CN216900593U - Annular heat conduction structure matched with annular sample disc and convenient for integrally receiving samples - Google Patents

Abstract

The utility model discloses an annular heat conduction structure which is matched with an annular sample disc and is convenient for integrally receiving a sample, and the annular heat conduction structure comprises a fixed base, a circular iron block, an annular sample disc body and a heat conduction mechanism, wherein a circular sliding groove is formed in the fixed base; according to the utility model, the heat conducting mechanism can be adsorbed and fixed at the top end of the circular iron block through the magnetic block arranged at the bottom end of the heat insulation shell, so that different annular sample disc bodies can be adapted conveniently and different placing grooves in the annular sample disc bodies can be adapted conveniently, the heat conducting mechanism is adsorbed and fixed below the placing grooves formed in the different annular sample disc bodies for heat conducting transmission, and therefore, the practicability and the convenience of the device are improved.

Description

Annular heat conduction structure matched with annular sample disc and convenient for integrally receiving samples

Technical Field

The utility model relates to the technical field of annular sample disc detection devices, in particular to an annular heat conduction structure which is matched with an annular sample disc and is convenient for integrally receiving a sample.

Background

The annular sample disc is a circular sample disc used for installing a detection reagent tube, is commonly used in the detection field, and is matched with a detection instrument for use to finish detection;

the traditional heat conduction structure is not beneficial to fixing annular sample discs with different sizes quickly, and meanwhile, the annular sample discs with different sizes and different grooves cannot be adapted to conduct heat, so that the utility model provides the annular heat conduction structure which is matched with the annular sample discs and is convenient for integrally accommodating samples, and the problems in the prior art are solved.

SUMMERY OF THE UTILITY MODEL

In view of the above problems, an object of the present invention is to provide an annular heat conducting structure, which is matched with an annular sample tray and facilitates overall sample receiving, and which solves the problem that the conventional heat conducting structure is not favorable for rapidly fixing annular sample trays of different sizes and cannot be adapted to heat annular sample trays of different sizes and different slots.

In order to realize the purpose of the utility model, the utility model is realized by the following technical scheme: the utility model provides a be convenient for whole annular heat conduction structure who accepts sample with annular sample dish is supporting, includes unable adjustment base, circular iron plate, annular sample dish body and heat conduction mechanism, circular spout has been seted up to unable adjustment base's inside, the internally mounted of circular spout has two sliders, two the top of slider all is through linking bridge fixedly connected with mounting panel, there is circular iron plate on the top of mounting panel through construction bolt threaded connection, the mounting groove has been seted up at the middle part of circular iron plate, mounting bracket fixedly connected with gas holder body is passed through on the top of mounting panel, the top of gas holder body adsorbs and is connected with annular sample dish body, the top of circular iron plate is provided with heat conduction mechanism.

The further improvement lies in that: the bottom end of the mounting plate is fixedly connected with the output end of the rotating motor through a flange connection plate.

The further improvement lies in that: the rotating motor is arranged in the installation box, and the installation box is arranged at the top end of the fixed base.

The further improvement lies in that: above-mentioned heat conduction mechanism is provided with thermal-insulated casing including thermal-insulated casing, graphite alkene installation piece and electric heating wire on the top of circular iron plate, the inside of thermal-insulated casing is provided with graphite alkene installation piece, and the lateral wall parcel of graphite alkene installation piece has electric heating wire.

The further improvement lies in that: the limiting groove is formed in the graphene mounting block, and the limiting groove is of an inverted triangular structure.

The further improvement lies in that: the inner side wall of the limiting groove is bonded with heat insulation cotton.

The further improvement lies in that: the bottom end of the heat insulation shell is provided with a magnetic block, and the heat insulation shell is connected with the top end of the round iron block in an adsorption mode through the magnetic block.

The utility model has the beneficial effects that: according to the utility model, the bottom end of the annular sample disc body is adsorbed and fixed through the arranged air suction disc body by means of air adsorption, so that the annular sample disc body can be rapidly replaced and installed, the practicability and convenience of the device are improved, and the connecting bracket at the bottom end of the mounting plate synchronously rotates in the circular sliding groove through the sliding block while the annular sample disc body rotates through the arranged circular sliding groove, so that the stability of the annular sample disc body in the rotating process is improved; through the arranged heat conduction mechanism, the heat conduction effect is better, the heat conduction mechanism can be adapted to different annular sample disc bodies and different placing grooves in the annular sample disc bodies, heat conduction is conducted through the electric heating wires and is transmitted to the graphene installation block, so that the graphene installation block transmits heat energy to the reagent tubes placed in the limiting grooves to complete heat conduction, the limiting grooves are arranged in an inverted triangular structure, so that the reagent tubes with different sizes can be placed, and meanwhile, the heat loss of the reagent tubes can be reduced through the heat insulation cotton; through the magnetic path that sets up, heat conduction mechanism can adsorb through the magnetic path that thermal-insulated casing bottom set up and fix the top at circular iron plate like this, is convenient for carry out different standing grooves in different annular sample dish body of adaptation and the annular sample dish body like this, adsorbs the below of fixing the standing groove that different annular sample dish bodies were seted up with heat conduction mechanism and carries out the heat conduction transmission, has improved the practicality and the convenience of device like this.

