CN114165981A

CN114165981A - Active sample transport device

Info

Publication number: CN114165981A
Application number: CN202010951151.0A
Authority: CN
Inventors: 秘心吾; 李明城; 许任胜
Original assignee: Scl Biotech Ltd
Current assignee: DRsignal Biotechnology Co Ltd
Priority date: 2020-09-11
Filing date: 2020-09-11
Publication date: 2022-03-11

Abstract

The invention relates to a living sample conveying device which is used for accommodating a plurality of containers for loading living samples and comprises a frame, a rotating bracket and a storage assembly. The rotating bracket can rotate along a first pivot shaft direction relative to the frame, and the storage group can rotate along a second pivot shaft direction relative to the rotating bracket. The first pivot axis direction is not parallel to the second pivot axis direction. The gravity center of the storage component is lower than the pivot point of the rotating bracket and the pivot point of the storage component. Therefore, the invention can ensure that when the sample is transported, even if the frame of the active sample transporting device tilts or overturns due to shaking or vibration in the way, the rotating bracket and the storage assembly can automatically rotate to the vertical direction due to gravity, thereby ensuring that the active samples can be soaked in the preservation liquid during the transportation process, and reducing the possibility that each active sample is attached to the tube wall to influence the activity.

Description

Active sample transport device

Technical Field

The present invention relates to a container for storing an active sample, and more particularly, to a transport apparatus capable of maintaining the activity of a sample when the sample is transported after being stored in the container.

Background

Because the active time of the active sample is limited, the active sample must be transported to the destination within a limited time after being obtained to preserve the activity of the sample for further treatment or use, the active sample must meet the human cell tissue quality operating standard (GTP) as much as possible during the transportation process, and the requirements of the human cell tissue quality operating standard (GTP) are 1, avoiding cross contamination between the personnel and the active sample during the transportation process, 2, tracking the position of the active sample during the transportation process, 3, recording the instant environment of the active sample during the transportation process, and 4, ensuring the stable and safe environment of the active sample during the transportation process.

In the prior art, the active sample is usually sealed in a test tube or a container, and then placed in a device with simple heat preservation together with the test tube or the container for transportation by a common carrier or vehicle. Since the active sample is usually put in a test tube or a container together with the preservation liquid, the active sample may be shaken or shaken during the transportation process, and the active sample may have high viscosity and thus may be easily attached to the inner wall surface of the test tube, so that the active sample may not be used because the active sample is not always immersed in the preservation liquid and loses activity. In addition, under long-term transportation, the active sample may deteriorate due to the unstable transportation environment, which also makes the sample unable to be further disposed. Therefore, the prior art method for transporting active samples cannot provide an efficient, safe and stable transport environment to ensure the activity required by the good operating standard (GTP) of human cell tissues.

In view of the above, a better solution is proposed, which is a problem to be solved in the art.

Disclosure of Invention

The main object of the present invention is to provide a device for transporting a living specimen, which can accommodate a plurality of containers containing a living specimen and can rotate with the environment, thereby keeping the loaded containers upright and vertical, keeping the living specimen activity during transportation after the living specimen is accommodated, and monitoring and recording the person, things, places and objects during transportation in real time, and transporting the living specimen in an environment conforming to the GTP standard.

To achieve the above object, the present invention provides an active specimen transport device comprising:

a frame;

at least one rotating bracket which is arranged on the frame and can rotate along a first pivot shaft direction relative to the frame; and

at least one storage component, which is arranged on the at least one rotating bracket and can rotate along a second pivot axis direction relative to the at least one rotating bracket; the first pivot axis direction is not parallel to the second pivot axis direction; each of the at least one storage element has:

a container part pivoted to the at least one rotating bracket;

a plurality of slots located in the receiving portion; each slot is used for accommodating one container; and

the cover body part is detachably arranged in the accommodating part and shields the slot;

wherein, the gravity center position of each storage component is lower than the pivot point of each corresponding rotating bracket on the frame and the pivot point of each corresponding rotating bracket of the storage component.

