KR100385897B1 - Freeze method and device dip transfer type - Google Patents

Abstract

The present invention relates to an immersion transfer type freezing method and apparatus for freezing while immersing and transporting various materials requiring freezing, including a material having a specific gravity greater than that of a refrigerant, in a freezing apparatus filled with a refrigerant in an ultra low temperature state.

In the immersion transfer freezing method, the frozen material is introduced between the transfer devices inside the freezing tank filled with the cryogenic refrigerant, and the driving device is driven to forcibly immerse and transfer the frozen material to the refrigerant for a predetermined time. A freezing step of freezing the frozen material at a constant temperature;

An immersion process includes installing an overflow pipe on the side of the freezing tank to maintain a constant level of the freezing refrigerant in the freezing tank, and supplying and circulating the freezing refrigerant to a cooler, thereby continuously supplying the cooling heat required for freezing the frozen material. Provided is a transfer freezing method and apparatus.

Description

Immersion Transfer Freezing Method and Apparatus {FREEZE METHOD AND DEVICE DIP TRANSFER TYPE}

The present invention relates to an immersion transfer type freezing method and apparatus, and more particularly, to freeze while transporting various substances requiring refrigeration in a freezing device filled with a refrigerant, including a material having a lighter specific gravity than the refrigerant. It relates to a submerged transfer freezing method and apparatus therefor.

In general, as a method for recycling products made of synthetic resin or rubber, a technique for producing fine powders by cooling them below the glass transition temperature and pulverizing them is widely used in the industrial field.

As such a method for freezing the various substances in a cryogenic state, as in the Republic of Korea Patent Application 95-2793, U.S. Patent 4,813,614, U.S. Patent 5,385,307, U.S. Patent 4,783,972, U.S. Patent 5,444,985, liquid nitrogen while passing the frozen material through the tunnel The injection method of injecting or supplying a cryogenic fluid refrigerant in a cryogenic state, such as, and a freezing tank filled with liquid nitrogen in a freezing tank in which a conveyor belt is installed, as in US Patent 5,630,327, US Patent 4,403,479, and US Patent 5,417,074. An immersion transfer method is proposed for freezing a frozen material by transporting the material into contact with liquid nitrogen.

However, in the conventional freezing method, the injection method of injecting liquid nitrogen has a disadvantage in that a large amount of expensive liquid nitrogen is consumed since the injected liquid nitrogen is evaporated and disappeared after freezing the frozen material. The food method allows the freezing tank containing liquid nitrogen to pass through the frozen material on the conveyor belt, so it can only freeze materials that are heavier than liquid nitrogen, and cannot freeze materials that are lighter than liquid nitrogen. During freezing, a significant amount of liquid nitrogen evaporates and disappears.

In addition, since the refrigerant used in the cooling method uses liquid nitrogen in an ultra low temperature state, the freezing temperature is constant at -196 ° C, which causes a problem of inducing excessive freezing.

The present invention has been made to solve the conventional problems as described above, the object of the present invention is to freeze by transporting the frozen material in the state immersed in the refrigerant even if the specific gravity of the material is lighter or heavier than the refrigerant. It is to provide an immersion transfer freezing method and apparatus configured to be able to.

Another object of the present invention is not only liquid nitrogen but also various fluids in an ultra low temperature state, for example, R-22, R-23, R-13B1, etc. may use a refrigerant for freezing, depending on the refrigerant used -40 ℃ ~- The present invention provides an immersion transfer freezing method and apparatus capable of freezing frozen materials in a wide temperature range of 160 and maintaining a constant refrigerant temperature and refrigerant level inside the freezing tank at all times.

In order to realize the object of the present invention as described above, the frozen material is introduced between the conveying device inside the freezing tank filled with the refrigerant, and the conveying device is driven in the state of being immersed in the coolant so that A refrigeration step of freezing the frozen material at a constant temperature while the frozen material is forcibly immersed and transported in the refrigerant even if the specific gravity is large or small;

The present invention provides an immersion transfer freezing method and apparatus including a refrigerant cooling step of continuously cooling a refrigerant having a temperature rise in a cooling process of a frozen material by a cooler to continuously supply cold air required for freezing the frozen material.

The refrigeration process allows the refrigerant to pass through the pair of conveyors with the frozen material interposed, so that the frozen material is completely submerged in the refrigerant even if the specific gravity of the frozen material is greater or smaller than the specific gravity of the refrigerant. It is characterized in that it is made to be cooled.

1 is a partial cutaway side view of a freezing device applied to the immersion-type freezing method according to the present invention.

