CN216917035U

CN216917035U - Remote long-acting heat preservation device with built-in frozen blue ice for soil sample to be detected

Info

Publication number: CN216917035U
Application number: CN202122335065.XU
Authority: CN
Inventors: 洪博; 毛凯; 杨超锦
Original assignee: Qingdao Kanghuan Testing Technology Co ltd
Current assignee: Yiming Testing Technology Service Qingdao Co ltd
Priority date: 2021-09-26
Filing date: 2021-09-26
Publication date: 2022-07-08
Anticipated expiration: 2031-09-26

Abstract

The utility model discloses a remote long-acting thermal insulation device for a soil sample to be detected with built-in frozen blue ice, which comprises a thermal insulation box, wherein a regular hexagonal thermal insulation chamber is arranged in the thermal insulation box, and a six-way partition frame is arranged in the thermal insulation chamber; the six-direction separation frame comprises six first separation plates which are annularly arranged at equal angles, and one ends of the six first separation plates are connected into a whole; the insulation chamber is equally divided into six triangular accommodating units by the six-direction partition frame; a three-way separation frame is respectively arranged in each containing unit; the three-way separation frame comprises three second partition plates which are annularly arranged at equal angles, and one ends of the three second partition plates are connected into a whole; the three-way separation frame equally divides the containing unit into three quadrilateral containing grids; the sample container filled with the soil sample is correspondingly placed in the containing grids; a cavity is arranged in the second clapboard, and an ice bag is arranged in the cavity. The utility model can prevent the containers filled with the soil samples from colliding and breaking with each other, and the cooling effect on the samples is more uniform.

Description

Remote long-acting heat preservation device with built-in frozen blue ice for soil sample to be detected

Technical Field

The utility model relates to the technical field of soil detection, in particular to a long-distance long-acting heat preservation device with a built-in frozen blue ice for a soil sample to be detected.

Background

With the development of society, the range of industrial production and human activities is increased, and soil in some areas is polluted. In order to protect soil and treat soil pollution, a pollution source and soil in a polluted area need to be sampled and detected. The soil sample needs a certain time to be transported to a laboratory after being collected, and organic components in the soil may be decomposed or volatilized in the time, so that the soil detection result is influenced. Suitable storage and transport means are required for this purpose, so that the soil samples are stored at temperatures below 4 ℃ in the dark. Soil samples are generally stored using glass bottles, which are susceptible to breakage during transport.

Disclosure of Invention

The purpose of the utility model is as follows: in order to overcome the defects in the prior art, the utility model provides the remote long-acting heat preservation device with the built-in frozen blue ice for the soil sample to be detected, which can prevent the containers filled with the soil sample from colliding and breaking with each other and has more uniform cooling effect on the sample.

The technical scheme is as follows: in order to achieve the purpose, the long-distance long-acting heat preservation device for the soil sample to be detected with the built-in frozen blue ice comprises a heat preservation box, wherein a regular hexagonal heat preservation chamber is arranged in the heat preservation box, and a six-direction separation frame is arranged in the heat preservation chamber; the six-direction separation frame comprises six first separation plates which are annularly arranged at equal angles, and one ends of the six first separation plates are connected into a whole; the six-direction separation frame equally divides the heat preservation chamber into six triangular accommodating units; a three-way separation frame is respectively arranged in each containing unit; the three-way separation frame comprises three second partition plates which are annularly arranged at equal angles, and one ends of the three second partition plates are connected into a whole; the three-way separation frame equally divides the containing unit into three quadrilateral containing grids; the sample container filled with the soil sample is correspondingly placed in the containing grid; a cavity is arranged in the second partition plate, and an ice bag is placed in the cavity.

Furthermore, the outer wall of the heat insulation box is circular, and a circular box cover is arranged above the heat insulation box; the inner side of the lower end of the box cover and the upper end of the outer wall of the heat preservation box are screwed relatively through a thread structure.

Furthermore, a portable support is arranged outside the heat insulation box; the portable support comprises a bearing plate and a lifting rod, two vertical rods are oppositely arranged on the bearing plate, a long groove which transversely penetrates through and vertically extends is arranged above the vertical rods, and a separation port is arranged at one side of the long groove; the lifting rod is horizontally arranged, two ends of the lifting rod are respectively provided with an inwards concave annular clamping groove, and the lifting rod is clamped in the strip groove through the annular clamping grooves; at least two insulation boxes are stacked on the bearing plate; two sliding grooves are oppositely arranged on the outer wall of the heat preservation box; the two sliding grooves are respectively in vertical sliding fit with the two vertical rods.

Furthermore, two inwards concave ear hanging grooves are oppositely arranged on the outer wall of the heat preservation box.

Furthermore, an inwards concave handle groove is formed in the upper portion of the box cover, and a rotatable handle is arranged in the handle groove.

Furthermore, the six-direction separation frame is vertically connected with the inner wall of the heat preservation chamber in a sliding manner, and the six-direction separation frame can be drawn out in a sliding manner relative to the heat preservation chamber; the three-way separation frame is vertically connected with the six-way separation frame in a sliding mode, and the three-way separation frame can be drawn out in a sliding mode relative to the six-way separation frame.

