CN216106992U

CN216106992U - Micropore plate constant temperature oscillator

Info

Publication number: CN216106992U
Application number: CN202121965652.0U
Authority: CN
Inventors: 范翠; 葛浩; 匡聪
Original assignee: Yota Bio Engineering Co ltd
Current assignee: Yota Bio Engineering Co ltd
Priority date: 2021-08-20
Filing date: 2021-08-20
Publication date: 2022-03-22
Anticipated expiration: 2031-08-20

Abstract

The utility model belongs to the technical field of oscillators, and particularly relates to a microplate constant temperature oscillator which comprises a control base, an oscillator, a culture mechanism, a heat dissipation mechanism and a thermometer, wherein the heat dissipation mechanism consists of a signal receiver, a controller, a motor, a fan and a ventilation opening. This micropore board constant temperature oscillator, when cultivateing, be connected heating pipe and external power supply through the wiring end, the heating pipe sends out the heat after the circular telegram, the heat preservation wall can prevent the heat loss, when the thermometer detects out the inside cultivation high temperature of cultivateing the mechanism, can take place the signal of telecommunication to signal receiver, signal receiver receives behind the signal of telecommunication, the controller can the starter motor, the output shaft of motor drives the fan and rotates, send external air into the inside of cultivateing the mechanism through the air intake, carry out the heat exchange with inside air, prevent to cultivate the high temperature, lead to the effect variation of cultivateing, make the inside culture of culture dish cultivate under homothermal state, improve the cultivation effect.

Description

Micropore plate constant temperature oscillator

Technical Field

The utility model relates to the technical field of oscillators, in particular to a microporous plate constant temperature oscillator.

Background

The microporous plate constant temperature oscillator adopts a micro-processing technology combined with PID control, can be quickly kept stable after reaching a target temperature, can save waiting time to form the microporous plate constant temperature oscillator, and has compact and strict product design and small occupied space range.

The microplate constant temperature oscillator is mainly used for uniformly mixing solutions such as an enzyme label plate, a cell culture plate and the like or culturing and incubating cells at a proper temperature, and brings more freedom and convenience, low noise and no pollution; temperature, oscillation and time are displayed by an LCD, and the device has the characteristics of elegant appearance, simple operation and the like.

However, the conventional constant-temperature oscillation of the microporous plate does not have an overheat protection device, and when the internal temperature is too high, the power-off protection circuit cannot be timely powered off.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to a microplate constant temperature oscillator to solve the above problems in the background art.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a micropore board constant temperature oscillator, includes control base, oscillator, cultivates mechanism, heat dissipation mechanism and thermometer, oscillator fixed mounting in the top of control base, cultivates mechanism fixed mounting in the top center of oscillator, and heat dissipation mechanism fixed mounting is in the top left and right sides of oscillator, and thermometer fixed mounting is in the inside of cultivateing the mechanism.

The heat dissipation mechanism consists of a signal receiver, a controller, a motor, a fan and a ventilation opening, wherein the signal receiver is fixedly arranged at the top of the right side of the heat dissipation mechanism, the controller is fixedly arranged at the bottom of the signal receiver, the motor is fixedly arranged at the left side of the controller, the fan is rotatably connected to the output end of the motor, and the ventilation opening is arranged at the left side of the heat dissipation mechanism.

Preferably, signal receiver and thermometer signal connection, the controller respectively with signal receiver and motor electric connection, the vent extends to the outside of oscillator, when the thermometer detects out the inside cultivation high temperature of cultivateing the mechanism, can take place the signal of telecommunication to signal receiver, after signal receiver received the signal of telecommunication, the controller can the starter motor, the output shaft of motor drives the fan and rotates, sends into the inside of cultivateing the mechanism with external air through the vent, carries out the heat exchange with inside air.

Preferably, the culture mechanism comprises vibrating rod, culture solution box, micropore, culture dish and apron, and vibrating rod fixed connection is in the top center of oscillator, and culture dish fixed mounting is in the top of vibrating rod, and culture solution box fixed mounting is in the inside bottom of culture dish, and the micropore is seted up in the top of culture solution box, and the apron sets up in the top of culture dish.

Preferably, the top of micropore extends to the top of culture dish, and the apron passes through bolt threaded connection in the top left and right sides of culture dish, and the quantity of culture dish is six, and six culture dishes equidistant distribution are in the top of oscillator, when cultivateing, start the oscillator at the control base, and the oscillator is at the oscillating in-process, and the oscillating bar can be continuous to strike the culture solution box, and the inside culture solution of culture solution box can enter into inside the culture dish through the micropore.

Preferably, the back hinge of oscillator articulates there is heating mechanism, and the draw-in groove has been seted up to the left and right sides of oscillator, and the inside and the fixture block joint of draw-in groove.

Preferably, heating mechanism comprises case lid, heat preservation wall, wiring end, fixture block, recess and heating pipe, and the case lid passes through hinge rotation and connects in the back of oscillator, and heat preservation wall fixed mounting is in the inner wall of case lid, and wiring end fixed connection is in the right side of case lid, and fixture block fixed mounting is in the inside of heat preservation wall, and the recess is seted up in the side of case lid, and heating pipe fixed mounting is in the inside of case lid.

Preferably, wiring end and control base electric connection, heating pipe and wiring end electric connection, the fixture block joint is in the inside of draw-in groove, and the shape of recess is the same with heat dissipation mechanism, and after having placed the culture dish, press the case lid, the case lid passes through the hinge and is connected with the back rotation of oscillator, makes the fixture block joint in the inside of draw-in groove, makes heat dissipation mechanism joint inside the recess, when cultivateing, is connected heating pipe and external power supply through the wiring end, and the heating pipe sends the heat after the circular telegram.

Compared with the prior art, the utility model has the beneficial effects that:

1. this micropore board constant temperature oscillator, when the thermometer detects out the inside cultivation high temperature of mechanism of cultivateing, can take place the signal of telecommunication to signal receiver, after signal receiver received the signal of telecommunication, the controller can the starter motor, the output shaft of motor drives the fan and rotates, send into the inside of cultivateing the mechanism with external air through the vent, carry out the heat exchange with inside air, prevent to cultivate the high temperature, lead to the effect variation of cultivation, make the inside culture of culture dish cultivate under homothermal state, improve the cultivation effect.

2. This micropore board constant temperature oscillator, after placing the culture dish, presses the case lid, and the case lid passes through the hinge to be connected with the back rotation of oscillator, makes the fixture block joint in the inside of draw-in groove, makes heat dissipation mechanism joint inside the recess, when cultivateing, is connected heating pipe and external power source through the wiring end, and the heating pipe sends the heat after the circular telegram, and the heat preservation wall can prevent that the heat from running off, makes the inside cultivation temperature of mechanism of cultivateing rise very fast.

Drawings

FIG. 1 is a top view of the present invention;

FIG. 2 is a front view of a culture structure of the present invention;

FIG. 3 is a front view of the heating mechanism of the present invention;

fig. 4 is a schematic structural diagram of a heat dissipation mechanism according to the present invention.

In the figure: 1 control base, 2 oscillator, 3 culture mechanism, 301 oscillating rod, 302 culture solution box, 303 micropore, 304 culture dish, 305 cover plate, 4 heating mechanism, 401 case lid, 402 heat preservation wall, 403 terminal, 404 fixture block, 405 groove, 406 heating pipe, 5 heat dissipation mechanism, 501 signal receiver, 502 controller, 503 motor, 504 fan, 505 vent, 6 card slot, 7 thermometer.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: the utility model provides a micropore board constant temperature oscillator, including control base 1, oscillator 2, cultivate mechanism 3, heat dissipation mechanism 5 and

thermometer

7, 2 fixed mounting of oscillator in control base 1's top, cultivate 3 fixed mounting in the top center of oscillator 2 of mechanism, 5 fixed mounting in the top left and right sides of oscillator 2 of heat dissipation mechanism, thermometer 7 fixed mounting is in the inside of cultivateing mechanism 3, the back hinge of oscillator 2 articulates there is heating mechanism 4, draw-in groove 6 has been seted up to the left and right sides of oscillator 2.

