CN221156785U - Detection sample storage device - Google Patents

Abstract

The utility model relates to the technical field of sample storage, and discloses a detection sample storage device, wherein a slide block and a support frame in a storage frame are driven to slide when a pressing head presses so as to fix a detection sample; the pressing head presses the slide block and the support frame to move to two sides, the support frame moves in the through hole in the middle of the support plate, the movement distance is determined by the distance that the pressing head presses the inner cavity of the storage frame, samples with different diameters can be stored, after the pressing head is loosened, the first spring compressed and contracted during pressing presses the support frame after no stress, and therefore the samples in the middle of the support frame are clamped; the base at the bottom of the sample of the clamping block with the rubber material arranged on the opposite surface of the supporting frame is more attached to the sample by adopting an arc-shaped design, so that the sample is not damaged; the motor drives the gear to link the rack to drive the whole chassis to extend or retract, so that the storing and taking process is more convenient and clear at a glance.

Description

Detection sample storage device

Technical Field

The utility model relates to the technical field of sample storage, in particular to a detection sample storage device.

Background

With the development of modern medicine, test subjects have progressed from medical tests to test medicine, which is an independent subject of depression, and plays a great role in diagnosis, treatment and prevention of diseases. The medical test can carry out early diagnosis on the disease condition of a patient, has important relation to the cure of the disease condition, and a plurality of test results are key indexes; can guide clinical treatment and detect curative effect; the health condition of the human body can be correctly estimated; emergency diagnosis can be made for epidemic diseases. The amount of each inspection operation of the clinical laboratory is white, and after the inspection operation is finished, the residual sample should be kept as complete as possible, so that the doctor can increase doctor orders or research demands, abnormal handling demands, medical dispute responsibility attribution and the like due to medical demands.

According to the immune function detection sample storage device disclosed in the Chinese patent disclosure CN215827457U, the immune function detection sample storage device comprises a pump body, a main body cylinder, a perfusion tube, a partition board, a placing cylinder, a communicating pipe, a connecting ring, a cover plate, a first telescopic rod, a connecting frame, a second telescopic rod, a sealing gasket, a sliding seat, a rotating shaft, a placing disc, a driving motor, a speed reducer and a vertical plate, wherein the partition board is arranged in the main body cylinder, the partition board is matched with the lower part of the main body cylinder to form a driving cavity, the placing cylinder is arranged on the upper part of the partition board and is positioned in the center of the main body cylinder, the upper part of the placing cylinder is flush with the upper part of the main body cylinder and is connected through the connecting ring, and the cover plate is correspondingly covered on the upper part of the placing cylinder. The utility model overcomes the defects of the prior art, can store samples in a classified way, drives the samples to rotate and stores the samples in a cooling way, thereby reducing the activity of the samples, ensuring that the samples are heated uniformly and are convenient to store, and being convenient for storing, taking and using the samples.

However, when the utility model drives the samples to rotate, each sample cannot be fixed, and the samples may be turned over during storage and may pollute other samples, so as to influence the detection result. In order to solve the problem, the utility model fixes each sample so as to prevent the phenomenon of falling out during transportation or movement, thereby bringing inconvenience to subsequent detection.

Disclosure of utility model

(One) solving the technical problems

Aiming at the defects of the prior art, the utility model provides a detection sample storage device which has the advantage of independent fixation and solves the problems that side leakage occurs when sample reagents are not fixed well, different sample bottle specifications are not uniformly stored and samples are not easy to uniformly take.

(II) technical scheme

In order to achieve the above purpose, the present utility model provides the following technical solutions: a test sample storage device comprising an external frame, the external frame comprising:

The box, its inside is provided with flexible subassembly, be provided with on the flexible subassembly and deposit the subassembly, deposit the subassembly and include:

The storage frame is arranged at the top of the telescopic component;

the pressing mechanism is arranged in the cavity at the bottom of the storage frame, and comprises:

the pressing head is inserted into the front side of the storage frame;

the second spring is arranged around the outer wall of the pressing head;

the sliding blocks are arranged on two sides of the pressing head and are in sliding connection with the inner wall of the cavity at the bottom of the storage frame;

the support frame is arranged on one side of the sliding block, which is far away from the pressing head;

The first spring is arranged on one side, far away from the sliding block, of the supporting frame, and one side, far away from the supporting frame, of the first spring is connected with the inner wall of the cavity at the bottom of the storage frame;

The sliding mechanism is arranged on the supporting frame.

Preferably, the sliding mechanism includes:

the support plate penetrates through the support frame;

The through hole is arranged on the supporting plate, has a size slightly larger than that of the supporting frame and can be used for the supporting frame to move;

the clamping block is arranged on the opposite surface of the top of the support frame.