Therefore, the present invention has an advantage that the rotation bracket and the storage assembly are rotatable, the rotation directions of the rotation bracket and the storage assembly are not parallel, and the center of gravity of the storage assembly is lower than the pivot point, so that even if the frame of the active specimen transport device tilts or overturns due to shaking or vibration during the transportation of the container by the active specimen transport device of the present invention, the rotation bracket and the storage assembly can rotate to the vertical direction by gravity, thereby reducing the chance that each active specimen leaves the preservation solution and adheres to the tube wall.

In the active sample transport apparatus, each of the at least one storage element has:

a communicating space formed between the accommodating part and the cover body part and communicated with the slot; and

at least one ultraviolet light source fixed in the communicating space.

and the refrigerating chip is used for keeping the accommodating part and the slot at constant temperature.

In the active sample transport apparatus, each of the at least one storage device has a GPS signal receiving module.

In the active-sample transport apparatus, each of the at least one storage device has a touch panel.

In the active sample transport apparatus, each of the at least one storage assembly has a plurality of rf induction modules respectively disposed in the slots for identifying information of the containers.

The active sample transport device further includes at least one rfid tag respectively disposed on the at least one storage element.

The active sample transport device further includes a radio frequency tag disposed on the frame.

In the active-sample transport device, each of the at least one storage element has a battery unit.

The active sample transport device further includes a power supply module, wherein the power supply module is fixedly disposed on the frame and electrically connected to the battery unit of each of the at least one storage assembly.

The active sample transport device further comprises a housing having a plurality of wheels and a pull rod; the frame, the at least one rotating bracket and the at least one storage component are arranged in the shell.

Drawings

Fig. 1 is a perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic side view of the first embodiment of the present invention.

Fig. 3 is a front partial cross-sectional schematic view of a first embodiment of the present invention.

Fig. 4 is a schematic cross-sectional view of a storage assembly according to a first embodiment of the present invention.

Fig. 5 is a schematic top view of the first embodiment of the present invention.

Fig. 6 is a perspective view of a second embodiment of the present invention.

Detailed Description

Please refer to fig. 1 to fig. 3. The invention provides a living sample conveying device, which is used for accommodating a plurality of containers A. The first embodiment of the active sample transport apparatus has a frame 10, at least one rotating rack 20, and at least one storage assembly 30, and optionally has a temperature control module 11, at least one radio frequency tag 12, and/or a power supply module 13. In the present embodiment, there are two rotating frames 20 and two storage assemblies 30, but the number is not limited thereto. The frame 10 may be provided with an ultraviolet light source 14 and/or a GPS signal receiving module 15.

Each rotating bracket 20 is disposed on the frame 10 and can rotate along a first pivot axis direction X relative to the frame 10. Specifically, each rotating bracket 20 has an annular frame 21 and two protrusions 22, and the two protrusions 22 are respectively disposed on the annular frame 21 and located at two opposite ends of the annular frame 21. Each protrusion 22 protrudes upward from the annular frame 21 and is pivotally mounted on the frame 10. In other words, the height position of the ring frame 21 is lower than the pivot point (which is the first pivot point 100) of the rotating bracket 20 on the frame 10.

Each storage assembly 30 is disposed on a rotating bracket 20 and can rotate along a second pivot axis direction Y relative to the rotating bracket 20. Specifically, the storage component 30 is pivoted on the ring frame 21, so that the pivot point (which is the second pivot point 210) of the storage component 30 on the ring frame 21 is also lower than the first pivot point 100 of the rotating bracket 20 on the frame 10. The first pivot axis direction X is not parallel to the second pivot axis direction Y, and is perpendicular in the embodiment. The center of gravity of the storage element 30 is lower than the first pivot point 100 of the rotating bracket 20 on the frame 10 and lower than the second pivot point 210 of the storage element 30 on the ring frame 21. By the above-described placement of the center of gravity and pivot point 100/210, it is ensured that the storage assemblies 30 remain vertically oriented regardless of the tilt or tilt of the frame 10.

