CN216605327U - Cold-stored sample frame of over-and-under type - Google Patents

Abstract

The utility model discloses a lifting type refrigerated specimen holder which comprises a supporting structure, a storage assembly and a lifting structure, wherein the supporting structure is provided with a support frame; the storage component is arranged in the supporting structure and connected with the supporting structure; the lifting structure is arranged on the end face of the supporting structure and is connected with the supporting structure; the storage assembly comprises a lifting assembly; the lifting component is arranged inside the storage component and connected with the storage component. The utility model has the beneficial effects that: set up elevation structure, make the storage assembly extend along first direction to can follow the shrink of second direction, can be more comprehensive show sample state and label during the expansion, put into the low temperature container during the shrink, save space.

Description

Cold-stored sample frame of over-and-under type

Technical Field

The utility model belongs to the technical field of medical experimental instruments, and particularly relates to a lifting type refrigerated specimen rack.

Background

In the clinical diagnosis process, pathological tissues, blood and the like of a patient are collected to be used as samples to carry out experiments so as to determine the disease of the patient, and a corresponding treatment method is established. In order to preserve a pathological specimen of a patient, it is often necessary to place it in a harsh cryogenic environment, such as a cryogenic container, e.g., a liquid nitrogen holding tank or freezer, in order to maintain viability for a long period of time.

In such a low-temperature environment, the collected sample cannot be directly put into the container, and the sample cannot be directly taken out from the container. It is now common practice to place biological samples on sample holders, which are then transferred to a cryogenic container.

The sample frame that uses at present simple structure, the function is single, is not convenient for read sample label information, can consume more time when looking for required sample, leads to all the other samples to break away from the low temperature state, is unfavorable for the sample to preserve. And the state of the sample can be observed only after the sample is taken out.

The utility model aims at the problems and provides a lifting type refrigerated specimen rack.

SUMMERY OF THE UTILITY MODEL

In order to overcome the problems presented in the background art, the utility model provides a lifting type refrigerated specimen rack.

A lifting type refrigerated specimen rack comprises a supporting structure, a storage assembly and a lifting structure; the storage assembly is arranged in the supporting structure and connected with the supporting structure; the lifting structure is arranged on the end face of the supporting structure and is connected with the supporting structure; the storage assembly comprises a lifting assembly; the lifting component is arranged inside the storage component and connected with the storage component.

Further, setting the first direction as the extending direction of the whole mechanism; setting the second direction as the opposite direction of the first direction; setting the third direction as a sample taking direction; the fourth direction is set to be opposite to the third direction.

Further, the support structure comprises an outer frame and a first mounting frame; the storage component is arranged in the supporting structure and is fixedly connected with the supporting structure; the first mounting frames are respectively arranged on two sides of the outer frame close to the first direction and fixedly connected with the outer frame.

Furthermore, the lifting assembly comprises a support rod, a sliding block and a rotating shaft; the sliding block is connected with the storage component in a sliding manner; the sliding blocks are arranged at two ends of the support rod and are rotationally connected with the support rod; the rotating shaft is arranged in the middle of the support rod and is rotatably connected with the support rod.

Furthermore, the stay bar is connected with the connected stay bar in a rotating way by taking the sliding block as an axis.

Or the support rod is connected with the connecting support rod in a rotating mode by taking the rotating shaft as an axis.

Further, a blood sample cartridge for housing a patient blood sample is provided; the storage assembly further comprises a first storage unit; the first storage unit is arranged in the fourth direction of the lifting assembly and is connected with the lifting assembly; the first storage unit is fixedly connected with the supporting structure; the projection pattern of the first storage unit in the second direction is the same as the projection pattern of the support structure in the second direction; the area of a projected graph of the first storage unit in the second direction is smaller than that of the projected graph of the support structure in the second direction; the blood sample box is arranged in the first storage unit, and the blood sample box is detachably connected with the first storage unit.

Alternatively, a tissue sample cassette is provided for housing a diseased tissue sample from a patient; the storage assembly further comprises a second storage unit; the second storage unit is arranged in the fourth direction of the lifting assembly and is connected with the lifting assembly; the second storage unit is fixedly connected with the supporting structure; the projection pattern of the second storage unit in the second direction is the same as the projection pattern of the support structure in the second direction; the area of a projected graph of the second storage unit in the second direction is smaller than that of the projected graph of the support structure in the second direction; the tissue sample box is arranged in the second storage unit, and the tissue sample box is detachably connected with the second storage unit.