The culture mechanism 3 comprises an oscillating rod 301, a culture solution box 302, micropores 303, culture dishes 304 and cover plates 305, wherein the oscillating rod 301 is fixedly connected to the center of the top of the oscillator 2, the culture dishes 304 are fixedly installed on the top of the oscillating rod 301, the culture solution box 302 is fixedly installed at the bottom inside the culture dishes 304, the micropores 303 are arranged on the top of the culture solution box 302, the cover plates 305 are arranged on the top of the culture dishes 304, the top of the micropores 303 extends to the top of the culture dishes 304, the cover plates 305 are connected to the left side and the right side of the top of the culture dishes 304 through bolts and threads, the number of the culture dishes 304 is six, the six culture dishes 304 are distributed on the top of the oscillator 2 at equal intervals, when in culture, the oscillator 2 is started by the control base 1, the oscillating rod 301 continuously impacts the culture solution box 302 in the oscillating process of the oscillator 2, the culture solution in the culture solution box 302 enters the culture dishes 304 through the micropores 303, the culture medium inside the culture dish 304 is better cultured, and the cover plate 305 can prevent the culture solution from overflowing during the shaking process.

The heating mechanism 4 comprises a case cover 401, a heat preservation wall 402, a terminal 403, a fixture block 404, a groove 405 and a heating pipe 406, the case cover 401 is rotatably connected to the back of the oscillator 2 through a hinge, the heat preservation wall 402 is fixedly installed on the inner wall of the case cover 401, the terminal 403 is fixedly connected to the right side of the case cover 401, the fixture block 404 is fixedly installed inside the heat preservation wall 402, the groove 405 is opened on the side surface of the case cover 401, the heating pipe 406 is fixedly installed inside the case cover 401, the terminal 403 is electrically connected with the control base 1, the heating pipe 406 is electrically connected with the terminal 403, the fixture block 404 is clamped inside the clamping groove 6, the shape of the groove 405 is the same as that of the heat dissipation mechanism 5, after the culture dish 304 is placed, the case cover 401 is pressed down, the case cover 401 is rotatably connected with the back of the oscillator 2 through a hinge, the fixture block 404 is clamped inside the clamping groove 6, the heat dissipation mechanism 5 is clamped inside the groove 405, during culture, the heating pipe 406 is connected with an external power supply through the terminal 403, the heating pipe 406 generates heat after being electrified, and the heat-insulating wall 402 can prevent heat loss, so that the culture temperature in the culture mechanism 3 can be increased quickly.

The heat dissipation mechanism 5 is composed of a signal receiver 501, a controller 502, a motor 503, a fan 504 and a vent 505, the signal receiver 501 is fixedly installed at the top of the right side of the heat dissipation mechanism 5, the controller 502 is fixedly installed at the bottom of the signal receiver 501, the motor 503 is fixedly installed at the left side of the controller 502, the fan 504 is rotatably connected to the output end of the motor 503, the vent 505 is opened at the left side of the heat dissipation mechanism 5, the signal receiver 501 is in signal connection with a thermometer 7, the controller 502 is respectively in electrical connection with the signal receiver 501 and the motor 503, the vent 505 extends to the outside of the oscillator 2, when the thermometer 7 detects that the culture temperature inside the culture mechanism 3 is too high, an electric signal is generated to the signal receiver 501, after the signal receiver 501 receives the electric signal, the controller 502 starts the motor 503, the output shaft of the motor 503 drives the fan 504 to rotate, and outside air is sent into the culture mechanism 3 through the air inlet 505, heat exchange with the air inside, so as to prevent the culture temperature from being too high, which leads to the deterioration of the culture effect, and the culture in the culture dish 304 is cultured in a constant temperature state, thereby improving the culture effect.

