CN212284125U - Integrated laboratory system for hospital - Google Patents

Abstract

The utility model discloses an integrated laboratory system for hospital, which comprises a material arranging subsystem, a batch sample transmitting subsystem, a conveying subsystem, a batch sample loading subsystem, a sample centrifugal processing subsystem, a sample management subsystem, a track subsystem, a tester group, a sample post-processing subsystem and a background monitoring subsystem; the system comprises a material arranging subsystem, a batch sample transmitting subsystem, a conveying subsystem, a sample centrifugal processing subsystem, a sample management subsystem, a track subsystem, a test instrument group and a sample post-processing subsystem, wherein the material arranging subsystem acquires blood sampling samples of a hospital, is connected with the batch sample transmitting subsystem, is connected with the batch sample loading subsystem through the conveying subsystem, is connected with the sample centrifugal processing subsystem, is connected with the sample management subsystem, is connected with the track subsystem, and is connected with a background monitoring subsystem. The utility model discloses it is rational in infrastructure, realize integration and the seamless joint of hospital's detection, it is efficient.

Description

Integrated laboratory system for hospital

Technical Field

The utility model relates to an external diagnosis medical health clinical examination technical field, concretely relates to an integration laboratory system for hospital.

Background

The existing in vitro diagnosis and detection instrument is developed very quickly, the automation degree of the whole in vitro diagnosis and flow process is high, laboratory automation equipment such as independent intelligent blood collection and automation assembly lines exist, and a special person is needed to link the laboratory automation equipment. But there is no intelligent laboratory system for the whole hospital laboratory and the hospital needs to purchase from various suppliers. Nor does the product connect all laboratory instruments from blood sampling to reporting integrally, and there is much manual intervention, non-standard management and low efficiency.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an integration laboratory system for hospital solves the artifical unable automatic butt joint of automation laboratory assembly line of tradition, consuming time, omits, easily makes mistakes, biological safety scheduling problem, has improved sample (TAT time), patient information, has realized the accurate control of sample position, has stopped the biohazard of existence, and the management of inspection administrative or technical offices is more high-efficient standardization, has reduced more artificial intervention.

The utility model discloses a following technical scheme realizes:

an integrated laboratory system for a hospital comprises a material arranging subsystem, a batch sample launching subsystem, a conveying subsystem, a batch sample loading subsystem, a sample centrifugal processing subsystem, a sample managing subsystem, a track subsystem, a tester group, a sample post-processing subsystem and a background monitoring subsystem;

the system comprises a material arranging subsystem, a batch sample loading subsystem, a sample centrifugal processing subsystem, a sample management subsystem, a track subsystem, a test instrument group, a track subsystem and a sample post-processing subsystem, wherein the material arranging subsystem acquires blood sampling samples of ordinary outpatients and courtyards of hospitals, is connected with the batch sample emitting subsystem, the batch sample emitting subsystem is connected with the batch sample loading subsystem through a transmission subsystem, the batch sample loading subsystem is connected with the sample centrifugal processing subsystem, the sample centrifugal processing subsystem is connected with the sample management subsystem, the sample management subsystem is connected with the track subsystem, the track subsystem is connected with the test instrument group, the track subsystem is further connected with the sample post-processing subsystem, and.

The working principle is as follows: based on the unable automatic butt joint of artifical and automatic laboratory assembly line of tradition, consuming time, omit, easily make mistakes, biological safety scheduling problem, the utility model adopts the above-mentioned scheme to connect the wisdom laboratory system that forms through the intelligent blood sampling and laboratory intelligence assembly line, intelligent storage subsystem etc. of application sample reason material subsystem and conveying subsystem with the ordinary outpatient service of hospital, in-house department, emergency and operating room. The intelligent assembly line is a complex system formed by connecting intelligent sample loading of a batch sample loading subsystem, centrifugal processing of a sample centrifugal processing subsystem, a track sampling interface, an intelligent pipe frame sample inlet interface, a sample post-processing subsystem, a sample warehousing subsystem, an automatic waste packaging processing subsystem and an automatic quality control self-checking subsystem through an intelligent track and an intelligent system.

