CN212610626U - Energy-conserving biological bacterial constant temperature equipment of high efficiency - Google Patents

Abstract

The utility model discloses an energy-conserving biological bacterial constant temperature equipment of high efficiency belongs to biological bacterial constant temperature equipment technical field, including the thermostated container, the division board has been welded in the thermostated container, constitute cultivation room an between thermostated container and the division board, cultivation room an left side can be dismantled and be connected with chamber door an, it has phenolic foam a to bond in the cultivation room a, phenolic foam a fixedly connected with water jacket layer an, water jacket layer an internal surface bonds and has heating tape an and heating tape an to have two, temperature sensor an is installed to cultivation room an bottom, constitute cultivation room b between division board and the thermostated container. The phenolic foam in the cultivation room is matched with the water jacket layer to carry out heat preservation on the cultivation room, the heat preservation effect is good, the electrifying time of a heating belt can be reduced, and the electric energy is saved; the incubator is divided into an incubation chamber a and an incubation chamber b, heating belts and heat preservation structures are arranged between the incubation chambers, so that strains with different required temperatures can be incubated at constant temperatures, and the incubation efficiency is high.

Description

Energy-conserving biological bacterial constant temperature equipment of high efficiency

Technical Field

The utility model relates to a biological bacterial constant temperature equipment technical field especially relates to an energy-conserving biological bacterial constant temperature equipment of high efficiency.

Background

The strain is used as microorganism of live cell catalyst in fermentation process, including bacteria, actinomycetes, yeast and mould. A culture box for biological bacterial is a widely used apparatus in the fields of microbiology, biomedicine, gene recombination and biological products for scientific research, teaching and production.

The patent No. CN 208917199U discloses a constant temperature breeding device for biological strains, which adopts a camera device to record and observe the conditions in a culture dish in the constant temperature breeding device, so that the growth conditions of the biological strains can be known more clearly and comprehensively, and more accurate observation data can be provided; a temperature sensor is adopted to detect the temperature in the box in real time, and a heater is controlled to stop heating, so that the overhigh temperature is prevented; the constant-temperature breeding device can be remotely controlled by adopting a remote controller.

The biological strain constant temperature device in the prior art has the following defects: 1. the temperature in the constant temperature box needs to be constantly heated to keep constant, the heat preservation effect of the constant temperature box is poor, the heat dissipation block and the heating element are started for multiple times in a short time to heat the constant temperature box, and the energy consumption is high; 2. the existing thermostat heating element heats the whole thermostat, the thermostat can only keep one temperature unchanged, two strains with different required temperatures cannot be cultivated at constant temperature, and the use is inconvenient.

SUMMERY OF THE UTILITY MODEL

The utility model provides a high-efficiency energy-saving biological strain constant temperature device, which can keep the temperature of a culture room by matching phenolic foam in the culture room with a water jacket layer, has good heat preservation effect, can reduce the power-on time of a heating belt and saves electric energy; the incubator is divided into an incubation chamber a and an incubation chamber b, heating belts and heat preservation structures are arranged between the incubation chambers, so that strains with different required temperatures can be incubated at constant temperatures, and the incubation efficiency is high.

The utility model provides a specific technical scheme as follows:

the utility model provides a high-efficiency energy-saving biological strain constant temperature device, which comprises a constant temperature box, a division plate is welded in the constant temperature box, a culture room a is formed between the constant temperature box and the division plate, the left side of the culture room a is detachably connected with a box door a, phenolic foam a is bonded in the culture room a, the phenolic foam a is fixedly connected with a water jacket layer a, a heating belt a and two heating belts a are bonded on the inner surface of the water jacket layer a, a temperature sensor a is installed at the bottom of the culture room a, a culture room b is formed between the division plate and the constant temperature box, a box door b is connected in a gap at the left side of the culture room b, phenolic foam b is bonded in the culture room b, the phenolic foam b is fixedly connected with a water jacket layer b, a heating belt b and two heating belts b are bonded on the inner surface of the water jacket layer b, a temperature sensor b is installed at the bottom of the culture room b, and the middle parts of the box door a and the box door b are provided with observation windows.

Optionally, the box door a extends outwards to form a clamping edge, and a sealing ring is bonded to the surface of the clamping edge.

Optionally, two sides in the cultivation room a are fixedly connected with a fixing frame a, and the fixing frame a is connected with a supporting plate a in a sliding manner.

Optionally, two sides in the cultivation room b are fixedly connected with a fixing frame b, and the fixing frame b is connected with a supporting plate b in a sliding mode.

Optionally, the current input ends of the heating band a, the temperature sensor b and the heating band b are electrically connected with an external power supply through a lead.

The utility model has the advantages as follows:

the embodiment of the utility model provides an energy-conserving biological bacterial constant temperature equipment of high efficiency:

1. the phenolic foam in the cultivation room is matched with the water jacket layer to carry out heat preservation on the cultivation room, the heat preservation effect is good, the electrifying time of a heating belt can be reduced, and the electric energy is saved; the inner surfaces of the cultivation room a and the cultivation room b are respectively bonded with phenolic foam a and phenolic foam b, the phenolic foam a and the phenolic foam b are fixedly connected with a water jacket layer a and a water jacket layer b, a heating belt a and a heating belt b are respectively arranged in the cultivation room a and the cultivation room b, the heating belt is electrified to emit heat, the heat emitted by the heating belt is transferred to the air of the cultivation room and absorbed by the air, the water jacket layer connected with the heating belt absorbs the heat, the temperature of the water in the water jacket layer rises after the heat is absorbed, the heating belt is continuously electrified to heat the cultivation room until the temperature reaches the required constant temperature, at the moment, the heating belt is powered off, the water jacket layer is contacted with the phenolic foam, the phenolic foam has a uniform closed-cell structure, the heat conductivity coefficient is low, the heat insulation performance is good, the heat dissipation can be kept in the cultivation room, the heat in the air is gradually dissipated, the water temperature of the water in the water jacket layer is slightly high, the indoor air of cultivating is heated to the heat that outwards gives off, and water jacket layer and phenolic foam cooperation can keep warm and keep warm effectually to cultivating indoor, and the heating tape start-up time is short, consumes electric power low.

2. The incubator is divided into an incubation chamber a and an incubation chamber b, heating belts and heat insulation structures are arranged between the incubation chambers, so that strains with different required temperatures can be incubated at constant temperature, and the incubation efficiency is high; the incubator is divided into two parts by a partition board in the incubator, the upper part is an incubation chamber a, the lower part is an incubation chamber b, phenolic foam and a water jacket layer are arranged in the incubation chamber a and the incubation chamber b for heat preservation, a heating belt a is adhered in the incubation chamber a, a heating belt b is adhered in the incubation chamber b, the heating belt a and the heating belt b are respectively controlled, the heating belt a can be controlled to be electrified according to needs to heat the incubation chamber a to a certain constant temperature to cultivate strains in the incubation chamber a, the controller controls the heating belt b to be electrified to heat the incubation chamber b to another constant temperature to cultivate strains in the incubation chamber b, strains with different temperatures or different strains can be cultivated in the incubator at the same time, and the cultivation efficiency is high.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic view of the overall structure of a high-efficiency energy-saving constant temperature device for biological bacteria according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an incubation chamber of a high-efficiency energy-saving biological strain constant temperature device according to an embodiment of the present invention.

In the figure: 1. a box door a; 2. an observation window; 3. a box door b; 4. a thermostat; 5. an incubation chamber a; 6. phenolic foam a; 7. a water jacket layer a; 8. heating the belt a; 9. a supporting plate a; 10. a fixed frame a; 11. a temperature sensor a; 12. a partition plate; 13. an incubation chamber b; 14. phenolic foam b; 15. a fixed frame b; 16. a supporting plate b; 17. a water jacket layer b; 18. a temperature sensor b; 19. a heating belt b; 20. edge clamping; 21. and (5) sealing rings.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the present invention will be described in further detail with reference to the accompanying drawings, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

The high-efficiency energy-saving biological strain constant temperature device according to the embodiment of the present invention will be described in detail with reference to fig. 1 to 2.

Referring to fig. 1-2, a high-efficiency energy-saving constant temperature device for biological bacteria, provided by an embodiment of the present invention, includes an incubator 4, a partition plate 12 is welded in the incubator 4, an incubation chamber a5 is formed between the incubator 4 and the partition plate 12, a door a1 is detachably connected to the left side of the incubation chamber a5, a phenolic foam a6 is adhered in the incubation chamber a5, a water jacket layer a7 is fixedly connected to the phenolic foam a6, a heating tape a8 and two heating tapes a8 are adhered on the inner surface of the water jacket layer a7, a temperature sensor a11 is installed at the bottom of the incubation chamber a5, an incubation chamber b13 is formed between the partition plate 12 and the incubator 4, a door 37b 84 is connected to the left side of the incubation chamber b13 in a gap manner, a phenolic foam b14 is adhered in the incubation chamber b13, a water jacket layer 14 is fixedly connected to the water jacket layer 17, a heating tape b19 and two heating tapes 57324 b19 b 57323 are adhered on the inner surface of the water jacket b 365, the bottom of the incubator chamber b13 is provided with a temperature sensor b18, and the middle parts of the box door a1 and the box door b3 are both provided with an observation window 2.

