invention detects a sample, the flow mainly comprises the following steps:

automatically feeding samples, namely moving a pipe frame along a sample feeding path in the X direction to convey test tubes to a sample placing position;

test tube type detects the step, and in the test tube of grabbing the test tube of putting appearance position department and shifting the test tube to test tube determine module's tube socket, the test tube pushed down the extensible member and makes it produce the displacement, and position sensor produces corresponding signal according to the position after the extensible member removes and gives the controller, controls the type in accordance with this and judges the test tube:

when the test tube is a common tube, the controller generates a signal to start a rotating motor of the blending component, and the sample is blended on the test tube in a rotating, swinging or reversing mode; the sampling needle descends to a first height to sample the uniformly mixed test tube;

when the test tube is the microtube, the controller produces the signal and starts the vibrating motor of mixing subassembly, carries out the sample mixing to the test tube through the mode of high-frequency vibration, and the high test tube sampling after to the mixing of sampling needle decline second height, and wherein the second height is less than first height.

When the sample analyzer 100 is used,

test tubes

60a, 60b and 60c of different types can be mixed on the same tube frame 70, the position sensor 26 of the test tube detection assembly 20 generates different sensing signals according to different displacements of the telescopic member 243 under the action of the

test tubes

60a, 60b and 60c of different types, the controller judges the types of the test tubes according to the sensing signals and starts the mixing assembly 30 and the sampling assembly 50 to perform corresponding operations, and the mixing assembly 30 mixes the test tubes 60 of different types in different ways, so that samples with a large dosage can be quickly mixed, and the problem that the samples with a small dosage are insufficient in dosage due to wall hanging can be avoided; the sampling needle 52 descends to different heights according to different types of test tubes and can just reach the bottom of the test tube 60, so that waste of samples to be tested is avoided, the sampling needle 52 or the test tube 60 is prevented from being damaged due to collision with the test tube 60, and smooth sample detection is ensured.

The sample analyzer 100 of the invention confirms the type of the test tube in advance between the uniform mixing and the sampling through the arrangement of the test tube detection component 20, has simple structure and accurate detection result on the whole, and ensures the smooth detection of the sample and the accuracy of the detection result; simultaneously, save the process of the categorised different test tubes of manual sorting, the automatic identification process of test tube need not to occupy the extra time, effectively simplifies the operation, promotes test speed. It should be understood that the types of test tubes, particularly the types of micro-tubes, used for the sample testing of the present invention may be one or more, and the number of the position sensors 26 of the test tube detecting assembly 60 may vary according to the types of test tubes, and is not limited to a specific embodiment. In addition, the elastic member 241 is provided for the automatic resetting of the telescopic member 243 and the buffering of the stress of the test tube 60, and the elastic member 241 may be omitted in some embodiments.

It should be noted that the description of the directions in the present invention is based on the placing direction of the sample analyzer during use, for example, the side facing the user is the front side, the side facing away from the user is the back side, the front-back direction is the Y direction of the drawing, the left-right direction is the X direction of the drawing, and the up-down direction is the Z direction of the drawing. It should be noted that the present invention is not limited to the above-mentioned embodiments, and other changes and modifications can be made by those skilled in the art according to the spirit of the present invention, and these changes and modifications made according to the spirit of the present invention should be included in the scope of the present invention as claimed.

Claims

1. The utility model provides a test tube detection subassembly, is applied to sample analysis appearance, its characterized in that, including the tube socket, set up movably in extensible member in the tube socket, correspond the position sensor that extensible member set up and with the controller that position sensor is connected, the tube socket is provided with the first holding chamber that is used for holding the pipe of waiting to test, the one end of extensible member stretch into in the first holding chamber in order to support the pipe of waiting to test of placing in the first holding chamber, the pipe of waiting to test of different grade type place make extensible member move down different height for the tube socket when in the first holding chamber, position sensor produces different signals according to the position after the extensible member moves down different height, the controller is according to the signal judgement place in the type of the pipe of waiting to test in the first holding chamber of position sensor.

2. The cuvette test assembly according to claim 1, further comprising an elastic member connected between the extensible member and the socket, wherein when the tube to be tested is placed in the first receiving cavity, the extensible member moves downward relative to the socket and compresses the elastic member, and when the tube to be tested leaves the first receiving cavity, the elastic member returns to deform and pushes the extensible member to move upward relative to the socket to return.

3. The test tube detecting assembly according to claim 2, wherein the tube seat is provided with a second receiving cavity for receiving the elastic member, the second receiving cavity is axially located below the first receiving cavity and spaced from the first receiving cavity, the tube seat is further provided with a through hole for communicating the first receiving cavity with the second receiving cavity, the diameter of the through hole is smaller than the diameter of the tube to be tested, and the telescopic member is movably inserted into the through hole.

4. A test tube detecting assembly as claimed in claim 1, wherein the tube base is provided with a positioning member for pressing down the tubes to be tested placed in the first receiving cavity, so that the tops of the different types of tubes to be tested are located at the same height, and the telescopic member is moved down by different heights relative to the tube base.

5. The cuvette detection assembly according to any one of claims 1 to 4, wherein said position sensor comprises a plurality of sensors, one of said sensors being adapted to sense an initial position of said bellows and the remaining sensors being adapted to sense a position of one of said tubes to be tested after said bellows is moved down relative to said socket in said first receiving chamber, respectively.

6. The cuvette detection assembly according to claim 5, wherein the plurality of sensors are sequentially arranged in an up-down direction in which a sensor for sensing an initial position of the expansion member is located uppermost.

7. The cuvette test tube detection assembly according to claim 6, wherein a blocking piece protrudes from the bottom of the telescopic member, when different types of cuvettes to be tested are placed in the first accommodating cavity, the telescopic member moves downwards relative to the tube seat by different heights, and the blocking piece extends into the detection grooves of different sensors.

8. The cuvette detection assembly of claim 5, wherein the position sensor is an opto-electronic or magnetic position sensor.

9. A sample analyzer, comprising the test tube detecting assembly, the mixing assembly, the sampling assembly and the sample detecting assembly according to any one of claims 1 to 8, wherein the controller controls the operation of the mixing assembly and the sampling assembly according to the type of the tube to be tested.

10. The sample analyzer of claim 9 wherein: the blending subassembly includes the tongs, the tongs has the removal route of X direction, Y direction and Z direction, test tube detection subassembly set up in sample analyzer's the host computer and be located on the removal route of the tongs of blending subassembly.