The utility model solves the problems that the traditional manual and automatic laboratory assembly line can not automatically butt joint, consumes time, is omitted, is easy to make mistakes, is biologically safe and the like; the system improves the time of the specimen (TAT) and the information of the patient, realizes the accurate control of the position of the specimen, avoids the existing biological danger, has more efficient and standardized management of the inspection department, and reduces more manual intervention. The utility model discloses the system is applicable to external diagnosis medical treatment health clinical examination technical field, is fit for using widely.

Preferably, the system further comprises a client terminal, wherein the client terminal is connected with the background monitoring subsystem; the client terminal adopts a computer terminal or a mobile phone terminal.

Preferably, the system further comprises a single sample emission subsystem, wherein the single sample emission subsystem acquires operating room and emergency blood sampling samples, the single sample emission subsystem is connected with the first long-distance conveying subsystem, and the first long-distance conveying subsystem is connected with the batch sample loading subsystem.

Preferably, the device further comprises a vacuum blood collection tube deceleration receiving device, the vacuum blood collection tube deceleration receiving device is arranged between the conveying subsystem and the batch sample loading subsystem, one end of the vacuum blood collection tube deceleration receiving device is connected with the conveying subsystem, and the other end of the vacuum blood collection tube deceleration receiving device is connected with the batch sample loading subsystem;

the vacuum blood collection tube speed reduction receiving device comprises a transmission pipeline, wherein a sample introduction detector A is arranged at an inlet of the transmission pipeline, a sample introduction detector B, an exhaust fan, an air suction fan, a pipeline fan, a non-return device and a back suction detector are sequentially arranged in the middle of the transmission pipeline from top to bottom, and an outlet detector is arranged at an outlet of the transmission pipeline; the inlet of the transmission pipeline is connected with the transmission subsystem, the outlet of the transmission pipeline is connected with the batch sample loading subsystem, and the exhaust fan and the suction fan are both connected with the pipeline fan;

after the vacuum blood collection tube is conveyed from the conveying subsystem, the vacuum blood collection tube enters the vacuum blood collection tube speed reduction receiving device through the inlet of the conveying pipeline, and the suction fan is used for generating negative pressure, so that the vacuum blood collection tube running at high speed in the conveying pipeline is uniformly decelerated.

Preferably, the delivery subsystem comprises a second long-distance delivery subsystem and a short-distance delivery subsystem, the material arranging subsystem acquires blood sampling samples of a common outpatient service of a hospital, the material arranging subsystem is connected with the batch sample emission subsystem, and the batch sample emission subsystem is connected with the batch sample loading subsystem through the short-distance delivery subsystem;

the material arranging subsystem acquires blood sampling samples of a courtyard, is connected with the batch sample transmitting subsystem, and is connected with the batch sample loading subsystem through a second long-distance conveying subsystem.

Preferably, the test instrument set comprises a first test instrument and a second test instrument, the first test instrument is connected with the track subsystem through a pipe rack type instrument interface subsystem, and the second test instrument is connected with the track subsystem through an online sampling instrument interface subsystem.

Preferably, the system also comprises an automatic quality control self-checking subsystem, an automatic waste packaging and processing subsystem and a sample warehousing subsystem, wherein the automatic quality control self-checking subsystem, the automatic waste packaging and processing subsystem and the sample warehousing subsystem are all connected with the background monitoring subsystem.

Compared with the prior art, the utility model, following advantage and beneficial effect have:

1. the utility model discloses an intelligent blood sampling and the wisdom laboratory system that forms such as laboratory intelligence assembly line, intelligent storage subsystem of the ordinary outpatient service of hospital, the academy of residence, emergency and operating room are connected to application sample reason material subsystem and conveying subsystem. The intelligent assembly line is a complex system formed by connecting intelligent sample loading of a batch sample loading subsystem, centrifugal processing of a sample centrifugal processing subsystem, a track sampling interface, an intelligent pipe frame sample inlet interface, a sample post-processing subsystem, a sample warehousing subsystem, an automatic waste packaging processing subsystem and an automatic quality control self-checking subsystem through an intelligent track and an intelligent system.