Further, the storage assembly comprises two or more first storage units; the first storage units are sequentially arranged along a first direction, and adjacent first storage units are connected by a lifting assembly; the projection patterns of the two or more first storage units in the second direction are completely overlapped.

Further, the first storage unit comprises a first storage cabin and a first slide way; the first slideway is arranged in the third direction of the first storage cabin and is connected with the first storage cabin; the first slide way is connected with the slide block in a sliding mode.

Further, the storage assembly comprises two or more second storage units; the second storage units are sequentially arranged along a first direction, and adjacent second storage units are connected by a lifting assembly; the projection patterns of the two or more second storage units in the second direction are completely overlapped.

Further, the second storage unit comprises a second storage compartment and a second slideway; the second slideway is arranged in the third direction of the second storage cabin and is connected with the second storage cabin; the second slide way is connected with the slide block in a sliding mode.

Further, the lifting structure comprises a handle and a second mounting rack; the second mounting frame is rotatably connected with the first mounting frame; the second mounting frames are respectively arranged at two ends of the handle and fixedly connected with the handle.

The utility model has the beneficial effects that: set up elevation structure, make the storage assembly extend along first direction to can follow the shrink of second direction, can be more comprehensive show sample state and label during the expansion, put into the low temperature container during the shrink, save space.

Drawings

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

FIG. 2 is an expanded view of the overall structure of the present invention;

FIG. 3 is a schematic view of a support structure of the present invention;

FIG. 4 is a schematic view of a storage assembly of the present invention;

FIG. 5 is a schematic diagram of a first memory cell of the present invention;

FIG. 6 is a schematic view of the overall structure of embodiment 3 of the present invention;

FIG. 7 is an extended view of the overall structure of embodiment 3 of the present invention;

FIG. 8 is a schematic diagram of a second storage unit according to the present invention;

in the figure, 1, a support structure; 11. an outer frame; 12. a first mounting bracket; 2. a storage assembly; 21. a first storage unit; 211. a first storage compartment; 212. a first slideway; 22. a stay bar; 23. a slider; 24. a rotating shaft; 25. a second storage unit; 251. a second storage compartment; 252. a second slideway; 3. a pull-up structure; 31. a grip; 32. a second mounting bracket.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described below by specific embodiments, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, rather than all embodiments, and other advantages and effects of the present invention can be easily understood by those skilled in the art from the disclosure of the present specification. The present invention can be implemented or applied by other different specific embodiments, and the features in the following embodiments and embodiments can be combined with each other without conflict, and all other embodiments obtained by a person of ordinary skill in the art without creative efforts based on the embodiments of the present invention belong to the protection scope of the present invention.

The first direction mentioned in the technical scheme is the extending direction of the whole mechanism; the second direction is opposite to the first direction; the third direction is a sample taking direction; the fourth direction is opposite to the third direction.

Example 1

As shown in fig. 1, the lifting type refrigerated specimen holder of the present embodiment includes a supporting structure 1, a storage assembly 2 and a lifting structure 3; the storage component 2 is arranged inside the supporting structure 1, and the storage component 2 is connected with the supporting structure 1; the lifting structure 3 is arranged on the end face of the supporting structure 1, and the lifting structure 3 is connected with the supporting structure 1; the storage assembly 2 comprises a lifting assembly; the lifting component is arranged inside the storage component 2 and is connected with the storage component 2.

A blood sample cartridge is provided for receiving a blood sample from a patient.

The storage assembly 2 further comprises a first storage unit 21; the first storage unit 21 is arranged in the fourth direction of the lifting assembly, and the first storage unit 21 is connected with the lifting assembly; the first storage unit 21 is fixedly connected with the support structure 1; the projection pattern of the first storage unit 21 in the second direction is the same as the projection pattern of the support structure 1 in the second direction; the area of the projected pattern of the first storage unit 21 in the second direction is smaller than the area of the projected pattern of the support structure 1 in the second direction; the blood sample cassette is disposed inside the first storage unit 21, and the blood sample cassette is detachably connected to the first storage unit 21.