Preferably, the telescopic assembly comprises:

The chassis is arranged at the bottom of the storage frame;

racks arranged on two sides of the top of the chassis;

the second gear is arranged at the top of the right side of the rack;

the motor penetrates through the right side of the box body, and the output end of the motor is connected with the second gear;

the first gear is arranged at the top of the left side of the rack.

Preferably, the bottom of the box body is provided with a refrigerating device, and the chassis is provided with air holes for cold air blown out by the refrigerating device to pass through.

Preferably, the supporting frame is in a shape with a narrow upper part and a wide lower part, the width of the part which is positioned in the cavity of the storage frame is the same as that of the sliding block, and the width of the part which extends out of the supporting plate is slightly narrower than that of the through hole.

Preferably, the support plate top is provided with the base and is in between the support frame, the base with the fixture block is the arc design and is the rubber material.

Preferably, the sliding blocks are in a trapezoid design, and the largest opening part of the two sliding blocks can pass through the narrowest part of the front end of the pressing head.

(III) beneficial effects

Compared with the prior art, the utility model provides a detection sample storage device, which has the following beneficial effects:

According to the detection sample storage device, the sliding blocks and the supporting frames in the storage frame are driven to slide to fix detection samples when the pressing heads are pressed, the sliding blocks and the supporting frames move to two sides when the pressing heads are pressed, the supporting frames move in the through holes in the middle of the supporting plates, the moving distance is determined by the distance that the pressing heads are pressed into the cavities in the storage frame, samples with different diameters can be stored, after the pressing heads are released, the first springs which are pressed and contracted when pressed press the supporting frames after no stress, so that the samples in the middle of the supporting frames are clamped; the base at the bottom of the sample of the clamping block with the rubber material arranged on the opposite surface of the supporting frame is more attached to the sample by adopting an arc-shaped design, so that the sample is not damaged; the motor drives the gear to link the rack to drive the whole chassis to extend or retract, so that the storing and taking process is more convenient and clear at a glance.

Drawings

FIG. 1 is a schematic cross-sectional view of a front structure of the present utility model;

FIG. 2 is a schematic elevational cross-sectional view of a storage assembly according to the present utility model;

FIG. 3 is a schematic top view of a pressing mechanism according to the present utility model;

FIG. 4 is a schematic top view of a sliding mechanism according to the present utility model;

fig. 5 is a schematic top view of the telescopic assembly of the present utility model.

In the figure:

1. An outer frame; 11. a case; 12. a telescoping assembly; 121. a chassis; 122. a rack; 123. a first gear; 124. a second gear; 125. a motor; 13. a refrigeration device;

2. A storage assembly; 21. a storage frame; 22. a pressing mechanism; 221. pressing head; 222. a slide block; 223. a support frame; 224. a first spring; 225. a second spring; 23. a sliding mechanism; 231. a support plate; 232. a clamping block; 233. a through hole; 24. and (5) a base.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