Drawings

Fig. 1 is a schematic front view of a cross-sectional structure according to the present invention.

Fig. 2 is a schematic structural diagram of the heat conducting mechanism of the present invention.

Fig. 3 is a schematic structural view of the heat conducting mechanism and the circular iron block assembly of the present invention.

FIG. 4 is a schematic view of the structure of the non-slip mat and soundproof cotton according to the present invention.

Wherein: 1. a fixed base; 2. a circular chute; 3. a slider; 4. connecting a bracket; 5. mounting a plate; 6. a flange connecting plate; 7. a rotating electric machine; 8. installing a box; 9. a round iron block; 10. mounting grooves; 11. a mounting frame; 12. a gas suction cup body; 13. an annular sample disk body; 14. a magnetic block; 15. a heat conducting mechanism; 1501. a thermally insulated housing; 1502. a graphene mounting block; 1503. an electric heating wire; 1504. a limiting groove; 1505. heat preservation cotton; 16. a non-slip mat; 17. soundproof cotton.

Detailed Description

In order to further understand the present invention, the following detailed description will be made with reference to the following examples, which are only used for explaining the present invention and are not to be construed as limiting the scope of the present invention.

Example one

According to the drawings of fig. 1-3, the embodiment provides an annular heat conducting structure matched with an annular sample disc for integrally receiving a sample, comprising a fixing base 1, a circular iron block 9, an annular sample disc body 13 and a heat conducting mechanism 15, wherein a circular chute 2 is formed inside the fixing base 1, two sliders 3 are mounted inside the circular chute 2, the top ends of the two sliders 3 are fixedly connected with a mounting plate 5 through a connecting bracket 4, the top end of the mounting plate 5 is connected with the circular iron block 9 through a mounting bolt and a thread, the middle part of the circular iron block 9 is provided with a mounting groove 10, the top end of the mounting plate 5 is fixedly connected with a gas suction disc body 12 through a mounting frame 11, the top end of the gas suction disc body 12 is connected with the annular sample disc body 13 in an adsorption manner, the top end of the circular iron block 9 is provided with the heat conducting mechanism 15, and the bottom end of the annular sample disc body 13 is fixed through the gas suction disc body 12, like this can be quick change and the installation annular sample dish body 13, improved the practicality and the convenience of device like this to through the circular spout 2 that sets up, when annular sample dish body 13 rotated like this, mounting panel 5 bottom linking bridge 4 was through slider 3 synchronous revolution in circular spout 2, improved annular sample dish body 13 like this and carried out the stability of rotation in-process.

The bottom of mounting panel 5 is passed through flange connection dish 6 and rotating electrical machines 7's output fixed connection, and rotating electrical machines 7 installs in the inside of install bin 8, and install on unable adjustment base 1's top for install bin 8, drives through the rotating electrical machines 7 that sets up and makes mounting panel 5 rotate, and the annular sample dish body 13 that mounting panel 5 carried out synchronous pneumatic suction cup body 12 and adsorbed the connection simultaneously rotates and carries out the detection of different reagents.

Heat-conducting mechanism 15 is including thermal-insulated casing 1501, graphite alkene installation piece 1502 and electric heating wire 1503, the top of circular iron plate 9 is provided with thermal-insulated casing 1501, the inside of thermal-insulated casing 1501 is provided with graphite alkene installation piece 1502, the lateral wall parcel of graphite alkene installation piece 1502 has electric heating wire 1503, heat-conducting mechanism 15 through setting up, the heat conduction effect is better like this and can the different standing grooves in the different annular sample dish body 13 of adaptation and the annular sample dish body 13, carry out heat conduction through electric heating wire 1503 and transmit for graphite alkene installation piece 1502, thereby graphite alkene installation piece 1502 accomplishes heat conduction with heat energy transfer for the reagent pipe of placing in spacing groove 1504.

Spacing groove 1504 has been seted up to graphite alkene installation piece 1502's inside, and spacing groove 1504 is the setting of inverted triangle formula structure, and the inside wall bonding of spacing groove 1504 is provided with heat preservation cotton 1505, and spacing groove 1504 is the setting of inverted triangle formula structure, can place unidimensional reagent pipe like this, and heat preservation cotton 1505 can reduce the heat energy loss of reagent pipe simultaneously.