2. The utility model solves the problems that the traditional manual and automatic laboratory assembly line can not automatically butt joint, consumes time, is omitted, is easy to make mistakes, is biologically safe and the like; the system improves the time of the specimen (TAT) and the information of the patient, realizes the accurate control of the position of the specimen, avoids the existing biological danger, has more efficient and standardized management of the inspection department, and reduces more manual intervention. The utility model discloses the system is applicable to external diagnosis medical treatment health clinical examination technical field, is fit for using widely.

3. The utility model connects all departments to be inspected with the clinical laboratory to form a closed loop, realizes the integration and seamless connection of hospital detection, has high efficiency, avoids the loss of samples, the stagnation of samples and the preferential rapid treatment of emergency samples; manual intervention is reduced, the whole process is automatically controlled, and the infection risk is reduced; realize the accurate control of sample position, stopped the biohazard that exists.

Drawings

The accompanying drawings, which are included to provide a further understanding of the embodiments of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the principles of the invention. In the drawings:

fig. 1 is a schematic structural diagram of an integrated laboratory system for hospitals according to the present invention.

Fig. 2 is the structure schematic diagram of the vacuum blood collection tube deceleration receiving device of the present invention.

Fig. 3 is a schematic diagram of an integrated laboratory system for hospitals according to the present invention.

Reference numbers and corresponding part names in the drawings:

1-a material arranging subsystem, 2-a batch sample launching subsystem, 3-a batch sample loading subsystem, 4-a sample centrifugal processing subsystem, 5-a sample management subsystem, 6-a track subsystem, 7-a tester group, 70-a first tester, 71-a second tester, 8-a sample post-processing subsystem, 9-a conveying subsystem, 90-a first long-distance conveying subsystem, 91-a second long-distance conveying subsystem, 92-a short-distance conveying subsystem, 10-a background monitoring subsystem, 11-a client terminal, 12-an automatic quality control self-checking subsystem, 13-an automatic waste packing processing subsystem, 14-a sample storage subsystem, 15-a single sample launching subsystem, and 16-a vacuum blood collection tube speed reduction receiving device, 20-sample introduction detector A, 21-transmission pipeline, 22-sample introduction detector B, 23-exhaust fan, 24-suction fan, 25-pipeline fan, 26-non-return device, 27-back suction detector, 28-outlet detector and 29-vacuum blood collection tube.

Detailed Description

To make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to the following examples and drawings, and the exemplary embodiments and descriptions thereof of the present invention are only used for explaining the present invention, and are not intended as limitations of the present invention.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. However, it will be apparent to one of ordinary skill in the art that: it is not necessary to employ these specific details to practice the present invention. In other instances, well-known structures, circuits, materials, or methods have not been described in detail so as not to obscure the present invention.

Throughout the specification, reference to "one embodiment," "an embodiment," "one example," or "an example" means: the particular features, structures, or characteristics described in connection with the embodiment or example are included in at least one embodiment of the invention. Thus, the appearances of the phrases "one embodiment," "an embodiment," "one example" or "an example" in various places throughout this specification are not necessarily all referring to the same embodiment or example. Furthermore, the particular features, structures, or characteristics may be combined in any suitable combination and/or sub-combination in one or more embodiments or examples. Further, those of ordinary skill in the art will appreciate that the illustrations provided herein are for illustrative purposes and are not necessarily drawn to scale. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

In the description of the present invention, the terms "front", "back", "left", "right", "up", "down", "vertical", "horizontal", "high", "low", "inner", "outer", etc. indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the scope of the present invention.

Example 1

As shown in fig. 1 to 3, the utility model relates to an integrated laboratory system for hospital, which comprises a material arranging subsystem 1, a batch sample launching subsystem 2, a conveying subsystem 9, a batch sample loading subsystem 3, a sample centrifugal processing subsystem 4, a sample management subsystem 5, a track subsystem 6, a test instrument group 7, a sample post-processing subsystem 8 and a background monitoring subsystem 10;

the material arranging subsystem 1 obtains blood sampling samples of a common outpatient service and a courtyard of a hospital, the material arranging subsystem 1 is connected with the batch sample transmitting subsystem 2, the batch sample transmitting subsystem 2 is connected with the batch sample loading subsystem 3 through a transmission subsystem 9, the batch sample loading subsystem 3 is connected with the sample centrifugal processing subsystem 4, the sample centrifugal processing subsystem 4 is connected with the sample management subsystem 5, the sample management subsystem 5 is connected with the track subsystem 6, the track subsystem 6 is connected with the tester group 7, the track subsystem 6 is further connected with the sample post-processing subsystem 8, and the sample post-processing subsystem 8 is connected with the background monitoring subsystem 10.