Please refer to fig. 1, fig. 4, and fig. 5. Each storage assembly 30 has a container 31, a cover 32, and a plurality of slots 33, and optionally has a communication space 300, at least one uv light source 34, a refrigeration chip 35, a GPS signal receiving module 36, a touch panel 37, a plurality of rf sensing modules 38, and/or a battery unit 39.

The accommodating portion 31 is pivotally disposed on the annular frame 21 of the rotating bracket 20, and the cover portion 32 is detachably disposed on the accommodating portion 31. The slots 33 are located in the accommodating portion 31, and each slot 33 is used for accommodating one container a. When the cover is disposed on the accommodating portion 31, the cover can shield the slot 33, thereby blocking the external pollution source. Further, when the cover is disposed on the accommodating portion 31, the communication space 300 is formed between the accommodating portion 31 and the cover portion 32. The communicating space 300 is communicated with the slot 33, and the ultraviolet light source 34 is fixedly arranged in the communicating space 300, so that when the container A is arranged in the slot 33, the ultraviolet light source 34 can irradiate the container A to sterilize the container A, and the influence of a pollution source on an active sample is reduced.

The temperature control module 11 may be disposed on the frame 10, and the refrigeration chip 35 may be disposed at the bottom of the accommodating portion 31, and the temperature control module 11 is in signal connection with the refrigeration chip 35. Therefore, the refrigeration chip 35 can be used to cool the accommodating portion 31, the slot 33, and the container a in the slot 33, and the temperature control module 11 controls the operation power of the refrigeration chip 35. In other embodiments, each refrigeration chip 35 can operate independently and can not be controlled by the temperature control module 11; in other words, the temperature control module 11 may not be present in some embodiments.

A GPS signal receiving module 36 may be disposed within the lid portion 32 and configured to receive GPS signals, thereby enabling monitoring of the dynamics of the container a.

The touch panel 37 may be disposed on the upper side of the lid portion 32, so that the person who samples the specimen, the person who carries the specimen, or the person who tests the specimen can input or read the information related to the container a through the touch panel 37.

A plurality of rf induction modules 38 may be respectively disposed in the slots 33. Since each container a is provided with a rfid tag B, the rfid module 38 can identify the information of the container a through the rfid tag B on each container a.

On the other hand, the radio frequency tag 12 may be provided on each storage unit 30 and/or the frame 10, thereby enabling identification of information of the active-specimen transport device and the storage unit 30.

The power supply module 13 may be fixed on the frame 10, and an electric storage unit (not shown) is disposed therein. The power supply module 13 may be electrically connected to an external power source to charge the power storage unit. The battery unit 39 may be disposed at the bottom of the accommodating portion 31. In the present embodiment, the battery unit 39 is located below the cooling chip 35. The battery unit 39 is used for supplying power to the ultraviolet light source 34, the refrigeration chip 35, the GPS signal receiving module 36, the touch panel 37, and the radio frequency induction module 38. The power supply module 13 is electrically connected to the battery unit 39, and can charge the battery unit 39 at any time, for example, the battery unit 39 can be charged during transportation. In the present embodiment, the power supply module 13 may be connected to the storage element 30 through a wire 130, for example, the wire 130 may be coupled to the first pivot point 100 of the rotating bracket 20 on the frame 10 or the second pivot point 210 of the storage element 30 on the ring frame 21.