Referring to fig. 1 to 5, a test sample storage device includes an outer frame 1, the outer frame 1 including: the box 11, its inside is provided with flexible subassembly 12, be provided with on the flexible subassembly 12 and deposit subassembly 2, deposit subassembly 2 and include: deposit frame 21 set up in telescoping assembly 12 top, press mechanism 22 set up in deposit frame 21 bottom cavity, press mechanism 22 includes: the pressing head 221 is inserted in the front side of the storage frame 21, the second spring 225 is arranged around the outer wall of the pressing head 221, the second spring 225 can limit the pressing direction of the pressing head 221, the second spring 225 is compressed when being pressed, and after the pressing is finished, the second spring 225 is restored to the original state, so that the pressing head 221 is driven to return to the original position. The sliding blocks 222 are disposed at two sides of the pressing head 221 and slidably connected with the inner wall of the cavity at the bottom of the storage frame 21, the sliding blocks 222 are in a trapezoidal design, and the largest opening of the two sliding blocks 222 can pass through the narrowest part of the front end of the pressing head 221. When the pressing head 221 presses toward the inside of the storage frame 21, the pressing head 221 presses forward along the angle formed by the two sliding blocks 222, and the sliding blocks 222 on both sides slide toward both sides after being pressed. The support frame 223 is arranged at one side of the sliding block 222 far away from the pressing head 221, the sliding block 222 drives the support frame 223 to slide towards two sides after sliding, the first spring 224 is arranged at one side of the support frame 223 far away from the sliding block 222, one side far away from the support frame 223 is connected with the inner wall of the cavity at the bottom of the storage frame 21, the sliding block 222 and the support frame 223 can compress the first spring 224 at one side of the support frame 223 when being extruded and slid to the outside, after not being extruded, the first spring 224 rebounds to drive the sliding block 222 and the support frame 223 to slide to the original position, the sliding distance between the sliding block 222 and the support frame 223 is influenced by the pressing force of the pressing head 221, when encountering the larger sample of diameter, alright great dynamics presses the press head 221, and slider 222 and support frame 223 gliding distance grow this moment, and the space between two support frames 223 is great, alright put into the detection sample of great diameter, and this press mechanism 22 does not receive the influence of detection sample diameter, alright so deposit the detection sample of multiple diameter, can not appear the condition that the same diameter detection sample just can place a storage device, convenient storage. The sliding mechanism 23 is disposed on the supporting frame 223, and after the pressing mechanism 22 at the bottom of the sliding mechanism 23 is pressed, the supporting frame 223 can slide on the sliding mechanism 23 to complete the subsequent clamping process of the sample. The slide mechanism 23 includes: the support plate 231 is inserted into the support plate 223, and the through hole 233 is formed in the support plate 231, and has a size slightly larger than that of the support plate 223, so that the support plate 223 can be moved, the support plate 223 is in a shape with a narrow upper part and a wide lower part, the part in the cavity of the storage frame 21 is the same as the width of the slider 222, and the part extending out of the support plate 231 is slightly narrower than the width of the through hole 233. After the sliding block 222 is extruded, the supporting frame 223 is driven to slide to two sides, and a wider part at the bottom of the supporting frame 223 transfers force from the sliding block 222 to the supporting frame 223 better, so that the width of the top of the supporting frame 223 is slightly smaller than that of the through hole 233, and the top of the supporting frame 223 can move back and forth in the through hole 233. The fixture block 232 is arranged on the opposite surface of the top of the supporting frame 223, the base 24 is arranged on the top of the supporting plate 231 and between the supporting frames 223, and the base 24 and the fixture block 232 are arc-shaped and made of rubber. The fixture block 232 clamps the side of sample, and the base 24 holds in the palm the end to the arc bottom of sample, and the rubber material makes can not extrude the sample and lead to the sample impaired when fixing the sample.

When the sample is required to be stored, an operator only needs to press the pressing head 221 on the side surface of the storage frame 21, the pressing head 221 presses the second spring 225 on the outer ring to press the inside of the storage frame 21, the sliding block 222 in the cavity of the storage frame 21 slides towards two sides after being pressed, the supporting frame 223 connected with one side of the sliding block 222 is driven to slide towards two sides, and at the moment, the first spring 224 connected with one side, far away from the sliding block 222, of the supporting frame 223 is pressed. The support frame 223 can slide in the support plate 231 through the through hole 233, and is influenced by the pressing force of the pressing head 221, when the pressing force is large, the sliding distance between the sliding block 222 and the support frame 223 at two sides is increased, at this time, the gap between the two support frames 223 is increased, and a detection sample with a larger diameter can be placed. After the detection sample is placed, the pressing head 221 is loosened, the outer ring of the pressing head 221 is subjected to the second spring 225 which is extruded, the elastic force during recovery drives the pressing head 221 to return to the original position, at the moment, the sliding block 222 and the supporting frame 223 are not subjected to the force during the pressing of the pressing head 221 any more, the first spring 224 which is not stressed after the compression is ended rebounds, the clamping block 232 on the opposite surfaces of the supporting frame 223 clamps the outer side wall of the detection sample, the base 24 at the bottom drags the detection sample, the clamping block 232 and the base 24 adopt an arc-shaped design for attaching the detection sample, and the rubber material is used, so that the surface of the sample cannot be abraded when the detection sample is firmly clamped.

Example two

On the basis of the first embodiment, the functions of uniformly extending or retracting the whole detection sample and refrigerating the sample are added.