The system also comprises an automatic quality control self-checking subsystem 12, an automatic waste packaging processing subsystem 13 and a sample warehousing subsystem 14, wherein the automatic quality control self-checking subsystem 12, the automatic waste packaging processing subsystem 13 and the sample warehousing subsystem 14 are all connected with the background monitoring subsystem 10.

The system further comprises a client terminal 11, wherein the client terminal 11 is connected with the background monitoring subsystem 10; the client terminal 11 is a computer terminal or a mobile phone terminal.

As a further preferable scheme, the system also comprises a single sample emission subsystem 15, wherein the single sample emission subsystem 15 acquires operating room and emergency blood sampling samples, the single sample emission subsystem 15 is connected with a first long-distance conveying subsystem 90, and the first long-distance conveying subsystem 90 is connected with the batch sample loading subsystem 3.

As a further preferable scheme, the conveying subsystem 9 includes a second long-distance conveying subsystem 91 and a short-distance conveying subsystem 92, the material arranging subsystem 1 obtains the blood sampling samples from the general outpatient service of the hospital, the material arranging subsystem 1 is connected with the batch sample emission subsystem 2, and the batch sample emission subsystem 2 is connected with the batch sample loading subsystem 3 through the short-distance conveying subsystem 92;

the material arranging subsystem 1 is used for obtaining blood sampling samples of a courtyard, the material arranging subsystem 1 is connected with the batch sample emission subsystem 2, and the batch sample emission subsystem 2 is connected with the batch sample loading subsystem 3 through the second long-distance conveying subsystem 91.

As a further preferred solution, the test instrument set 7 includes a first test instrument 70 and a second test instrument 71, the first test instrument 70 is connected to the track subsystem 6 through a rack-type instrument interface subsystem, and the second test instrument 71 is connected to the track subsystem 6 through an online sampling instrument interface subsystem.

As shown in fig. 3, fig. 3 is a schematic layout diagram of an integrated laboratory system for hospitals according to the present invention. As can be seen from fig. 3, the laboratory system includes a material handling subsystem 1, a batch sample launching subsystem 2, a conveying subsystem 9, a batch sample loading subsystem 3, a sample centrifugation processing subsystem 4, a track subsystem 6, a testing instrument set 7, a first testing instrument 70, a second testing instrument 71, and a sample post-processing subsystem 8, wherein the sample processed by the sample post-processing subsystem 8 is placed in an automatic waste packaging processing subsystem 13 (such as an automatic discarding unit) or a sample warehousing subsystem 14 (such as a refrigerator); specifically, firstly, (1) blood sampling samples of a common outpatient service of a hospital are transmitted to the material arranging subsystem 1, are subjected to material arranging treatment by the material arranging subsystem 1 and then transmitted to the batch sample emission subsystem 2, and then are transmitted to the batch sample loading subsystem 3 by the short-distance transmission subsystem 92; (2) blood sampling samples of the courtyard are transmitted to the material arranging subsystem 1, are arranged and processed by the material arranging subsystem 1 and then are transmitted to the batch sample emission subsystem 2, and then are transmitted to the batch sample loading subsystem 3 through the second long-distance transmission subsystem 91; (3) the operating room and emergency blood samples are passed to the single sample emitter subsystem 15, and the single sample emitter subsystem 15 is transferred to the bulk sample loading subsystem 3 via the first remote transport subsystem 90. Of course, the above-mentioned (1), (2) and (3) may be separately performed. Secondly, the batch sample loading subsystem 3 performs batch loading processing, the batch sample loading subsystem 3 can be transmitted to the sample centrifugal processing subsystem 4 (or the sample management subsystem 5) and then transmitted to the tester group 7 through the rail subsystem 6 for testing, or the batch sample post-processing subsystem 8 performs subsequent processing, and the sample processed by the sample post-processing subsystem 8 is placed into an automatic waste packaging processing subsystem 13 (such as an automatic discarding unit) or a sample storage subsystem 14 (such as a refrigerator) and the like.

