JPS6128569Y2 - - Google Patents

Description

[Detailed description of the invention] This invention relates to an animal fertilized egg freezing device used for cryopreserving fertilized eggs and embryos (hereinafter referred to as fertilized eggs) of cows, horses, sheep, goats, pigs, mice, etc.

Fertilized egg transplantation technology for improving and multiplying livestock is currently being put into practical use in earnest, and there is a desire to establish technology for cryopreservation of fertilized eggs. Conventional equipment for freezing fertilized eggs uses liquefied nitrogen (LN ₂ ) as the cold source, places a straw or ampoule containing the fertilized eggs and freezing preservation solution in the freezing chamber, and pumps a predetermined amount of LN from the LN ₂ tank into the freezing chamber. There is a known method that cools the fertilized eggs by intermittently blowing out LN ₂ gas using a solenoid valve, and freezes the fertilized eggs at a predetermined cooling rate.

However, since such freezing equipment uses _LN2 as the cold source, it requires large size.
An LN ₂ storage container was essential, making the entire device large and inconvenient to transport. In addition, LN ₂ is often not readily available at all times, especially in mountainous or remote areas, where it is difficult to replenish LN ₂ , and it has the disadvantage that it cannot be easily used in gardens such as ranches.

This idea was made in view of the above circumstances,
The object of the present invention is to provide an animal fertilized egg freezing device that can be extremely miniaturized and can be easily used anywhere without using LN ₂ .

This invention will be explained in detail below with reference to the drawings.

FIGS. 1 and 2 show an example of the main parts of the freezing device of this invention, and the reference numeral 1 in the figures is a freezing tank. The freezing tank 1 is a container made of metal with good thermal conductivity, such as steel or aluminum, and in this example is a rectangular cylindrical steel container. This freezing tank 1 is filled with a refrigerant C, such as alcohol or freon, which does not solidify even at -50°C to -80°C, for cooling and freezing animal fertilized eggs. In one of the freezing tanks 1, the cooling side of a plate-shaped first thermomodule 2 made of an electronic refrigeration element that generates cold heat by utilizing the Bertier effect is closely joined to the side wall 1a. One side of a heat transfer plate 3 made of a thick steel plate is bonded to the heating side of the first thermomodule 2 in close contact therewith. Furthermore, the cooling side of a similar second thermomodule 4 is joined to the opposite side surface of the heat exchanger plate 3 in close contact therewith. Furthermore, the second thermo module 4
A heat transfer plate 5 made of a thick steel plate is attached to the heating side of the
is joined on one side. Further, the cooling side of the third thermomodule 6 is joined to the opposite side surface of the heat exchanger plate 5 in close contact therewith. A water cooling plate 7 made of aluminum is provided on the heating side of the third thermomodule 6 in close contact therewith. Cooling water is fed into the water cooling plate 7 from a cooling water inlet 7a, cools the heating side of the third thermomodule 6, and is then led out from a cooling water outlet 7b. The first, second, and third thermomodules 2, 4, and 6 are connected to a DC constant voltage power source (not shown), and the first thermomodule 2 cools the freezing tank 1 and transfers this heat to the heat transfer plate 3. The second thermomodule 4 cools the heat exchanger plate 3 and transfers this heat to the heat exchanger plate 5. Furthermore, the third thermomodule 6 cools the heat exchanger plate 5 and transfers this heat to the water cooling plate 7. tell the
As a result, the refrigerant C in the freezing tank 1 is cooled. Further, a heating heater 8 is attached to the other wall surface 1b of the freezing tank 1 in close contact therewith. These freezing tank 1, first, second and third thermo modules 2, 4, 6, heat exchanger plates 3, 5,
The main body of the apparatus, which consists of a water cooling plate 7 and a heating heater 8, is wrapped in a heat insulating material J such as styrofoam, as shown by the dashed line in FIG. 1, and is thermally insulated from the outside.