Has the advantages that: the long-distance long-acting heat preservation device with the built-in frozen blue ice for the soil sample to be detected has the following beneficial effects:

1) a six-way separation frame and a three-way separation frame are arranged in the heat preservation box, the interior of the heat preservation chamber is divided into a plurality of containing grids, and each containing grid is correspondingly provided with a glass bottle filled with a soil sample, so that the glass bottles cannot collide with each other and are not easy to break;

2) the ice bag is placed in a cavity of the second partition plate of the three-way partition frame, and two second partition plates are arranged around each containing grid, so that the cooling effect of the heat preservation device on the soil sample in each containing grid is more uniform;

3) a plurality of heat preservation boxes can be carried by the portable bracket at the same time, so that the use is convenient;

4) the six-direction separation rack and the three-direction separation rack can be drawn out from the heat preservation box, and cleaning is convenient.

Drawings

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

FIG. 2 is a schematic view of the internal structure of the incubator;

FIG. 3 is a schematic structural view of a six-way partition frame and a three-way partition frame;

FIG. 4 is a schematic view of a twist grip;

FIG. 5 is a schematic structural view of a portable stand;

FIG. 6 is a schematic view showing the combination of the incubator and the cover.

Detailed Description

The present invention will be further described with reference to the accompanying drawings.

The long-distance long-acting thermal insulation device with the built-in frozen blue ice for the soil sample to be detected comprises a thermal insulation box 1, wherein a regular-hexagon thermal insulation chamber 2 is arranged in the thermal insulation box 1, and the cross section of the thermal insulation chamber 2 is in a regular hexagon shape.

A six-direction separation frame 3 is arranged in the heat preservation chamber 2. The structure of the six-direction separation frame 3 is as shown in the attached drawing 3, the six-direction separation frame 3 comprises six first partition plates 4 which are annularly arranged at equal angles, the six first partition plates 4 are same in shape, the six first partition plates 4 are vertical plate bodies, and one ends of the six first partition plates 4 are connected into a whole. The six-direction separation frame 3 equally divides the heat preservation chamber 2 into six regular triangle-shaped accommodating units 5.

Each accommodating unit 5 is internally provided with a three-way partition frame 6. The structure of the three-way partition frame 6 is shown in the attached drawing 3, the three-way partition frame 6 comprises three second partition plates 7 which are annularly arranged at equal angles, the structures and the shapes of the three second partition plates 7 are the same, the three second partition plates 7 are vertical plate bodies, and one ends of the three second partition plates 7 are connected into a whole. The three-way partition frame 6 equally divides the containing unit 5 into three quadrangular containing compartments 8.

A sample container 9 containing a soil sample is correspondingly placed in the containing compartment 8, and the sample container 8 is usually a glass bottle. Each second partition plate 7 is internally provided with a cavity 10, an ice bag 11 is placed in each cavity 10, and the upper end of each cavity 10 is provided with an opening for placing the ice bag 11.

The outer wall of the heat preservation box 1 is circular, a circular box cover 12 is arranged above the heat preservation box 1, and the box cover 12 is used for sealing the heat preservation box 1. As shown in fig. 6, the inner side of the lower end of the box cover 12 and the upper end of the outer wall of the heat preservation box 1 are screwed relatively through a screw structure.

And a portable bracket 13 is arranged outside the heat preservation box 1. The portable stand 13 includes a support plate 14 and a lifting bar 15. As shown in fig. 5, the supporting plate 14 is a horizontal circular plate, two vertical rods 16 are oppositely arranged on the supporting plate 14, a strip groove 17 which transversely penetrates through and vertically extends is arranged above the vertical rods 16, a separation port 18 is arranged on one side of the strip groove 17, and the separation port 18 is arranged in the vertical middle position of the strip groove 17. The lifting rod 15 is horizontally arranged, and the two ends of the lifting rod 15 are respectively provided with an inwards concave annular clamping groove 19. The lifting rod 15 is a round rod, and the width of the long strip groove 17 is larger than the diameter of the annular clamping groove 19 and smaller than the diameter of the lifting rod 15. The lifting rod 15 is clamped in the long groove 17 through the annular clamping groove 19. The lifting bar 15 can be disengaged from the elongated slot 17 through the disengagement opening 18.

At least two insulation boxes 1 are stacked on the bearing plate 14, and a plurality of insulation boxes 1 can be conveniently carried through the portable bracket 13. Two sliding grooves 20 are oppositely arranged on the outer wall of the heat preservation box 1. The two sliding grooves 20 are respectively in vertical sliding fit with the two vertical rods 16, so that the insulation can 1 can be fixed, and the insulation can 1 is prevented from falling off from the portable support 13. When the incubator 1 needs to be removed from the portable rack 13, the lift lever 15 is first removed from the release opening 18, and then the incubator 1 can be slid upward and removed.