Please refer to fig. 6. In the second embodiment, the active-sample transport apparatus has a housing 40 in addition to the frame 10, the rotating stand 20, and the storage assembly 30, and the frame 10, the rotating stand 20, and the storage assembly 30 are all disposed in the housing 40. The housing 40 has a housing 41, a cover 42, a plurality of wheels 43, and a pull rod 44, but not limited thereto. The housing 41 and the cover 42 together form an inner space, and the frame 10, the rotating bracket 20, and the storage assembly 30 are disposed in the inner space. In other embodiments, the housing 41 may have at least one partition to separate the plurality of storage elements 30, and the number of covers 42 in this embodiment may be equal to the number of storage elements 30. Further, the cover 42 is located on the lateral side of the housing 40 in this embodiment. The wheel 43 and the pull rod 44 are respectively disposed on the housing 41, and the pull rod 44 can be retracted into the housing 41.

In addition, the housing 40 may further be provided with an ultraviolet light source, a GPS signal receiving module, a touch panel, and a radio frequency tag, so as to achieve the functions of sterilization, positioning, operation, and identification. Specifically, the ultraviolet light source may be disposed inside the housing 40, and the GPS signal receiving module, the touch panel, and the rf tag may be disposed on the cover 42.

With the above configuration, even if the frame 10 of the active specimen transport apparatus tilts or turns over due to vibration or vibration during transportation of the containers a by the active specimen transport apparatus of the present invention, the rotational bracket 20 and the storage unit 30 can rotate to the vertical direction by gravity, thereby reducing the chance that the active specimen in each container a adheres to the tube wall. In other words, the active sample transport apparatus of the present invention can transport active samples in a stable and safe manner, and can efficiently manage and transport active samples in large quantities, so that each active sample can be effectively disposed of while maintaining its activity.

On the other hand, by sterilizing the container a with the ultraviolet light source 34 and maintaining the container a at a constant temperature with the refrigeration chip 35, the rate of deterioration of the active sample can be reduced, and transportation over a longer period of time or over a long distance can be performed. The information of the container A is identified by the wireless radio frequency induction module 38, and the information of the active sample conveying device can be identified by the wireless radio frequency tag 12, so that the transportation operation is facilitated, the times of opening and closing the storage assembly 30 can be reduced, the chance of contacting the container A is avoided, and the cross contamination between the active sample and the conveying personnel can be avoided.

The wheel 43 and the pull rod 44 on the housing 40 can make the whole sample conveyer move more conveniently and more laborsavingly. Since the cover 42 is located on the lateral side of the housing 40, the entire active sample transport apparatus can be laid flat when the container a is to be taken out, and then the cover 42 is opened.

Claims

1. A living sample transport device for accommodating a plurality of containers each containing a living sample, comprising:

a frame;

a container part pivoted to the at least one rotating bracket;

2. The active analyte transport apparatus according to claim 1, wherein each of the at least one storage element comprises:

at least one ultraviolet light source fixed in the communicating space.

3. The active analyte transport apparatus according to claim 1, wherein each of the at least one storage element comprises:

4. The active-sample transport apparatus according to claim 1, wherein each of the at least one storage device has a GPS signal receiving module.

5. The active-specimen transport device according to claim 1, wherein each of the at least one storage element has a touch panel.

6. The active analyte transport apparatus according to claim 1, wherein each of the at least one storage assembly has a plurality of RF sensor modules respectively disposed in the slots for identifying information of the containers.

7. The active sample transport apparatus according to claim 1, further comprising at least one radio frequency tag respectively disposed on the at least one storage element.

8. The active sample transport device according to claim 1, further comprising a radio frequency tag provided on the frame.

9. The active-sample transport device according to any one of claims 2 to 6, wherein each of the at least one storage element has a battery cell.

10. The active sample transport apparatus according to claim 9, further comprising a power supply module, wherein the power supply module is fixed to the frame and electrically connected to the battery unit of each of the at least one storage assembly.

11. The active-specimen transport device according to any one of claims 2 to 6, further comprising a housing having a plurality of wheels and a pull rod; the frame, the at least one rotating bracket and the at least one storage component are arranged in the shell.