CN116371252A - Microplate oscillation device - Google Patents

Abstract

The utility model discloses a micro-pore plate oscillation device, which belongs to the technical field of micro-pore plate oscillation and comprises: the box body, box body one side articulates there is the case lid, case lid one side fixedly connected with handrail, the box lower surface is provided with buffer assembly, the inside equidistance array backup pad of box, be provided with the baffle on the backup pad, baffle upper surface symmetry is provided with the second spring, fixed mounting has vibration platform on the second spring, fixed mounting has vibration motor under the vibration platform, the utility model is through having set up the radiator assembly, absorbs the heat that vibration motor produced through the heat absorption base, and the heat is absorbed by the water in the heat absorption base, flows into the fin through the wet return, carries out the heat exchange through fin and air, reduces the temperature of water, and the water that the temperature reduces is got back to in the first water tank again, is sent into the heat absorption base by first water pump and recycles, carries out continuous cooling to vibration motor, extension equipment's live time.

Description

Microplate oscillation device

Technical Field

The utility model relates to the technical field of microplate oscillation, in particular to a microplate oscillation device.

Background

Along with the continuous development of modern society and the continuous promotion of economic level, domestic bio-pharmaceuticals technology is also constantly developing, and in current bio-pharmaceuticals in-process, in order to accelerate the inside solution of test tube receiver and turbid liquid solid-liquid separation, often need be in the use of micropore board oscillator, produce the vibration to the test tube receiver of placing in its inside to make the inside solution of test tube receiver and turbid liquid solid-liquid separation, thereby the user of facilitating the use is treated the solid that detects and is taken a sample respectively.

Patent document CN201821678536.9 discloses a quick oscillator of micropore board, which comprises a supporting plate, the disinfect box is installed to the upper end of backup pad, the support is installed to the upper end of disinfect box, control panel has on the support, the cavity is installed to the upper end partial rear side of support, the motor is installed in the middle of the inside of cavity, vibrating platform is installed to the upper end of motor, the second recess has been seted up to vibrating platform's upper end, the spout has been seted up to the inside lateral wall of disinfect box, the internally mounted of disinfect box has the drawer, install the third handle on the drawer, install the camera in the middle of the inside side of top cap, the left and right sides symmetry of camera has the installing frame, the universal wheel is installed to the below of backup pad. The utility model solves the problems that the prior equipment has single function and the prior equipment can not observe the real-time condition in the oscillation cavity in real time by arranging the sterilizing box, the drawer, the camera and the control panel, and the micro-pore plate oscillator runs for a long time, so that the generated heat can not be evacuated in time and stays in the micro-pore plate oscillator equipment, the motor is short-circuited due to overhigh temperature, the normal operation of the micro-pore plate oscillator is influenced, the service life of the micro-pore plate oscillator is shortened, and the micro-pore plate can not be heated by the oscillator, so that a certain use deficiency exists.

Disclosure of Invention

1. Technical problem to be solved

Aiming at the problems in the prior art, the utility model aims to provide the micro-pore plate oscillating device which can radiate heat to the motor on the basis of realizing the oscillation of the micro-pore plate, prolong the service life of equipment, ensure the normal operation of the oscillator, heat the micro-pore plate through the heat of the motor, heat the micro-pore plate at constant temperature and reduce the service time.

2. Technical proposal

In order to solve the problems, the utility model adopts the following technical scheme:

a microplate oscillation device comprising: the box, box one side articulates there is the case lid, case lid one side fixedly connected with handrail, the box lower surface is provided with buffer assembly, the inside equidistance array backup pad of box, be provided with the baffle in the backup pad, baffle upper surface symmetry is provided with the second spring, fixed mounting has vibrating platform on the second spring, be provided with the spacing groove on the vibrating platform, fixed mounting has vibrating motor under the vibrating platform, be provided with radiator unit on the box, box surface symmetry is provided with the thermovent.

As a preferable scheme of the utility model, the box cover is provided with the observation openings, the box cover is symmetrically provided with the sliding grooves, the sliding grooves are connected with the light shielding plates in a sliding manner, and the light shielding plates are fixedly connected with the handles.