When the heat preservation device of the utility model is carried to collect soil samples, a plurality of heat preservation boxes 1 can be carried by the portable bracket 13, and the heat preservation box 1 at the top is in a working state. After the uppermost insulation can 1 is filled with the soil sample, the stacking sequence of the insulation can 1 can be changed, and the empty insulation can 1 is placed at the uppermost end so as to continue to collect the soil sample.

The outer wall of the heat preservation box 1 is relatively provided with two inwards concave ear hanging grooves 21, and the heat preservation box 1 is conveniently lifted through the ear hanging grooves 21.

An inward handle groove 22 is formed above the box cover 12, a rotatable handle 23 is arranged in the handle groove 22, the handle 23 can conveniently rotate the box cover 12, and the handle groove 22 enables the surface of the box cover 12 to be relatively flush, so that a plurality of insulation boxes 1 can be stacked mutually.

The six-direction separation frame 3 is vertically connected with the inner wall of the heat preservation chamber 2 in a sliding manner, and the six-direction separation frame 3 can be drawn out in a sliding manner relative to the heat preservation chamber 2; the three-way partition frame 6 is vertically connected with the six-way partition frame 3 in a sliding manner, and the three-way partition frame 6 can be drawn out in a sliding manner relative to the six-way partition frame 3. Since the six-way partition shelf 3 and the three-way partition shelf 6 can be drawn out, the inside of the incubator 1 can be conveniently cleaned.

The above description is only of the preferred embodiments of the present invention, and it should be noted that: it will be apparent to those skilled in the art that various modifications and adaptations can be made without departing from the principles of the utility model and these are intended to be within the scope of the utility model.

Claims

1. The remote long-acting heat preservation device for the soil sample to be detected with the built-in frozen blue ice is characterized in that: the heat preservation device comprises a heat preservation box (1), wherein a regular hexagonal heat preservation chamber (2) is arranged in the heat preservation box (1), and a six-direction separation frame (3) is arranged in the heat preservation chamber (2); the six-direction separation frame (3) comprises six first partition plates (4) which are annularly arranged at equal angles, and one ends of the six first partition plates (4) are connected into a whole; the six-direction separation frame (3) equally divides the heat preservation chamber (2) into six triangular containing units (5);

each accommodating unit (5) is internally provided with a three-way separation frame (6); the three-way separation frame (6) comprises three second partition plates (7) which are annularly arranged at equal angles, and one ends of the three second partition plates (7) are connected into a whole; the three-way separation frame (6) equally divides the containing unit (5) into three quadrilateral containing grids (8); the sample container (9) filled with the soil sample is correspondingly placed in the containing grid (8); a cavity (10) is arranged in the second partition plate (7), and an ice bag (11) is placed in the cavity (10).

2. The remote long-acting heat preservation device for the soil sample to be detected with the built-in frozen blue ice according to claim 1, which is characterized in that: the outer wall of the heat preservation box (1) is circular, and a circular box cover (12) is arranged above the heat preservation box (1); the inner side of the lower end of the box cover (12) and the upper end of the outer wall of the heat preservation box (1) are screwed relatively through a thread structure.

3. The remote long-acting heat preservation device for the soil sample to be detected with the built-in frozen blue ice according to claim 2, characterized in that: a portable bracket (13) is arranged on the outer side of the heat preservation box (1); the portable support (13) comprises a bearing plate (14) and a lifting rod (15), two vertical rods (16) are oppositely arranged on the bearing plate (14), a long groove (17) which transversely penetrates through and vertically extends is arranged above the vertical rods (16), and a separation opening (18) is formed in one side of the long groove (17); the lifting rod (15) is horizontally arranged, two ends of the lifting rod (15) are respectively provided with an inwards concave annular clamping groove (19), and the lifting rod (15) is clamped in the long groove (17) through the annular clamping grooves (19);

at least two heat preservation boxes (1) are stacked on the bearing plate (14); two sliding grooves (20) are oppositely arranged on the outer wall of the heat preservation box (1); the two sliding grooves (20) are respectively in vertical sliding fit with the two vertical rods (16).

4. The remote long-acting heat preservation device for the soil sample to be detected with the built-in frozen blue ice according to claim 3, characterized in that: two inwards concave ear hanging grooves (21) are oppositely arranged on the outer wall of the heat preservation box (1).

5. The remote long-acting heat preservation device for the soil sample to be detected with the built-in frozen blue ice according to claim 3, characterized in that: an inwards concave handle groove (22) is formed above the box cover (12), and a rotatable handle (23) is arranged in the handle groove (22).

6. The remote long-acting heat preservation device for the soil sample to be detected with the built-in frozen blue ice according to claim 1, which is characterized in that: the six-direction separation frame (3) is vertically connected with the inner wall of the heat preservation chamber (2) in a sliding manner, and the six-direction separation frame (3) can be drawn out in a sliding manner relative to the heat preservation chamber (2); the three-way separation frame (6) is vertically connected with the six-way separation frame (3) in a sliding mode, and the three-way separation frame (6) can be drawn out in a sliding mode relative to the six-way separation frame (3).