Referring to fig. 1-5, in the conventional storage device, the efficiency is low because the storage device needs to be opened to access samples one by one, and in order to solve the problem, the motor 125 is adopted to drive the whole tray to extend out of the storage mechanism, so that the storage frame 21 is easier to access and search the detection samples by an operator after being fully exposed. The telescopic assembly 12 is located inside the box 11, and the telescopic assembly 12 comprises: the chassis 121 is arranged at the bottom of the storage frame 21, six groups of storage frames 21 are uniformly arranged on the chassis 121, racks 122 are arranged on two sides of the top of the chassis 121, a second gear 124 is arranged at the top of the right side of the racks 122, a motor 125 penetrates through the right side of the box 11, the output end of the chassis is connected with the second gear 124, when the motor 125 is started, the second gear 124 drives the output end to rotate, the second gear 124 rotates, the racks 122 at the bottom are linked to move when the second gear 124 rotates, and because the racks 122 are arranged on the chassis 121, the racks 122 can drive the chassis 121 to stretch out or shrink, a first gear 123 is arranged at the top of the left side of the racks 122, when the whole chassis 121 is driven to stretch out or retract, the racks 122 at the left side of the chassis 121 also move, the first gear 123 at the top is driven to rotate, the gears at the two sides are all driven, and the whole chassis 121 stretches out or retracts to operate more labor-saving. When a detection sample needs to be stored and taken, the motor 125 is started, so that the motor 125 rotates anticlockwise, the motor 125 drives the gear II 124 to rotate, the gear II 124 is linked with the rack 122 on the right side of the top of the chassis 121 to move, the rack 122 drives the whole chassis 121 to extend when moving, and the gear I123 on the left side is driven to rotate when the chassis 121 extends; the chassis 121 can be accessed after extending, all extending and accessing are more clear, the driving motor 125 runs clockwise after the accessing is completed, the second gear 124 rotates reversely, the linkage rack 122 drives the chassis 121 to move towards the inside of the box 11, and the retraction of the chassis 121 can be realized. The general detection sample needs to be refrigerated after collection, so that the activity of the sample is ensured, the storage device needs to be provided with a refrigeration device 13, the bottom of the box body 11 is provided with the refrigeration device 13, the chassis 121 is provided with air holes, and cold air blown out by the refrigeration device 13 can be cooled through the detection sample stored in the storage frame 21 at the upper layer, so that the activity of the detection sample is ensured.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. A test sample storage device, characterized by: comprising an outer frame (1), the outer frame (1) comprising:

the box (11), its inside is provided with flexible subassembly (12), be provided with on flexible subassembly (12) and deposit subassembly (2), deposit subassembly (2) and include:

the storage frame (21) is arranged at the top of the telescopic component (12);

The pressing mechanism (22) is arranged in the cavity at the bottom of the storage frame (21), and the pressing mechanism (22) comprises:

a pressing head (221) inserted into the front side of the storage frame (21);

a second spring (225) which is arranged around the outer wall of the pressing head (221);

The sliding blocks (222) are arranged on two sides of the pressing head (221) and are in sliding connection with the inner wall of the cavity at the bottom of the storage frame (21);

A support (223) provided on a side of the slider (222) away from the pressing head (221);

The first spring (224) is arranged on one side, far away from the sliding block (222), of the supporting frame (223), and one side, far away from the supporting frame (223), of the first spring is connected with the inner wall of the cavity at the bottom of the storage frame (21);

and a sliding mechanism (23) provided on the support frame (223).

2. A test sample storage device as claimed in claim 1, wherein: the slide mechanism (23) includes:

a support plate (231) penetrating the support frame (223);

The through hole (233) is arranged on the supporting plate (231) and has a size slightly larger than that of the supporting frame (223) so as to enable the supporting frame (223) to move;

the clamping blocks (232) are arranged on the opposite surfaces of the top of the supporting frame (223).

3. A test sample storage device as claimed in claim 1, wherein: the telescopic assembly (12) comprises:

the chassis (121) is arranged at the bottom of the storage frame (21);

Racks (122) arranged on both sides of the top of the chassis (121);

The second gear (124) is arranged at the top of the right side of the rack (122);

the motor (125) penetrates through the right side of the box body (11), and the output end of the motor is connected with the second gear (124);

and the first gear (123) is arranged at the left top of the rack (122).

4. A test sample storage device as claimed in claim 3, wherein: the bottom of the box body (11) is provided with a refrigerating device (13), and the chassis (121) is provided with air holes for cold air blown out by the refrigerating device (13) to pass through.

5. A test sample storage device as claimed in claim 2, wherein: the supporting frame (223) is in a shape with a narrow upper part and a wide lower part, the width of the part which is positioned in the cavity of the storage frame (21) is the same as that of the sliding block (222), and the width of the part which extends out of the supporting plate (231) is slightly narrower than that of the through hole (233).

6. A test sample storage device as claimed in claim 2, wherein: the top of the supporting plate (231) is provided with a base (24) between the supporting frames (223), and the base (24) and the clamping blocks (232) are of arc-shaped design and made of rubber materials.

7. The test sample storage device of claim 5, wherein: the sliding blocks (222) are in a trapezoid design, and the largest opening part of the two sliding blocks (222) can pass through the narrowest part of the front end of the pressing head (221).