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

1 is a partial cutaway side view of a freezing apparatus applied to an immersion conveying method of freezing according to the present invention, 2 denotes a freezing tank.

The freezing tank (2) has an internal space having a predetermined area in a state insulated with a heat insulator, and the internal space is filled with a predetermined amount of the refrigerant (4).

The refrigerant 4 may be used as a liquid nitrogen that is commonly used in the freezing method, as well as a liquid refrigerant liquefied in an ultra low temperature state.

In the outside of the freezing tank 2, an input device 6 for injecting the frozen substance into the freezing tank 2 is installed, and inside the freezing tank 2, the frozen material introduced from the input device 6 ( The transfer device 8 for freezing while transferring R) in the state of being immersed in the refrigerant 4, and the frozen material R cooled by the transfer device 8 is transferred onto the surface of the coolant 4 so that A refrigerant recovery device (10) is installed to dry the frozen substance while allowing the refrigerant contained in the frozen substance (R) to fall into the freezing tank (2) by gravity.

The feeding device 6 is a raw material for continuously feeding the hopper 12 containing the frozen material to be frozen and the frozen material R supplied from the hopper 12 by a predetermined amount into the transfer device 8. It is made of an input unit (14).

The raw material input part 14 may be formed in a piston type to forcibly push a predetermined amount of raw material toward the feeder (8).

The conveying apparatus 8 is composed of a pair of conveyors 16a and 16b which are located below the surface of the coolant 4 and installed up and down side by side at regular intervals, and outside the conveyors 16a and 16b. A plurality of locking projections 18a and 18b are formed to maintain equal intervals.

The conveyors 16a and 16b have a network structure, and both ends thereof are fixed to the shafts and installed in a caterpillar shape, and rotated in opposite directions by a driving force of a driving device (not shown), that is, the frozen material. (R) is configured to be transferred from the input device 6 side toward the refrigerant recovery device 10.

In addition, the conveyor (16a, 16b) is to adjust the distance between the conveyor (16a, 16b) to move up and down the shaft installed on both ends in the drawings, respectively, the height adjusting section (20a), (20b) Is formed.

The height adjusting portion 20a (20b) may be used a conventional structure that can adjust the height of the conveyor (16a, 16b) using a screw rod.

The coolant recovery device 10 is installed at an end of the transfer device 8 to be inclined on the surface of the coolant 4 and formed of a conveyor 22 having a network structure to allow the coolant to pass therethrough, and formed on the conveyor 22. It is formed of a plurality of engaging jaw 24, the discharge end 26 is installed at the end of the conveyor 22 to allow the frozen frozen material (R) is discharged to the outside of the freezing tank (2).

And the upper and lower outer sides of the freezing tank (2) is connected to the conduit (28) made to communicate with the inside of the freezing tank (2), the heat exchanger 30 and the pump 32 is installed on the conduit (28) Thus, the temperature of the refrigerant 4 and the surface of the refrigerant surface in the freezing tank 2 can be kept constant.

That is, when the refrigerant cooled to a constant temperature in the heat exchanger 30 is supplied to the lower portion of the freezing tank 2 through the pump 32, the refrigerant in the upper portion of the freezing tank 2 is supplied to the conduit 28 by the supplied refrigerant. The refrigerant is introduced into the heat exchanger (30), the refrigerant is cooled to a predetermined temperature or less in the heat exchanger (30), and then the refrigerant is circulated by supplying the refrigerant to the freezing tank (2) through the pump (32). The refrigerant 4 contained in (2) can maintain the temperature and the surface height constant.

In addition, by further installing a cooling coil 34 in contact with the refrigerant 4 inside the freezing tank 2 to directly cool the refrigerant, the cooling effect can be further enhanced.

The cooling coil 34 is formed in a tubular shape, and the cryogenic fluid such as liquid nitrogen, liquefied natural gas, liquid oxygen, etc. is supplied therein to exchange the refrigerant 4 by heat exchange with the refrigerant 4 in the freezing tank 2. Directly cooling, both ends of the cooling coil 34, the valves are respectively installed in the state extending to the outside of the freezing tank (2) to discharge the refrigerant of the cooling coil 34 or to inject a new refrigerant.

In order to cool the frozen material using the immersion transfer freezing apparatus of the present invention as described above, first, a certain amount of refrigerant 4 is filled in the freezing tank 2 and the frozen material R is supplied to the hopper 12. The raw material input unit 14 pushes the frozen material R to be forced into the transfer device 8.

Then, the frozen substance R is caught in the locking projections 18a and 18b of the conveyors 16a and 16b which rotate in opposite directions at a predetermined speed while being contained in the refrigerant 4, and the refrigerant recovery device 10 Cooled to the side.