The working principle is as follows: based on the unable automatic butt joint of artifical and automatic laboratory assembly line of tradition, consuming time, omit, easily make mistakes, biological safety scheduling problem, the utility model adopts the above-mentioned scheme to connect the wisdom laboratory system that forms through the intelligent blood sampling and laboratory intelligence assembly line, intelligent storage subsystem etc. of application sample reason material subsystem and conveying subsystem with the ordinary outpatient service of hospital, in-house department, emergency and operating room. The intelligent assembly line is a complex system formed by connecting intelligent sample loading of a batch sample loading subsystem, centrifugal processing of a sample centrifugal processing subsystem, a track sampling interface, an intelligent pipe frame sample inlet interface, a sample post-processing subsystem, a sample warehousing subsystem, an automatic waste packaging processing subsystem and an automatic quality control self-checking subsystem through an intelligent track and an intelligent system.

The utility model solves the problems that the traditional manual and automatic laboratory assembly line can not automatically butt joint, consumes time, is omitted, is easy to make mistakes, is biologically safe and the like; the system improves the time of the specimen (TAT) and the information of the patient, realizes the accurate control of the position of the specimen, avoids the existing biological danger, has more efficient and standardized management of the inspection department, and reduces more manual intervention. The utility model discloses the system is applicable to external diagnosis medical treatment health clinical examination technical field, is fit for using widely.

The utility model connects all departments to be inspected with the clinical laboratory to form a closed loop, realizes the integration and seamless connection of hospital detection, has high efficiency, avoids the loss of samples, the stagnation of samples and the preferential rapid treatment of emergency samples; manual intervention is reduced, the whole process is automatically controlled, and the infection risk is reduced; realize the accurate control of sample position, stopped the biohazard that exists.

Example 2

As shown in fig. 1 to 3, the difference between this embodiment and embodiment 1 is that fig. 2 is a schematic structural diagram of a vacuum blood collection tube deceleration receiving device of the present invention, the present invention further includes a vacuum blood collection tube deceleration receiving device 16, the vacuum blood collection tube deceleration receiving device 16 is disposed between the conveying subsystem 9 and the batch sample loading subsystem 3, one end of the vacuum blood collection tube deceleration receiving device 16 is connected to the conveying subsystem 9, and the other end is connected to the batch sample loading subsystem 3;

the vacuum blood collection tube deceleration receiving device 16 comprises a transmission pipeline 21, an inlet of the transmission pipeline 21 is provided with a sample injection detector A20, the middle part of the transmission pipeline 21 is sequentially provided with a sample injection detector B22, an exhaust fan 23, an air suction fan 24, a pipeline fan 25, a check device 26 and a suck-back detector 27 from top to bottom, and an outlet of the transmission pipeline 21 is provided with an outlet detector 28; the inlet of the transmission pipeline 21 is connected with the transmission subsystem 9, the outlet of the transmission pipeline 21 is connected with the batch sample loading subsystem 3, and the exhaust fan 23 and the suction fan 24 are both connected with the pipeline fan 25;

after the vacuum blood collection tube 29 is transferred from the transfer subsystem 9, it enters the vacuum blood collection tube deceleration receiving device through the inlet of the transfer line 21, and the suction fan 24 generates negative pressure to uniformly decelerate the vacuum blood collection tube 29 running at high speed in the transfer line 21.

The working principle is as follows: at present, the sample deceleration of the vacuum blood collection tube mostly adopts physical buffer type deceleration or reverse ventilation deceleration from a sample outlet. However, the two deceleration modes have different degrees, the physical buffer mostly adopts the spring piece or the buffer pad and other modes to realize deceleration, the deceleration mode has short action distance and time, the blood sampling tube is subjected to large instantaneous impulse, and irreversible influence such as hemolysis and other defects are easily caused on the sample in the tube; and the reverse ventilation mode of sample export often is limited by the laboratory condition, and most laboratories do not possess the air supply, and dispose the air compressor machine alone in the laboratory and put forward new demand to the place again, and the great noise of air compressor machine often is not accepted.