Example 2

As shown in fig. 2 to 5, the present embodiment specifically sets the following technical features on the basis of embodiment 1:

the support structure 1 comprises an outer frame 11 and a first mounting frame 12; the storage component 2 is arranged inside the supporting structure 1, and the storage component 2 is fixedly connected with the supporting structure 1; the first mounting brackets 12 are respectively disposed on two sides of the outer frame 11 close to the first direction, and the first mounting brackets 12 are fixedly connected with the outer frame 11.

The lifting assembly comprises a support rod 22, a sliding block 23 and a rotating shaft 24; the sliding block 23 is connected with the storage component 2 in a sliding way; the sliding blocks 23 are arranged at two ends of the support rod 22, and the sliding blocks 23 are rotatably connected with the support rod 22; the rotating shaft 24 is arranged in the middle of the stay bar 22, and the rotating shaft 24 is rotatably connected with the stay bar 22.

The stay 22 and the connected stay 22 are rotatably connected with the slider 23 as an axis.

Alternatively, the stay 22 and the connected stay 22 are rotatably connected with the rotation shaft 24 as an axis.

The storage assembly 2 comprises two or more first storage units 21; the first storage units 21 are sequentially arranged along a first direction, and adjacent first storage units 21 are connected by a lifting assembly; the projection patterns of the two or more first storage units 21 in the second direction are completely overlapped.

The first storage unit 21 includes a first storage compartment 211 and a first chute 212; the first chute 212 is arranged in a third direction of the first storage compartment 211, and the first chute 212 is connected with the first storage compartment 211; the first slide 212 is slidably connected to the slider 23.

The first storage compartment 211 is internally provided with a feedback structure, and the feedback structures are respectively arranged on the side walls of the first storage compartment 211.

The feedback structure comprises an inductor, a power supply and a light source structure; the inductor, the power supply and the light source structure are connected through a lead; the light source structures are respectively arranged on the outer side walls of the first storage compartments 211; after the blood sample box is placed in the first storage compartment 211, the sensor is stimulated to light the light source structure, thereby prompting that the sample is placed in the first storage compartment 211.

The lifting structure 3 comprises a handle 31 and a second mounting frame 32; the second mounting bracket 32 is rotatably connected with the first mounting bracket 12; the second mounting brackets 32 are respectively disposed at two ends of the handle 31, and the second mounting brackets 32 are fixedly connected to the handle 31.

Example 3

As shown in fig. 6 to 8, the present embodiment is different from embodiment 2 in that:

a tissue sample cassette is provided for housing a diseased tissue sample from a patient.

The storage assembly 2 further comprises a second storage unit 25; the second storage unit 25 is arranged in the fourth direction of the lifting assembly, and the second storage unit 25 is connected with the lifting assembly; the second storage unit 25 is fixedly connected to the support structure 1; the projection pattern of the second storage unit 25 in the second direction is the same as the projection pattern of the support structure 1 in the second direction; the projected pattern area of the second storage unit 25 in the second direction is smaller than the projected pattern area of the support structure 1 in the second direction; the tissue sample cassette is arranged inside the second storage unit 25, and the tissue sample cassette is detachably connected with the second storage unit 25.

The storage assembly 2 comprises two or more second storage units 25; the second storage units 25 are sequentially arranged along a first direction, and adjacent second storage units 25 are connected by a lifting assembly; the projection patterns of the two or more second storage units 25 in the second direction are completely overlapped.

The second storage unit 25 includes a second storage compartment 251 and a second slide 252; the second slide way 252 is arranged in the third direction of the second storage compartment 251, and the second slide way 252 is connected with the second storage compartment 251; the second slide 252 is slidably connected to the slider 23.

Feedback structures are provided inside the second storage compartment 251, and the feedback structures are respectively provided on the sidewalls of the second storage compartment 251.

The feedback structure comprises an inductor, a power supply and a light source structure; the inductor, the power supply and the light source structure are connected through a lead; the light source structures are respectively arranged on the outer side walls of the second storage compartment 251; when the tissue sample box is placed in the second storage compartment 251, the sensor is stimulated to light the light source structure, thereby indicating that the sample is placed in the second storage compartment 251.