FIG. 2 shows the ice plate of the freezing device of this invention. This ice-planting plate 9 includes an ice-planting plate main body 10 made of a metal with good thermal conductivity such as steel or aluminum, a fourth thermomodule 11 for cooling the ice-planting plate main body 10, and a fourth thermomodule 11. A fifth thermomodule 13 to be cooled, a heat transfer plate 12 made of a thick steel plate joined between the fourth thermomodule 11 and the fifth thermomodule 13, and the fifth thermomodule 13.
It consists of a water cooling plate 14 that cools the thermo module 13. The ice-planting plate main body 10 includes a square cooling plate portion 10a to which the fourth thermomodule 11 is closely attached, a heat transfer plate portion 10b extending downward from the cooling plate portion 10a, and a fertilized egg and a frozen egg. The holder part 10c holds an ampoule or straw 15 containing a storage solution and transmits cold heat to the ampoule or straw 15.
This holder part 10c is a member having a comb-shaped cross section, in which a plurality of grooves 10d for accommodating straws or ampoules are formed in the vertical direction on both sides of a slightly thick plate material, and is located below the heat transfer plate part 10b. It was formed integrally with this. And the fourth above,
By applying direct current from a DC constant voltage power source (not shown) to the thermomodules 11 and 13, the cooling plate section 10a is cooled, and this cold heat passes through the heat transfer plate section 10b and the holder section 10c.
The cold heat is transmitted to the straw 15 or ampoule held in the holder part 10c, and the cryopreservation solution in the straw 15 or ampoule is cooled, so that the cryopreservation solution is not given to the fertilized eggs during freezing. Ice nuclei are formed in the liquid (planted ice).

Next, a method for freezing fertilized eggs and the like using such a freezing device will be explained with reference to FIGS. 3 and 4. First, as shown in FIG.
... is immersed in refrigerant C in freezing tank 1. The freezing tank 1 is placed on a magnetic stirrer 16, and the refrigerant in the tank 1 is stirred by a rotor 17 inserted into the tank 1. Next, the first, second, third, fourth, and fifth thermomodules 2, 4, 6, and 1
1 and 13 are supplied with DC current from DC constant voltage power supplies 18 and 19, and cooling water is passed through the water cooling plates 7 and 14 to start cooling.

In addition, in the freezing preservation solution in the straw 15,
A small first temperature measuring element 20 such as a sheath type thermocouple is inserted to detect the temperature of the freezing preservation solution, and a second measuring element 20 is also installed on the heat transfer plate portion 10b of the ice planting plate 9. A temperature element 21 is attached so that the temperature here can be detected.

As shown in FIG. 4, the temperature signal from the first temperature measuring element 20 is transmitted to the program temperature controller 2.
2, and the temperature signal from the second temperature measuring element 21 is input to the ice-planting temperature controller 23. A predetermined cooling rate is set in the program temperature controller 22.
2 supplies DC current from the DC constant voltage power supply 18 to the first, second and third thermomodules 2, 4 and 6 so that the freezing preservation liquid in the straw 15 is cooled according to this set cooling rate. Open/close the switch (relay) 24 of the circuit. Further, the program temperature controller 22 controls on/off a switch (relay) 25 of the power supply circuit of the heating heater 8, and controls the first, second, third thermomodules 2,
This is designed to compensate when cooling by steps 4 and 6 progresses too much. Moreover, when repeatedly performing freezing work, the temperature of the cooled refrigerant C can be quickly raised to room temperature by the heating heater 8. The output signal from the first temperature measuring element 20 is simultaneously input to the recorder 26, and the straw 1
The temperature change of the cryopreservation solution within 5 is recorded.

Furthermore, the program temperature controller 22 includes:
The ice-planting temperature is set in the same way in advance, and when the temperature of the freezing storage solution in the straw 15 reaches this set temperature (usually -4°C to -7°C), the relay 27 is operated and the fourth and fifth Thermo module 11, 13
The switch (relay) 28 of the circuit connected to the DC constant voltage power supply 19 is turned on for 10 to 20 seconds, and a DC current is passed through the fourth and fifth thermomodules 11 and 13 to cool the ice planting board body 10 and the straw 15. Plant ice in the freezing storage solution inside. The temperature of the ice-planting plate main body 10 at this time is controlled by the ice-planting temperature controller 23, and is usually about -15°C to -50°C. When the temperature of the ice-planting board body 10 falls below a predetermined temperature, the ice-planting temperature controller 23 operates relays 27 and 29, turns off a switch (relay) 28, and switches a switch (relay) 30 is turned on to reverse the polarity of the direct current flowing through the fourth and fifth thermomodules 11 and 13, thereby heating the ice plate main body 10.

In this way, the freezing storage solution and the fertilized eggs in the straw 15 are frozen without being subjected to thermal and physical shocks due to supercooling, and the risk of death or degeneration of the fertilized eggs is prevented. And the first, second,
Cooling is further advanced by the third thermomodules 2, 4 and 6, and the straw 15 is cooled to about -70°C to complete freezing. The straw 15 after freezing is transferred to another cryogenic storage container and stored frozen, if necessary.