Therefore, the present invention considers that the vacuum blood collection tube 29 coming from the conveying subsystem 9 is moving at the high speed, and the vacuum blood collection tube 29 moving slowly and uniformly is needed on the batch sample loading subsystem 3; therefore, the utility model discloses set up vacuum test tube speed reduction receiving arrangement 16 between conveying subsystem 9 with batch sample subsystem 3 that samples, vacuum test tube speed reduction receiving arrangement 16 includes transmission line 21, the entry of transmission line 21 is equipped with appearance detector A20, transmission line 21 middle part is equipped with appearance detector B22 from the top down in proper order, exhaust fan 23, aspiration fan 24, pipeline fan 25, non return device 26, resorption detector 27, can effectively solve the problem such as the hemolysis that vacuum test tube produced because of receiving too big impulsive force; the fan is small in size, flexible in arrangement and not limited by an installation site.

The pipeline length between the outlet of the air suction fan 24 and the outlet of the transmission pipeline 21 is the deceleration distance, and on the path, the wind resistance of the vacuum blood collection tube 29 is constant, so that the vacuum blood collection tube 29 can be uniformly decelerated, and the problem that the vacuum blood collection tube 29 is subjected to overlarge impulse force is solved. In addition, through the sample detection, can measure the transmission speed of vacuum test tube, according to the adjustment fan (exhaust fan 23, suction fan 24) rotational speed of vacuum test tube speed, make the vacuum test tube 29 of different speeds all can reach the same deceleration effect. The compressed air in the pipeline has certain peculiar smell due to the influence of the pipeline material, the outdoor environment and other factors, the exhaust fan 23 can pump out the gas, and the pipeline fan 25 discharges the gas outdoors, so that the laboratory pollution is avoided.

When in implementation: the vacuum blood collection tube 29 enters the device through the transmission pipeline 21, and the exhaust fan 23 is in a long-open state to remove the peculiar smell gas in the pipeline; vacuum test tube 29 successively detects A20 through advancing the appearance, advances the appearance and detects B22, and sample transmission speed is calculated to this section distance, and the fan 24 that breathes in begins work when the sample reaches to advance the appearance and detect B22, and according to vacuum test tube 29 speed difference, the fan 24 that breathes in can inhale with corresponding settlement speed, produces the negative pressure in the messenger speed reduction pipeline, and vacuum test tube 29 evenly slows down under the windage effect, when vacuum test tube 29 speed drops to 0, can be by suck-back upward movement. At this time, the non-return device 26 starts to operate, and prevents the vacuum blood collection tube 29 from moving upward, and thus suspends to the position shown in the figure (the non-return device 26 can ensure that the vacuum blood collection tube 29 passes through in one direction), at this time, the suck-back detector 27 detects that the vacuum blood collection tube 29 exists, the suction fan 24 stops operating, the vacuum blood collection tube 29 is influenced by gravity and falls freely, and whether the vacuum blood collection tube 29 is separated from the transmission pipeline 21 can be determined by the outlet detector 28. The air drawn by the exhaust fan 23 and the suction fan 24 is discharged to the outside through the duct fan 25.

The vacuum blood collection tube deceleration receiving device 16 of the utility model has simple and reasonable structure, can realize uniform deceleration of the vacuum blood collection tube, and avoids sample hemolysis; peculiar smell gas is discharged, and the pollution of a laboratory is eliminated; the device is suitable for blood sampling tubes with different transmission speeds; and the construction is simple, and the modification cost is low.

The above-mentioned embodiments, further detailed description of the objects, technical solutions and advantages of the present invention, it should be understood that the above description is only the embodiments of the present invention, and is not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (8)

1. An integrated laboratory system for hospitals is characterized by comprising a material arranging subsystem (1), a batch sample transmitting subsystem (2), a conveying subsystem (9), a batch sample loading subsystem (3), a sample centrifugal processing subsystem (4), a track subsystem (6), a test instrument group (7), a sample post-processing subsystem (8) and a background monitoring subsystem (10);

the system comprises a material arranging subsystem (1), a batch sample transmitting subsystem (2), a conveying subsystem (9), a batch sample loading subsystem (3), a sample centrifugal processing subsystem (4), a track subsystem (6) and a test instrument set (7), wherein the material arranging subsystem (1) acquires blood sampling samples of ordinary outpatients and courtyards of hospitals, the material arranging subsystem (1) is connected with the batch sample transmitting subsystem (2), the batch sample transmitting subsystem (2) is connected with the batch sample loading subsystem (3) through the conveying subsystem (9), the batch sample loading subsystem (3) is connected with the sample centrifugal processing subsystem (4), the sample centrifugal processing subsystem (4) is connected with the track subsystem (6), the track subsystem (6) is further connected with the sample post-processing subsystem (8), and the sample post-.