When the culture dish is used, after the culture dish 304 is placed, the box cover 401 is pressed down, the box cover 401 is rotatably connected with the back of the oscillator 2 through a hinge, the clamping block 404 is clamped inside the clamping groove 6, the heat dissipation mechanism 5 is clamped inside the groove 405, when the culture is carried out, the heating pipe 406 is connected with an external power supply through the terminal 403, the heating pipe 406 generates heat after being electrified, the oscillator 2 is started up by the control base 1, the oscillating rod 301 continuously impacts the culture solution box 302 in the oscillating process of the oscillator 2, the culture solution in the culture solution box 302 enters the culture dish 304 through the micropores 303, when the temperature gauge 7 detects that the culture temperature in the culture mechanism 3 is too high, an electric signal is generated to the signal receiver 501, after the signal receiver 501 receives the electric signal, the controller 502 starts the motor 503, the output shaft of the motor 503 drives the fan 504 to rotate, and the external air is sent into the culture mechanism 3 through the vent 505, heat exchange with the air inside.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments 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

1. The utility model provides a micropore board constant temperature oscillator, includes control base (1), oscillator (2), cultivates mechanism (3), heat dissipation mechanism (5) and thermometer (7), its characterized in that: the oscillator (2) is fixedly arranged at the top of the control base (1), the culture mechanism (3) is fixedly arranged at the center of the top of the oscillator (2), the heat dissipation mechanisms (5) are fixedly arranged at the left side and the right side of the top of the oscillator (2), and the thermometer (7) is fixedly arranged in the culture mechanism (3);

heat dissipation mechanism (5) comprises signal receiver (501), controller (502), motor (503), fan (504) and vent (505), signal receiver (501) fixed mounting is in the right side top of heat dissipation mechanism (5), controller (502) fixed mounting is in the bottom of signal receiver (501), motor (503) fixed mounting is in the left side of controller (502), fan (504) rotate the output of connecting in motor (503), the left side in heat dissipation mechanism (5) is seted up in vent (505).

2. The microplate thermostatic oscillator of claim 1, wherein: the signal receiver (501) is in signal connection with the thermometer (7), the controller (502) is respectively in electrical connection with the signal receiver (501) and the motor (503), and the ventilation opening (505) extends to the outside of the oscillator (2).

3. The microplate thermostatic oscillator of claim 1, wherein: cultivate mechanism (3) and constitute by rocking bar (301), culture solution box (302), micropore (303), culture dish (304) and apron (305), rocking bar (301) fixed connection is in the top center of oscillator (2), culture dish (304) fixed mounting is in the top of rocking bar (301), culture solution box (302) fixed mounting is in the inside bottom of culture dish (304), the top of culture solution box (302) is seted up in micropore (303), apron (305) set up in the top of culture dish (304).

4. The microplate thermostatic oscillator of claim 3, wherein: the top of micropore (303) extends to the top of culture dish (304), apron (305) pass through bolt threaded connection in the top left and right sides of culture dish (304), the quantity of culture dish (304) is six, six culture dish (304) equidistant distribution is in the top of oscillator (2).

5. The microplate thermostatic oscillator of claim 1, wherein: the back hinge of oscillator (2) articulates there is heating mechanism (4), draw-in groove (6) have been seted up to the left and right sides of oscillator (2).

6. The microplate thermostatic oscillator of claim 5, wherein: heating mechanism (4) comprises case lid (401), heat preservation wall (402), wiring end (403), fixture block (404), recess (405) and heating pipe (406), case lid (401) rotates through the hinge and connects in the back of oscillator (2), heat preservation wall (402) fixed mounting is in the inner wall of case lid (401), wiring end (403) fixed connection is in the right side of case lid (401), fixture block (404) fixed mounting is in the inside of heat preservation wall (402), recess (405) are seted up in the side of case lid (401), heating pipe (406) fixed mounting is in the inside of case lid (401).

7. The microplate thermostatic oscillator of claim 6, wherein: the terminal (403) is electrically connected with the control base (1), the heating pipe (406) is electrically connected with the terminal (403), the clamping block (404) is clamped in the clamping groove (6), and the shape of the groove (405) is the same as that of the heat dissipation mechanism (5).