The bottom of thermal-insulated casing 1501 is provided with magnetic path 14, thermal-insulated casing 1501 adsorbs through magnetic path 14 and circular iron plate 9's top and is connected, magnetic path 14 through setting up, heat conduction mechanism 15 can adsorb through the magnetic path 14 that thermal-insulated casing 1501 bottom set up and fix the top at circular iron plate 9 like this, be convenient for carry out different standing grooves in the different annular sample dish body 13 of adaptation and the annular sample dish body 13 like this, adsorb heat conduction transmission is carried out in the below of fixing the standing groove that different annular sample dish bodies 13 were seted up with heat conduction mechanism 15, the practicality and the convenience of device have been improved like this.

When in use, the annular sample disc body 13 to be used is firstly absorbed and fixed through the air suction disc body 12, secondly, the heat conducting mechanism 15 is adsorbed and fixed below the placing grooves arranged on different annular sample disc bodies 13 through the magnetic blocks 14 for heat conducting transmission, then the reagent tube is inserted into the placing groove arranged on the annular sample disc body 13 and is abutted and fixed with the limit groove 1504, thus, the graphene mounting block 1502 transfers heat energy to the reagent tube placed in the limiting groove 1504 to complete heat conduction, and finally the mounting plate 5 is driven to rotate by the arranged rotating motor 7, meanwhile, the mounting plate 5 rotates the annular sample disk body 13 which is connected with the synchronous pneumatic suction disk body 12 in an adsorption way to detect different reagents, the annular heat conducting structure matched with the annular sample disk and convenient for integrally receiving the sample is completed.

Example two

According to fig. 4, the present embodiment provides an annular heat conducting structure matched with an annular sample plate for integrally receiving a sample, and a non-slip pad 16 is adhered to the bottom end of the fixing base 1.

The inside wall bonding of installing box 8 is provided with soundproof cotton 17.

During the use, through the slipmat 16 that sets up, can improve the fixed effect of whole device through slipmat 16 like this, improve the stability of device to through the soundproof cotton 17 that sets up, can reduce the noise of the rotating electrical machines 7 of 8 internally mounted of install bin like this.

The foregoing shows and describes the general principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (8)

1. The utility model provides a be convenient for wholly accept annular heat conduction structure of sample with annular sample dish is supporting, includes unable adjustment base (1), circular iron plate (9), annular sample dish body (13) and heat conduction mechanism (15), its characterized in that: circular spout (2) have been seted up to the inside of unable adjustment base (1), the internally mounted of circular spout (2) has two sliders (3), linking bridge (4) fixedly connected with mounting panel (5) are all passed through on the top of two sliders (3), the top of mounting panel (5) has circular iron plate (9) through construction bolt threaded connection, mounting groove (10) have been seted up at the middle part of circular iron plate (9), mounting bracket (11) fixedly connected with gas suction cup body (12) are passed through on the top of mounting panel (5), the top of gas suction cup body (12) is adsorbed and is connected with annular sample dish body (13), the top of circular iron plate (9) is provided with heat conduction mechanism (15).

2. The annular heat conducting structure associated with an annular sample disk for integrally receiving a sample according to claim 1, wherein: the bottom end of the mounting plate (5) is fixedly connected with the output end of the rotating motor (7) through a flange connection plate (6).

3. The annular heat conducting structure associated with an annular sample disk for integrally receiving a sample according to claim 2, wherein: the rotating motor (7) is installed inside the installation box (8), and the installation box (8) is installed at the top end of the fixed base (1).

4. The annular heat conducting structure associated with an annular sample disk for integrally receiving a sample according to claim 1, wherein: the heat conducting mechanism (15) comprises a heat insulation shell (1501), a graphene installation block (1502) and an electric heating wire (1503), the heat insulation shell (1501) is arranged at the top end of the round iron block (9), the graphene installation block (1502) is arranged inside the heat insulation shell (1501), and the electric heating wire (1503) is wrapped on the outer side wall of the graphene installation block (1502).

5. The annular heat conducting structure associated with an annular sample disk for integrally receiving a sample according to claim 4, wherein: limiting grooves (1504) are formed in the graphene mounting blocks (1502).

6. The annular heat conducting structure associated with an annular sample disk for integrally receiving a sample according to claim 5, wherein: the limiting groove (1504) is arranged in an inverted triangle structure.

7. The annular heat conducting structure associated with an annular sample disk for integrally receiving a sample according to claim 5, wherein: the inner side wall of the limiting groove (1504) is provided with heat insulation cotton (1505) in an adhering mode.

8. The annular heat conducting structure associated with an annular sample disk for integrally receiving a sample according to claim 4, wherein: the bottom end of the heat insulation shell (1501) is provided with a magnetic block (14), and the heat insulation shell (1501) is connected with the top end of the round iron block (9) in an adsorption mode through the magnetic block (14).

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