Reference numeral 31 in FIG. 4 is a monitoring device that monitors the temperature of the water-cooled plates 7, and the temperature of the water-cooled plates 7 and 14 becomes abnormal due to the supply of cooling water being stopped or the amount of water decreasing. When it rises, an alarm will be issued first to notify you, and if it returns normally, 1~
After two minutes, switches 32 and 33 cut off the circuits that supply direct current to the first, second, third, fourth, and fifth thermomodules 2, 4, 6, 11, and 13. Reference numeral 34 denotes a leakage monitoring device, which instantly shuts off the power to the entire device in the event that there is a leakage in the freezing tank or the ice-planting plate 9.

According to such an animal fertilized egg freezing device, since a thermomodule is used for cooling the freezing tank 1 and for planting ice, it can be used even in places where LN ₂ is difficult to obtain, and LN ₂ , which is troublesome to handle, can be used. There is no need to use a commercial power supply and cooling water, and the freezing work can be easily carried out using a commercial power source and cooling water, and the entire device can be assembled compactly, making it easier to handle and transport. In addition, ice planting can be performed automatically, and precious fertilized eggs will not die or degenerate. Furthermore, if the thermomodule is cooled by an air cooling method using a blower, or by a circulating water cooling method using a small radiator, instead of using the water cooling plates 7 and 14, cooling water is not required, making it even easier to use.

FIG. 5 shows a cooling method when the thermo module is cooled by circulating water. Cooling water from the water cooling plates 7 and 14 is sent to the radiator 35. The radiator 35 is small in size, has a long channel length, and has a high heat exchange rate, and is forced to be air-cooled by a fan. The cooling water cooled to approximately room temperature by the radiator 35 is sent to the cooler 37 by an extremely small circulation pump 36. Cooler 37
The cooling water that has flowed in is further cooled to about 15° C. by the thermo module, and this cooling water is sent to the water cooling plates 7 and 14 again. The thermo module of the cooler 37 is forced to be air cooled by a fan. Further, a temperature sensor 38 is provided on the outlet side of the cooler 37 to measure the temperature of the cooling water flowing through this portion, and a signal from this sensor is input to a temperature controller 39. The temperature controller 39 controls the direct current supplied to the thermo module of the cooler 37 based on this temperature signal, and maintains the temperature of the cooling water flowing into the water cooling plates 7 and 14 constant.

By adopting such a cooling method, this freezing device can be used anywhere as long as there is a commercial power source, and can be made completely portable.

Note that the control system shown in FIG. 4 can be changed in various ways, for example, by changing the program temperature controller
Can be replaced with a PID temperature controller. Furthermore, if the material and dimensions of the freezing tank 1, the type of refrigerant C and its storage amount, etc. are kept constant, the control system can be greatly simplified, the entire device can be downsized, and manufacturing costs can be reduced. You can also do that.

As explained above, the animal fertilized egg freezing device of this invention uses a thermomodule consisting of an electronic refrigeration element as a cold source for cooling and planting ice, so there are no problems with supplying and handling conventional cold sources. Compared to equipment that uses liquefied nitrogen (LN ₂ ), which is inconvenient to use, the entire equipment can be made smaller, easier to operate, cheaper to manufacture, and more convenient to transport. Therefore, this freezing device will greatly contribute to the spread of cryopreservation of fertilized eggs and the like.

[Brief explanation of the drawing]

Figures 1 and 2 show an example of the freezing device of this invention. Figure 1 is a schematic diagram of the main body of the freezing device, Figure 2 is a perspective view of the ice plate, and Figure 3 shows the state in use. FIG. 4 is a block diagram showing a control system, and FIG. 5 is a schematic configuration diagram showing another example of this invention. 1...Freezing tank, 2...First thermomodule,
4...Second thermo module, 9...Ice plate, 1
0...Ice plate body, 10a...Cooling plate part, 10b
...Heat transfer plate part, 10c...Holder part, 11...
4th thermomodule, 15...Straw, 18
...DC constant voltage power supply, 19...DC constant voltage power supply,
20...First temperature measuring element, 21...Second temperature measuring element, 22...Program temperature controller, 23...Ice planting temperature controller, 26...Recorder.

Claims (1)

[Claims for Utility Model Registration] A freezing tank filled with a refrigerant for cooling and freezing fertilized animal eggs contained in a straw or an ampoule, an electronic freezing element thermally coupled to this freezing tank, and the above-mentioned freezing tank. an ice planting plate that is partially inserted into the upper space of the cell and is cooled by an electronic refrigeration element and holds the straw or ampoule, and a control unit that controls the temperature of the freezing storage solution and the ice planting plate in the straw or ampoule. An animal fertilized egg freezing device comprising: