KR20010000901A - Temperature Regulator for Fermenter - Google Patents

Abstract

PURPOSE: A temperature control device of a microorganism incubator is provided which does not use a refrigerant so, has neither inlet line nor outlet line thereof. Consequently, the incubator can be freely installed everywhere. CONSTITUTION: A temperature control device of microorganism incubator is characterized by comprising the followings; a heat transfer panel(2) which is adhered to the bottom of reaction container(1), a thermoelement(3a) for heating and a thermoelement(3b) for chilling which heat and chill the heat transfer panel(2) by supply of electric source, a heat sink(4) which is located at the bottom of the thermoelements(3a,3b), a fan(5) which is adhered to the bottom of the heat sink(4), a temperature sensor(6) which is installed at the inside of the reaction container(1).

Description

Temperature regulator of microbial incubator {Temperature Regulator for Fermenter}

The present invention relates to a temperature control device of the microbial incubator, and to a temperature control device of the microbial incubator used in the field of fermentation of microorganisms using the incubator, such as biological industry, medicine, microbial pesticides, chemicals, plant cell incubator. The present invention relates to a thermoelectric device for heating and cooling under the reactor for temperature control of the incubator, thereby facilitating temperature control of the reactor.

The microbial incubator must maintain a constant temperature in the reactor to provide conditions suitable for the culture of microorganisms and the like. Therefore, in order to raise the temperature in the reactor, heat is applied to the ring heater attached to the bottom of the reactor, and for cooling, the temperature of the reactor is controlled by lowering the temperature inside the reactor by providing a coolant around the ring heater.

As a method of providing a coolant for cooling the reactor, a structure as shown in FIG. 1 was used, which is a ring-heater 101 and a coolant circulation path through which a coolant is supplied to control a temperature at a lower end of the reactor 100. (101a) is provided, the ring heater 101 is installed at the lower end of the reaction tank 100 and is adapted to apply heat to the reaction tank 100 by supplying electricity.

In addition, the refrigerant circulation path 101a formed around the ring heater 101 is a place where coolant is supplied and circulated for temperature control, and the temperature inside the reactor 100 of the heating furnace of the ring heater 101 is more than necessary. When rising to the solenoid valve 105 to allow the refrigerant to be supplied to control the temperature in the reaction tank (100).

Cooling water is supplied to the condenser 120 through the tap water supply line 110 through the supply line 102, and the supplied water drops the temperature of the condenser 120 and then drains through the drain line 103. Will exit.

The refrigerant is continuously supplied to the refrigerant through the refrigerant supply line 102 and the drainage line 103 in order to function as a condenser, in which case a large amount of refrigerant is required.

The role of the condenser 120 plays a role of releasing water vapor generated during the cultivation, in which the microorganism in the culture of the water vapor is prevented from being mixed and released.

The inside of the condenser 120 is composed of a plurality of pipes, and when the cooling water coming from the supply line 102 passes through the pipe, condensed water is condensed by condensing water vapor. It serves to fall off.

In the conventional microbial incubator as described above, tap water is mostly used as a refrigerant, and the equipment of the incubator itself is complicated and occupies a large area by installing separate supply lines and drainage lines for supplying and draining the tap water. In addition, it was inconvenient to move the incubator, and the maintenance of the feeder and drainage lines was difficult because of the need for separation and reinstallation.

In particular, by continuously supplying and draining the refrigerant, waste of the refrigerant is severe and a separate drainage treatment facility is required. In addition, when water is used as a refrigerant, the temperature change of the water, which is a refrigerant, becomes severe according to the seasons, which adversely affects the temperature control of the reactor according to the seasons.

As such, when the reactor is cooled, a considerable amount of cooling water is required to continuously supply the cooling water, and in summer, a cooling time is required for a long time according to an increase in the surrounding temperature, and the incubator is not operated due to a decrease in the ambient temperature in the winter. In addition, the cooling water in the supply pipe must be removed to prevent freezing. In addition, the connection part is separated and the cooling water is ejected to the outside because the pressure of water cannot be overcome at the connection between the cooling plate of the incubator and the cooling line. This, in turn, has hindered the fermentation process, which is absolutely necessary to block external substances in culture.

The present invention has been made in order to solve the above problems of the conventional microbial incubator, the object of the present invention does not use a separate refrigerant, thereby removing the supply line and the discharge line for supply and discharge of the refrigerant It is possible to freely install the incubator, as well as to provide a temperature control device of the microbial incubator that is easy to maintain.

In order to achieve the above object, the present invention provides a heat transfer plate attached to a lower part of a microbial incubator reactor, a heating thermoelectric element for cooling or heating the heat transfer plate by contacting a lower part of the heat transfer plate and supplying power. A thermoelectric element, a heat dissipation plate disposed under the thermoelectric element, a fan attached to the lower portion of the heat dissipation plate, a temperature sensor installed in the reactor, and a temperature sensor to adjust the temperature inside the reactor. It includes a control circuit for controlling the driving of the thermoelectric element and the fan by a signal, the control circuit provides a temperature control device of the microbial incubator equipped with a control means for setting the temperature of the reaction tank to an arbitrary temperature.

1 is a cross-sectional view of a microbial incubator capable of achieving temperature control of a reaction tank by a conventional ring-heater and refrigerant (tap water) circulation;

Figure 2 is a cross-sectional view of the microbial incubator equipped with a temperature control apparatus according to the present invention,

3 is an exploded perspective view of the temperature control device according to the present invention.

* Explanation of symbols for main parts of the drawings

1: Reactor 2: Heat transfer plate

3a: heating element 3b: cooling element

4: heat sink 5: fan

6: temperature sensor

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view showing a microbial incubator equipped with a temperature control device according to the present invention, Figure 3 is an exploded perspective view showing a temperature cutting device of the microbial incubator according to the present invention.

As shown in the present invention for controlling the internal temperature of the microbial incubator reactor, the heat transfer plate (2) attached to the bottom of the reaction tank (1) of the incubator, and in contact with the lower portion of the heat transfer plate (2) The heat transfer plate 2 for heating or cooling the heat transfer plate 2 by the supply of the heat transfer element 3a and the heat transfer element 3b for cooling, and the heat dissipation plate 4 disposed below the thermoelectric elements 3a and 3b. ), A fan (5) attached to the bottom of the heat sink (4), and a temperature sensor (6) provided inside the reactor (1).

The temperature control device of the present invention controls the driving of the thermoelectric elements (3a) (3b) and the fan (5) by the signal sensed by the temperature sensor (6) in order to adjust the temperature inside the reactor (1) It includes a circuit, the control circuit is provided with a control means for setting the temperature of the reaction tank (1) to an arbitrary temperature, such a control circuit and temperature control means is a technique known in the art to which the present invention belongs Detailed description thereof will be omitted.

The heat generating thermoelectric element 3a and the cooling thermoelectric element 3b have the same structure, which is to be cooled and generated by switching the poles (+,-) of a DC power source. The element 3a attaches the surface of the heat generating portion to the heat transfer plate 2 to supply power, thereby heating the reactor 1, and the cooling thermoelectric element 3b attaches the surface of the heat absorbing portion to the heat transfer plate 2 to supply power. It is possible to lead the cooling of the reaction tank (1) by supplying, and the back surface of the cooling thermoelectric element (3b), that is, the surface of the heat generating portion is in contact with the heat sink (4) so that the rapid heat dissipation by the drive of the fan (5) Make it happen.

The thermoelectric elements 3a and 3b are generally cooled and heated within a temperature range of -30 ° C. to 150 ° C., and can be maintained at a constant temperature at all times without external influences. Microbial culture is possible.

In addition, in order to increase the thermal conductivity of the thermoelectric elements 3a and 3b, heat-dissipating grease is applied to both surfaces of the thermoelectric elements 3a and 3b to increase the heat transfer efficiency to the heat transfer plate 2 and the heat sink 4. To facilitate temperature control of the reaction tank (1).

When the temperature of the microorganism incubator reactor 1 is set to an arbitrary temperature in the temperature adjusting means of the control circuit, the present invention configured as described above inputs the value of the temperature sensor 6 installed in the reactor 1 in the control circuit. If the temperature is below the set temperature, the temperature of the reaction tank 1 is increased by applying power to the heat generating thermoelectric element 3a and heating it.

In addition, when the temperature inside the reaction tank 1 is equal to or higher than the set temperature, the power supplied to the heat generating thermoelectric element 3a is cut off, and the power supplied to the cooling thermoelectric element 3b is cooled to cool the temperature inside the reaction tank 1. It can be maintained at the set temperature.

As described above, the microorganism incubator temperature control device according to the present invention can control the microorganisms at low temperature, so that the microorganisms can be cultured at low temperature, thereby enabling a wider range of research and production. It is very economical because it can be used, and it can reduce the cost of tap water that has been used as a refrigerant while solving the difficulties caused by lack of water, and it does not need to have a separate cooling device for low temperature culture. It is possible to reduce the cost, to facilitate the convenience of researchers and producers, and when the user needs to move the existing incubator to another place, it is easy to move because the supply line and drainage line of the refrigerant are not connected. It has the advantage of easy maintenance.

Claims (3)

In controlling the internal temperature of the microorganism incubator reaction tank, A heat transfer plate 2 attached to the bottom of the reactor 1 and a heat transfer element for contacting the bottom of the heat transfer plate 2 and heating or cooling the heat transfer plate 2 by supply of power ( 3a) and a cooling thermoelectric element 3b, a heat dissipation plate 4 disposed under the thermoelectric elements 3a and 3b, a fan 5 attached to the lower part of the heat dissipation plate 4, and the reaction tank ( 1) Temperature control device of the microbial incubator, characterized in that it comprises a temperature sensor (6) installed inside. The method according to claim 1, The heat generating thermoelectric element 3a attaches the surface of the heat generating portion to the heat transfer plate 2, and the cooling thermoelectric element 3b attaches the surface of the heat absorbing portion to the heat transfer plate 2, and the cooling thermoelectric element 3b. The heating element surface of the) microorganism incubator temperature control device, characterized in that the contact with the heat sink (4). The method according to claim 1, The thermoelectric element (3a) (3b) is a temperature control device of the microbial incubator, characterized in that the heat-dissipating grease is applied to both surfaces thereof in contact with the heat transfer plate (2) and the heat sink (4).