Illustratively, the incubator 4 includes an incubation chamber a5, a partition plate 12 and an incubation chamber b13, the partition plate 12 is welded in the middle of the incubator 4 to divide the incubator 4, the incubation chamber a5 includes a phenolic foam a6, a water jacket layer a7, a heating tape a8, a fixing frame a10 and a supporting plate a9, the heating tape a8 is adhered to the inner surface of the incubation chamber a5, the incubation chamber b13 includes a phenolic foam b14, a water jacket layer b17, a heating tape b19, a fixing frame b15 and a supporting plate b16, and the strains incubated in the incubation chamber a5 and the incubation chamber b13 can be observed through an observation window 2 formed in a door 1 and a door b 3.

Referring to fig. 1, the door a1 has a bead 20 extending outward, and a sealing ring 21 is adhered to the surface of the bead 20.

Illustratively, the card edge 20 is clamped into the incubation chamber, and the sealing ring 21 adhered to the surface of the card edge 20 is in contact with the surface of the incubation chamber for sealing, i.e. the sealing between the box door and the incubation chamber can prevent the culture dish from being polluted by the outside.

Referring to fig. 1, a fixing frame a10 is fixedly connected to two sides in the incubation chamber a5, and a supporting plate a9 is slidably connected to the fixing frame a 10.

For example, the fixed frame a10 is fixed on both sides of the incubation chamber a5, and can provide a mounting platform for the pallet a9, and the pallet a9 slides into the incubation chamber a5 along the sliding groove of the fixed frame a10 to be fixed.

Referring to fig. 1, a fixing frame b15 is fixedly connected to two sides in the cultivation chamber b13, and a supporting plate b16 is slidably connected to the fixing frame b 15.

Illustratively, the holders b15 are fixed on both sides of the incubation chamber b13, and can provide a mounting platform for the pallet b16, and the pallet b16 slides along the slide grooves on the holders b15 into the incubation chamber b 13.

Referring to fig. 1, the current input terminals of the heating tape a8, the temperature sensor a11, the temperature sensor b18 and the heating tape b19 are electrically connected with an external power supply through wires.

For example, when a plug is inserted into the socket, the external power supply supplies power to the heating belt a8, the temperature sensor a11, the temperature sensor b18 and the heating belt b 19.

When the device is used, an external power supply supplies power, a starting button is pressed, phenolic foam a6 and phenolic foam b14 are adhered to the inner surfaces of the incubation chamber a5 and the incubation chamber b13 respectively, a water jacket layer a7 and a water jacket layer b17 are fixedly connected to the phenolic foam a6 and the phenolic foam b14 respectively, a heating belt a8 and a heating belt b19 are installed in the incubation chamber a5 and the incubation chamber b13 respectively, and after the heating belts are connected with the power supply, current flows from one wire core to the other wire core through a conductive PTC material to form a loop. The electric energy heats the conductive material, the resistance of the conductive material is increased immediately, when the temperature of the core belt rises to a certain value, the resistance is large to the degree of almost blocking current, the temperature of the core belt does not rise any more, meanwhile, the heat emitted by the heating belt is transferred to the air of the cultivation room and absorbed by the air, meanwhile, the water jacket layer connected with the heating belt absorbs the heat, the temperature rises after the water in the water jacket layer absorbs the heat, the heating belt is continuously electrified to heat the cultivation room until the temperature reaches the required constant temperature, at the moment, the heating belt is powered off, the water jacket layer is contacted with the phenolic foam, the phenolic foam has a uniform closed-cell structure, the heat conduction coefficient is low, the heat insulation performance is good, the cultivation room can be insulated, the heat dissipation of the heat is reduced, the heat in the air is gradually dissipated in the heat insulation process, the water temperature of the water in the water jacket layer is slightly higher, the heat is dissipated outwards to heat the air in the cultivation room, the, the incubator 4 is divided into two parts by a partition plate 12, the upper part is an incubation chamber a5, the lower part is an incubation chamber b13, the incubation chamber a5 and the incubation chamber b13 are both provided with phenolic foam and a water jacket layer for heat preservation, a heating belt a8 is adhered in the incubation chamber a5, a heating belt b19 is adhered in the incubation chamber b13, the heating belt a8 and the heating belt b19 are respectively controlled, the heating belt a8 can be controlled to be electrified according to requirements to heat the incubation chamber a5 to a certain constant temperature for culturing strains in the incubation chamber a5, a box door a1 is opened, the strains to be cultured are put on an inner supporting plate a9 of the incubation chamber a5, the box door a1 is closed after the arrangement, a temperature sensor a11 in the incubation chamber a5 is electrified (two conductors made of different materials are mutually connected at a certain point, the connecting point is heated, the potential difference is generated at the non-heated position, and the potential difference is measured again, the temperature of the heating point can be accurately known) to measure the temperature in the incubation chamber a5, when the temperature is lower than the set value, the control panel controls the heating belt a8 to be electrified to heat the incubation chamber a5, the controller controls the heating belt b19 to be electrified to heat the incubation chamber b13 to another constant temperature to cultivate the strains in the incubation chamber b13, the box door b3 is opened, the other strain to be cultivated is put on the supporting plate b16 in the incubation chamber b13, then the box door b3 is closed to cultivate the strains, the temperature sensor b18 in the incubation chamber b13 measures the temperature in the incubation chamber b13, and the box door a1 and the box door b3 are opened to take out the strains after the cultivation.