2. An integrated laboratory system for hospitals according to claim 1, characterized by further comprising a client terminal (11), wherein said client terminal (11) is connected with said background monitoring subsystem (10); the client terminal (11) adopts a computer terminal or a mobile phone terminal.

3. An integrated laboratory system for hospitals according to claim 1, characterized by further comprising a single sample launching subsystem (15), said single sample launching subsystem (15) taking operating room and emergency blood samples, said single sample launching subsystem (15) being connected to a first teletransmission subsystem (90), said first teletransmission subsystem (90) being connected to said batch sample loading subsystem (3).

4. The integrated laboratory system for hospitals according to claim 1, further comprising a vacuum blood collection tube deceleration receiving device (16), wherein the vacuum blood collection tube deceleration receiving device (16) is arranged between the conveying subsystem (9) and the batch sample loading subsystem (3), one end of the vacuum blood collection tube deceleration receiving device (16) is connected with the conveying subsystem (9), and the other end is connected with the batch sample loading subsystem (3);

the vacuum blood collection tube deceleration receiving device (16) comprises a transmission pipeline (21), a sample injection detector A (20) is arranged at an inlet of the transmission pipeline (21), a sample injection detector B (22), an exhaust fan (23), an air suction fan (24), a pipeline fan (25), a non-return device (26) and a suck-back detector (27) are sequentially arranged in the middle of the transmission pipeline (21) from top to bottom, and an outlet detector (28) is arranged at an outlet of the transmission pipeline (21); the inlet of the transmission pipeline (21) is connected with the transmission subsystem (9), the outlet of the transmission pipeline (21) is connected with the batch sample loading subsystem (3), and the exhaust fan (23) and the suction fan (24) are both connected with the pipeline fan (25);

after the vacuum blood collection tube is conveyed from the conveying subsystem (9), the vacuum blood collection tube enters the vacuum blood collection tube speed reduction receiving device through the inlet of the conveying pipeline (21), and the vacuum blood collection tube running at high speed in the conveying pipeline (21) is uniformly decelerated by utilizing the negative pressure generated by the suction fan (24).

5. An integrated laboratory system for hospitals according to claim 1, characterized in that said transport subsystem (9) comprises a second long-distance transport subsystem (91) and a short-distance transport subsystem (92), said material arranging subsystem (1) obtains the blood sampling samples of the hospital general outpatient service, said material arranging subsystem (1) is connected with said batch sample emission subsystem (2), said batch sample emission subsystem (2) is connected with said batch sample loading subsystem (3) through the short-distance transport subsystem (92);

the material arranging subsystem (1) is used for obtaining blood sampling samples of the courtyard, the material arranging subsystem (1) is connected with the batch sample transmitting subsystem (2), and the batch sample transmitting subsystem (2) is connected with the batch sample loading subsystem (3) through the second long-distance conveying subsystem (91).

6. An integrated laboratory system for hospitals according to claim 1, characterized in that said set of test instruments (7) comprises a first test instrument (70) and a second test instrument (71), said first test instrument (70) being connected to said rail subsystem (6) through a rack-and-tube instrument interface subsystem, said second test instrument (71) being connected to said rail subsystem (6) through an online sampling instrument interface subsystem.

7. The integrated laboratory system for hospitals according to claim 1, further comprising an automatic quality control self-testing subsystem (12), an automatic waste packaging and processing subsystem (13), and a sample storage subsystem (14), wherein the automatic quality control self-testing subsystem (12), the automatic waste packaging and processing subsystem (13), and the sample storage subsystem (14) are all connected to the background monitoring subsystem (10).

8. An integrated laboratory system for hospitals according to claim 1, characterized by further comprising a sample management subsystem (5), wherein said sample management subsystem (5) is connected with a batch sample loading subsystem (3), said sample management subsystem (5) is also connected with a sample centrifugation processing subsystem (4).

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