The above description of the embodiments is only intended for the understanding of the present invention. It should be noted that modifications could be made to the utility model without departing from the principle of the utility model, which would also fall within the scope of the claims of the utility model.

Claims (10)

1. A lifting type refrigerated specimen rack comprises a supporting structure, a storage assembly and a lifting structure; the device is characterized in that the storage component is arranged in the supporting structure and connected with the supporting structure; the lifting structure is arranged on the end face of the supporting structure and is connected with the supporting structure; the storage assembly comprises a lifting assembly; the lifting assembly is arranged in the storage assembly and is connected with the storage assembly; setting the first direction as the extending direction of the whole mechanism; setting the second direction as the opposite direction of the first direction; setting the third direction as a sample taking direction; setting the fourth direction as the opposite direction of the third direction; the support structure comprises an outer frame and a first mounting frame; the first mounting frames are respectively arranged on two sides of the outer frame close to the first direction and fixedly connected with the outer frame.

2. The elevating refrigerated specimen holder of claim 1 wherein the storage assembly is fixedly attached to the support structure.

3. The elevating refrigerated specimen holder of claim 2 wherein the elevating assembly comprises a support rod, a slide block and a rotating shaft; the sliding block is connected with the storage component in a sliding manner; the sliding blocks are arranged at two ends of the support rod and are rotationally connected with the support rod; the rotating shaft is arranged in the middle of the support rod and is rotatably connected with the support rod.

4. The elevating refrigerated specimen holder of claim 3 wherein the support rod is rotatably connected to the connecting support rod about the slide block;

or the support rod is connected with the connecting support rod in a rotating mode by taking the rotating shaft as an axis.

5. An elevating refrigerated specimen holder according to claim 4 wherein a blood sample cassette is provided for receiving a patient blood sample; the storage assembly further comprises a first storage unit; the first storage unit is arranged in the fourth direction of the lifting assembly and is connected with the lifting assembly; the first storage unit is fixedly connected with the supporting structure; the projection pattern of the first storage unit in the second direction is the same as the projection pattern of the support structure in the second direction; the area of a projected graph of the first storage unit in the second direction is smaller than that of the projected graph of the support structure in the second direction; the blood sample box is arranged in the first storage unit, and the blood sample box is detachably connected with the first storage unit.

6. An elevating refrigerated specimen holder according to claim 4 wherein a tissue specimen cassette is provided for receiving diseased tissue specimens of a patient; the storage assembly further comprises a second storage unit; the second storage unit is arranged in the fourth direction of the lifting assembly and is connected with the lifting assembly; the second storage unit is fixedly connected with the supporting structure; the projection pattern of the second storage unit in the second direction is the same as the projection pattern of the support structure in the second direction; the area of a projected graph of the second storage unit in the second direction is smaller than that of the projected graph of the support structure in the second direction; the tissue sample box is arranged in the second storage unit, and the tissue sample box is detachably connected with the second storage unit.

7. The elevating refrigerated specimen holder of claim 5 wherein the storage assembly comprises two or more first storage units; the first storage units are sequentially arranged along a first direction, and adjacent first storage units are connected by a lifting assembly; the projection patterns of the two or more first storage units in the second direction are completely overlapped.

8. The elevating refrigerated specimen holder of claim 7 wherein the first storage unit comprises a first storage compartment and a first slide; the first slideway is arranged in the third direction of the first storage cabin and is connected with the first storage cabin; the first slide way is connected with the slide block in a sliding mode.

9. The elevating refrigerated specimen holder of claim 6 wherein the storage assembly comprises two or more second storage units; the second storage units are sequentially arranged along a first direction, and adjacent second storage units are connected by a lifting assembly; the projection graphs of the two or more second storage units in the second direction are completely overlapped; the second storage unit comprises a second storage cabin and a second slide way; the second slideway is arranged in a third direction of the second storage cabin and is connected with the second storage cabin; the second slide way is connected with the slide block in a sliding mode.

10. The elevating refrigerated specimen holder of any one of claims 5 to 9 wherein the lifting structure comprises a handle and a second mounting bracket; the second mounting frame is rotatably connected with the first mounting frame; the second mounting frames are respectively arranged at two ends of the handle and fixedly connected with the handle.

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