It should be noted that the utility model relates to an energy-conserving biological bacterial constant temperature equipment of high efficiency, including heat band a8 (heat band a8 model is DXW), temperature sensor a11 (temperature sensor a11 model is WZP-035), temperature sensor b18 (temperature sensor b18 model is WZP-035) and heat band b19 (heat band b19 model is DXW), above-mentioned electrical components are prior art products, by the needs of using, select, install and accomplish the debugging operation of circuit, ensure that each electrical apparatus can normal work, the part is general standard component or the part that technical staff in the field knows, its structure and principle all can learn through the technical manual or learn through conventional experimental method for this technical staff.

It is apparent that those skilled in the art can make various changes and modifications to the embodiments of the present invention without departing from the spirit and scope of the embodiments of the present invention. Thus, if such modifications and variations of the embodiments of the present invention fall within the scope of the claims and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (5)

1. The utility model provides an energy-conserving biological bacterial constant temperature equipment of high efficiency, includes thermostated container (4), its characterized in that, division board (12) have been welded in thermostated container (4), constitute between thermostated container (4) and division board (12) and cultivate room a (5), it is connected with chamber door a (1) to dismantle in cultivate room a (5) left side, it has phenolic foam a (6) to bond in cultivate room a (5), phenolic foam a (6) fixedly connected with water jacket layer a (7), water jacket layer a (7) internal surface bonds has heating tape a (8) and heating tape a (8) to have two, temperature sensor a (11) are installed to cultivate room a (5) bottom, constitute between division board (12) and thermostated container (4) and cultivate room b (13), it has chamber door b (3) to cultivate room b (13) left side gap connection, there is phenolic foam b (14) in cultivate room b (13), phenolic foam b (14) fixedly connected with water jacket layer b (17), water jacket layer b (17) internal surface bonds has heating band b (19) and heating band b (19) to have two, temperature sensor b (18) are installed to cultivation room b (13) bottom, observation window (2) have all been seted up in chamber door a (1) and chamber door b (3) middle part.

2. The high-efficiency energy-saving biological strain thermostatic device is characterized in that a clamping edge (20) extends outwards from the box door a (1), and a sealing ring (21) is bonded on the surface of the clamping edge (20).

3. The high-efficiency energy-saving biological strain constant-temperature device as claimed in claim 1, wherein a fixing frame a (10) is fixedly connected to two sides in the cultivation room a (5), and a supporting plate a (9) is slidably connected to the fixing frame a (10).

4. The high-efficiency energy-saving biological strain constant-temperature device as claimed in claim 1, wherein a fixing frame b (15) is fixedly connected to two sides in the cultivation room b (13), and a supporting plate b (16) is slidably connected to the fixing frame b (15).

5. The high-efficiency energy-saving biological strain thermostatic device according to claim 1, wherein the current input ends of the heating belt a (8), the temperature sensor a (11), the temperature sensor b (18) and the heating belt b (19) are electrically connected with an external power supply through leads.

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