If the frozen material R is lighter than the specific gravity of the refrigerant 4 during the cooling transfer, the frozen material R is caught by the locking jaw 18b formed on the upper side conveyor 16b, and the frozen material R is transferred to the refrigerant 4. If it is heavier than the specific gravity, it is caught and transported by the locking step 18a formed on the lower side conveyor 16a.

Therefore, even if the material to be frozen R is lighter or heavier than the specific gravity of the refrigerant 4, the frozen material R may be frozen while being transported in the state of being immersed in the refrigerant 4.

According to the size of the frozen material (R) to be frozen, the height adjusting portions 20a and 20b formed on the conveyors 16a and 16b may be adjusted and used.

When the frozen material R is cooled and transferred to the coolant recovery device 10, the cooled frozen material R is transported onto the surface of the coolant 4 by being caught by the catching jaw 24 of the conveyor 22 that is inclined. In this case, the refrigerant buried on the surface of the frozen material (R) is dropped into the freezing tank (2) by gravity and only the frozen frozen material (R) is discharged out of the freezing tank (2) through the outlet (26).

During the cooling process, the refrigerant cooled to a predetermined temperature or less in the heat exchanger 30 installed outside the freezing tank 2 is supplied into the freezing tank 2 through the pump 32. The internal temperature and surface height of the refrigerant 4 can be kept constant.

In addition, since the cooling coil 34 is installed in the freezing tank 2 to directly contact the refrigerant 4 to cool the refrigerant, the refrigerant 4 contained in the freezing tank 2 maintains a more constant cooling temperature. do.

As described above, the immersion-transfer freezing method and the apparatus according to the present invention have a structure for transferring the frozen material between the transfer devices, so that the frozen material is immersed in the refrigerant even if the frozen material is lighter or heavier than the refrigerant. Can be frozen while transferring.

It also has a structure that cools and circulates the refrigerant, so that the temperature of the refrigerant and the surface height of the refrigerant can be kept constant.In the freezer, a cooling coil is installed to directly cool the refrigerant by contacting the refrigerant. It can be kept below.

Claims (6)

The frozen material is introduced between the transfer device inside the freezing tank filled with the refrigerant, and the driven device is driven while the transfer device is immersed in the refrigerant to force the frozen material to the refrigerant even if the specific gravity of the frozen material is larger or smaller than the specific gravity of the refrigerant. A freezing step of freezing the frozen material to a predetermined temperature while being immersed and transferred; An immersion transfer freezing method comprising a refrigerant cooling step of continuously cooling a refrigerant having risen in temperature during cooling of the frozen material by a cooler to continuously supply cold air required for freezing the frozen material. The cooling heat source of claim 1, wherein, in the refrigerant cooling process, the refrigerant cooled by the cooler is supplied to the lower end of the freezing tank, and a cooling heat source is introduced into the cooler through the overflow pipe on the side of the freezing tank and cooled by the amount of the supplied coolant. Immersion transfer freezing method characterized in that for supplying. A freezing tank having a predetermined internal space and filled with a predetermined refrigerant; An input device installed outside the freezing tank to input a frozen material into the freezing tank; A transfer device for freezing while transporting the frozen material introduced from the input device in a state of being immersed in a refrigerant; A refrigerant recovery device for transporting the frozen material to be cooled and transported onto the surface of the refrigerant to dry the frozen material while dropping the refrigerant contained in the frozen material into the freezing tank by gravity; An immersion transfer freezing device including a discharge unit for interlocking with the refrigerant recovery device to discharge the frozen material to be frozen out of the freezing tank. (Correction) The pair of conveyors according to claim 3, wherein the conveying apparatus is disposed up and down side by side while being positioned below the coolant surface filled in the freezing tank, and the height adjusting portions are formed, respectively, and the distance therebetween is adjusted. It is made of a network structure having a plurality of locking projections formed at equal intervals on the outside of the conveyor, the conveyor is characterized in that both ends are fixed to the shaft and configured to rotate in opposite directions by the driving force of the drive device. Immersion conveying freezing device. 4. The pipe of claim 3, wherein a pipe line configured to communicate with the inside of the freezing tank is connected to the upper and lower outer sides of the freezing tank, and a heat exchanger for cooling the refrigerant and a pump for supplying the cooled refrigerant to the cooling tank are further installed on the freezing tank. Immersion transfer type freezing apparatus, characterized in that configured to maintain a constant the temperature and the refrigerant surface height inside the freezing tank. The immersion transfer freezing apparatus according to claim 3, wherein a cooling coil is further installed in the freezing tank to directly contact the refrigerant to cool the refrigerant.