As a preferable scheme of the utility model, the buffer component comprises a positioning column, a sliding column, supporting legs and first springs, wherein the positioning column is symmetrically arranged on the lower surface of the box body, the sliding column is connected onto the positioning column in a sliding manner, one end of the sliding column is fixedly connected with the supporting legs, and the first springs are arranged on the sliding column.

As a preferable scheme of the utility model, the first spring is matched with the sliding column, and the supporting leg is provided with a fixing hole.

As a preferable scheme of the utility model, the heat radiation assembly comprises a first water tank, a communicating pipe, a first water pump, a third electromagnetic valve, a first water pipe and a heat absorption base, wherein the heat absorption base is arranged on the surface of the vibration motor, the first water tank is fixedly connected in the tank, the first water pump is fixedly arranged on the lower surface of the partition plate, the first water pump is fixedly communicated with the first water tank through the communicating pipe, the third electromagnetic valve is communicated with the water outlet of the first water pump, and the third electromagnetic valve is communicated with the heat absorption base through the first water pipe.

As a preferable scheme of the utility model, the heat radiation assembly further comprises a first electromagnetic valve, a water return pipe and heat radiation fins, wherein the water return pipe is fixedly communicated with the heat absorption base, the heat radiation fins are arranged on the water return pipe in an equidistant communication manner, and the first electromagnetic valve matched with the water return pipe is arranged on the heat absorption base.

As a preferred scheme of the utility model, the heat dissipation assembly further comprises a second water tank, a second water pump, a second water pipe, a one-way valve, a second electromagnetic valve, a second communicating pipe, a second water return pipe and a heating pipe, wherein the second water tank is fixedly installed on the partition plate, the second water pump is fixedly installed on one side of the second water tank, the second water pipe is communicated with the second water pump, the one-way valve is fixedly communicated with the second water pipe, the one-way valve is communicated with the heat absorption base, the second communicating pipe is fixedly communicated with one side of the heat absorption base, which is far away from the one-way valve, the second communicating pipe is provided with the second water return pipe, the second water return pipe is fixedly communicated with the vibration platform, the vibration platform is communicated with the second water tank through the second water return pipe, and the heating pipe is arranged in the second water tank.

As a preferable scheme of the utility model, the heat dissipation opening is matched with the heat dissipation fin, and the side of the heat absorption base, which is contacted with the limit groove, is provided with heat-conducting glue.

3. Advantageous effects

Compared with the prior art, the utility model has the advantages that:

1) According to the utility model, the heat radiating component is arranged, the heat generated by the vibration motor is absorbed through the heat absorbing base, the heat is absorbed by the water in the heat absorbing base, the heat flows into the cooling fins through the water return pipe, the temperature of the water is reduced through heat exchange between the cooling fins and the air, the water with the reduced temperature returns to the first water tank again, and is sent into the heat absorbing base by the first water pump to be recycled, so that the vibration motor is continuously cooled, and the service time of equipment is prolonged.

2) According to the utility model, the heat radiating component is arranged, the heat generated by the motor is absorbed into the water in the heat absorbing base through the heat absorbing base, the warm water in the heat absorbing base is sent into the vibration platform through the second water pump, and the micro-pore plate is heated through the vibration platform, so that the service time is shortened.

Drawings

FIG. 1 is a perspective view of a microplate oscillation device of the present utility model;

FIG. 2 is a perspective view of a buffer assembly of a microplate oscillation device in accordance with the present utility model;

FIG. 3 is a partial cross-sectional view of a microplate oscillation device in accordance with the present utility model;

FIG. 4 is a perspective view of a vibrating platform of a microplate oscillation device of the present utility model;

FIG. 5 is a perspective view of a heat dissipating assembly of a microplate oscillation device of the present utility model;

fig. 6 is a perspective view of a support plate of a microplate oscillation device in accordance with the present utility model.

The reference numerals in the figures illustrate:

1. a case; 2. a case cover; 3. an armrest; 4. an observation port; 5. a chute; 6. a light shielding plate; 7. a handle; 8. a heat radiation port; 9. a buffer assembly; 901. positioning columns; 902. a sliding column; 903. supporting feet; 904. a first spring; 10. a support plate; 11. a partition plate; 12. a second spring; 13. a vibration platform; 14. a limit groove; 15. a heat dissipation assembly; 1501. a first water tank; 1502. a communicating pipe; 1503. a first water pump; 1504. a third electromagnetic valve; 1505. a first water pipe; 1506. a heat absorbing base; 1507. a first electromagnetic valve; 1508. a water return pipe; 1509. a heat sink; 1510. a second water tank; 1511. a second water pump; 1512. a second water pipe; 1513. a one-way valve; 1514. a second electromagnetic valve; 1515. a second communicating pipe; 1516. a second return pipe; 1517. heating pipes; 16. and vibrating the motor.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the drawings in the embodiments of the present utility model. It is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments, and that all other embodiments obtained by persons of ordinary skill in the art without making creative efforts based on the embodiments in the present utility model are within the protection scope of the present utility model.

Referring to fig. 1-6, a microplate oscillation device comprising: the box 1, box 1 one side articulates there is case lid 2, case lid 2 one side fixedly connected with handrail 3, box 1 lower surface is provided with buffer assembly 9, the inside equidistance array backup pad 10 of box 1 is provided with baffle 11 on the backup pad 10, baffle 11 upper surface symmetry is provided with second spring 12, fixed mounting has vibration platform 13 on the second spring 12, be provided with spacing groove 14 on the vibration platform 13, fixed mounting has vibration motor 16 under the vibration platform 13, be provided with radiator unit 15 on the box 1, box 1 surface symmetry is provided with thermovent 8.

In the specific embodiment of the utility model, the heat dissipation component 15 is used for dissipating heat of the vibration motor 16, so that the service time of the equipment is prolonged, and the heat dissipation component 15 is used for heating the micro-pore plate, so that the experiment time is shortened, the efficiency is improved, and the use is convenient.

Specifically, an observation port 4 is formed in the box cover 2, sliding grooves 5 are symmetrically formed in the box cover 2, a light shielding plate 6 is connected in a sliding mode in the sliding grooves 5, and a handle 7 is fixedly connected to the light shielding plate 6.

In the embodiment of the utility model, the handle 7 drives the light shielding plate 6 to move, so that the observation port 4 can be opened and closed, and the interior of the box body 1 can be observed conveniently.

Specifically, the buffer assembly 9 includes a positioning column 901, a sliding column 902, a supporting leg 903 and a first spring 904, the positioning column 901 is symmetrically arranged on the lower surface of the box 1, the sliding column 902 is slidably connected to the positioning column 901, one end of the sliding column 902 is fixedly connected to the supporting leg 903, and the sliding column 902 is provided with the first spring 904.

In the embodiment of the utility model, the first spring 904 is extruded by the first spring 904 driving the sliding column 902 to stretch and contract, and the shock is absorbed by the first spring 904.

Specifically, the first spring 904 is disposed in a matching manner with the sliding post 902, and the supporting leg 903 is provided with a fixing hole.

In the embodiment of the present utility model, the vibration of the case 1 is absorbed by the first spring 904, thereby reducing the generation of noise.

Specifically, the heat dissipation assembly 15 includes a first water tank 1501, a communicating pipe 1502, a first water pump 1503, a third electromagnetic valve 1504, a first water pipe 1505 and a heat absorption base 1506, the surface of the vibration motor 16 is provided with the heat absorption base 1506, the first water tank 1501 is fixedly connected with the inside of the box 1, the first water pump 1503 is fixedly mounted on the lower surface of the partition plate 11, the first water pump 1503 is fixedly communicated with the first water tank 1501 through the communicating pipe 1502, a water outlet of the first water pump 1503 is communicated with the third electromagnetic valve 1504, and the third electromagnetic valve 1504 is communicated with the heat absorption base 1506 through the first water pipe 1505.

In the embodiment of the present utility model, the heat of the vibration motor 16 is absorbed by the heat absorbing base 1506, and the water after absorbing the heat flows into the heat sink 1509 for heat exchange and cooling, and then flows back into the first water tank 1501 for recycling.

Specifically, the heat dissipating assembly 15 further includes a first solenoid valve 1507, a water return pipe 1508 and a heat sink 1509, the water return pipe 1508 is fixedly connected to the heat absorbing base 1506, the heat sink 1509 is disposed on the water return pipe 1508 and is equidistantly connected to the heat absorbing base 1506, and the first solenoid valve 1507 is disposed on the heat absorbing base 1506 and is matched with the water return pipe 1508.

In an embodiment of the present utility model, the water in the first water tank 1501 is cooled by the heat sink 1509 and the pair of vibration motors 16 is cooled by the water.

Specifically, the heat dissipating assembly 15 further includes a second water tank 1510, a second water pump 1511, a second water pipe 1512, a check valve 1513, a second electromagnetic valve 1514, a second communicating pipe 1515, a second water return pipe 1516 and a heating pipe 1517, the second water tank 1510 is fixedly installed on the partition 11, the second water pump 1511 is fixedly installed on one side of the second water tank 1510, the second water pump 1511 is communicated with the second water pipe 1512, the check valve 1513 is fixedly communicated with the second water pipe 1512, the check valve 1513 is communicated with the heat absorbing base 1506, a second communicating pipe 1515 is fixedly communicated on one side of the heat absorbing base 1506 far away from the check valve 1513, the second communicating pipe 1515 is provided with the second water return pipe 1516, the second water return pipe 1516 is fixedly communicated with the vibration platform 13, the vibration platform 13 is communicated with the second water tank 1510 through the second water return pipe 1516, and the heating pipe 1517 is provided inside the second water tank 1510.

In the embodiment of the present utility model, a temperature controller matched with the heating pipe 1517 is disposed on the second water tank 1510, the second water pump 1511 sends the water in the second water tank 1510 into the heat absorbing base 1506, the water is heated by the heat absorbing base 1506, then sent into the vibration platform 13 through the second communicating pipe 1515, heated by the vibration platform 13, and then returned into the second water tank 1510 through the second water return pipe 1516.

Specifically, the heat dissipation opening 8 is arranged in a matching manner with the heat dissipation fin 1509, and the heat absorption base 1506 is provided with heat conducting glue on the contact side with the limit groove 14.

In an embodiment of the present utility model, the heat of the limiting groove 14 is quickly transferred to the heat absorbing base 1506 through the heat conductive adhesive.

Working principle: opening the case lid 2, putting the microplate into the limit groove 14, closing the case lid 2, determining that the vibration motor 16 vibrates the microplate, closing the third electromagnetic valve 1504 and the first electromagnetic valve 1507 when the temperature is low and heating the microplate, starting the second water pump 1511, feeding water in the second water tank 1510 into the heat absorption base 1506 through the second water pump 1511, heating the water through the heat absorption base 1506, flowing the heated water into the vibration platform 13 to heat the microplate, starting the heating pipe 1517 to heat the water in the second water tank 1510 in an auxiliary mode, and stopping when the temperature is heated to 37 ℃. When the air temperature is high, the third electromagnetic valve 1504 is closed, heat generated by the vibration motor 16 is absorbed through the heat absorption base 1506, the heat is absorbed by water in the heat absorption base 1506, the heat flows into the cooling fins 1509 through the water return pipe 1508, the heat exchange is carried out between the cooling fins 1509 and the air, the temperature of the water is reduced, the water with the reduced temperature returns to the first water tank 1501 again, the water is sent into the heat absorption base 1506 by the first water pump 1503 for recycling, the vibration motor 16 is continuously cooled, and the service life of equipment is prolonged.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical solution and the modified concept thereof, within the scope of the present utility model.

Claims (8)

1. A microplate oscillation device characterized by comprising: the novel vibrating box comprises a box body (1), wherein a box cover (2) is hinged to one side of the box body (1), a handrail (3) is fixedly connected to one side of the box cover (2), a buffer assembly (9) is arranged on the lower surface of the box body (1), a baffle plate (11) is arranged on the support plate (10), a second spring (12) is symmetrically arranged on the upper surface of the baffle plate (11), a vibrating platform (13) is fixedly arranged on the second spring (12), a limiting groove (14) is formed in the vibrating platform (13), a vibrating motor (16) is fixedly arranged under the vibrating platform (13), a heat radiating assembly (15) is arranged on the box body (1), and a heat radiating opening (8) is symmetrically arranged on the surface of the box body (1).

2. The micro-pore plate oscillation device according to claim 1, wherein the box cover (2) is provided with an observation opening (4), sliding grooves (5) are symmetrically formed in the box cover (2), a light shielding plate (6) is connected in the sliding grooves (5) in a sliding mode, and a handle (7) is fixedly connected to the light shielding plate (6).

3. The microplate oscillation device according to claim 1, wherein the buffer assembly (9) comprises a positioning column (901), a sliding column (902), supporting legs (903) and a first spring (904), the positioning column (901) is symmetrically arranged on the lower surface of the case body (1), the sliding column (902) is slidably connected to the positioning column (901), one end of the sliding column (902) is fixedly connected with the supporting legs (903), and the first spring (904) is arranged on the sliding column (902).

4. A microplate oscillation device according to claim 3, wherein the first spring (904) is arranged to match the sliding post (902), and the support leg (903) is provided with a fixing hole.

5. The micro-pore plate oscillation device according to claim 1, wherein the heat dissipation assembly (15) comprises a first water tank (1501), a communicating pipe (1502), a first water pump (1503), a third electromagnetic valve (1504), a first water pipe (1505) and a heat absorption base (1506), the heat absorption base (1506) is arranged on the surface of the vibration motor (16), the first water tank (1501) is fixedly connected to the inside of the box (1), the first water pump (1503) is fixedly arranged on the lower surface of the partition plate (11), the first water pump (1503) and the first water tank (1501) are fixedly communicated through the communicating pipe (1502), a third electromagnetic valve (1504) is communicated with the water outlet of the first water pump (1503), and the third electromagnetic valve (1504) is communicated with the heat absorption base (1506) through the first water pipe (1505).

6. The micro-plate oscillation device according to claim 5, wherein the heat dissipation assembly (15) further comprises a first electromagnetic valve (1507), a water return pipe (1508) and a heat dissipation fin (1509), the water return pipe (1508) is fixedly connected to the heat absorption base (1506), the heat dissipation fin (1509) is arranged on the water return pipe (1508) in an equidistant connection mode, and the first electromagnetic valve (1507) matched with the water return pipe (1508) is arranged on the heat absorption base (1506).

7. The microplate oscillating device according to claim 6, wherein the heat dissipating assembly (15) further comprises a second water tank (1510), a second water pump (1511), a second water pipe (1512), a check valve (1513), a second electromagnetic valve (1514), a second communication pipe (1515), a second water return pipe (1516) and a heating pipe (1517), the second water tank (1510) is fixedly mounted on the partition plate (11), the second water pump (1511) is fixedly mounted on one side of the second water tank (1510), the second water pump (1511) is communicated with a second water pipe (1512), the second water pipe (1512) is fixedly communicated with a check valve (1513), the check valve (1513) is communicated with a heat absorbing base (1506), the second communication pipe (1515) is fixedly communicated with one side of the heat absorbing base (1506), the second water return pipe (1516) is arranged on the second communication pipe (1515), the second water return pipe (1516) is fixedly communicated with the second water tank (15113), and the second water tank (1510) is fixedly communicated with the second water tank (1517) through the second communication pipe (1516).

8. The micro-pore plate oscillation device according to claim 7, wherein the heat dissipation opening (8) is arranged in a matching manner with the heat dissipation plate (1509), and the heat absorption base (1506) is provided with heat conducting glue on the contact side with the limit groove (14).

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