WO2013089306A1 - Grain refrigerator - Google Patents

Abstract

The present invention relates to a grain refrigerator. According to the grain refrigerator, since an isolation device is disposed in a cooling part which is disposed at the inner center of the refrigerator whereby grains are stored so as to be spaced apart from the cooling part and in contact with the isolation device, cooling air may not be directly transferred to the grains thereby preventing condensation from forming on the grains. Also, since the grains are stored so as to be spaced apart from the cooling part and in contact with the isolation device, water generated from condensation due to the melting of frost formed on the inner surface of the cooling part may not permeate into the grains thereby preventing the grains from decaying or becoming denatured. In addition, since the cooling part includes a heater and cooling tube which are formed of far infrared ray emission materials or porous materials, water generated due to the dew formed on the inner and outer surfaces of the cooling part may be heated, dried, and absorbed to prevent the water generated on the inner and outer surfaces of the cooling part from leaking, thereby preventing the grains from decaying or being denatured.

Description

Grain freezer

The present invention relates to a grain refrigerator, and in particular, by installing an isolator outside the cooling unit in the oven to prevent the stored grain from contacting the cooling unit prevents the deterioration of the grain due to condensation of the cooling unit, and the segregation during storage The present invention relates to a grain refrigerator capable of easily separating and removing grains or debris of grains to be put into the device, thereby maintaining the cold air circulation in the refrigerator smoothly for long-term storage at low temperatures.

In general, grains contain a lot of carbohydrates, so they are easily deteriorated by the change of ambient temperature during long-term storage, so they should be stored at low temperature if possible for long-term storage without alteration.

In view of this, various studies have been conducted on grain refrigerators capable of storing grain at low temperatures. As part of this, the grain refrigerator is equipped with a cooling device to circulate cold air in the cooling device to cool the grain. Condensation occurs on the surface of the cooling device due to the temperature difference with the grains during storage, and the generated condensation generates moisture in the evaporation process so as to permeate the surrounding grains to alter the grains.

Therefore, in the case of a grain refrigerator using a cooling device, various studies are being conducted to prevent the deterioration of grains due to condensation during storage, and the domestic patent application shown in FIG. 1 filed and registered by the applicant of the present invention. In the arc (name of the invention: a grain refrigerator), a cylindrical evaporator accommodating portion is provided at the center of the storage of the grain refrigerator using a refrigerant cycle, and a vertical rod 101 at the center of the evaporator accommodating portion, and a lower end of the vertical rod 101. The bottom portion 110 is formed in the shape of a disc installed in the cylindrical outer portion 120, which is mounted on the outer peripheral inner upper surface of the bottom portion 110, is installed on the upper end of the vertical rod 101 is the exterior portion ( Correlation unit 140 covering the upper surface of the 120 and having a guide pipe 144 on one side, a sponge tube 106 and a straight portion 131 installed along the longitudinal direction of the vertical rod 101, the straight portion With one end of 131 Consisting of the spiral portion 130 is wound around the vertical rods 101 in a spiral manner, the exterior portion 120 and the spiral portion 130 due to direct contact with the inside and outside due to condensation Inserting the buffer 150 to prevent the condensation was prevented in the receiving portion exterior portion 120.

In addition, in the domestic registration practical application 20-0390039 (name of the invention: a cooling device of a grain refrigerator) shown in FIG. 2 filed and registered by the applicant of the present invention, a cylindrical cooling housing (100) in the center of the grain storage unit using a Peltier element. And cold air generated from the upper surface (cooling surface) of the Peltier element 113 to the lower portion of the cooling housing 100 is transferred to the cooling post 101 to discharge the cold air, and the lower surface of the Peltier element 113. The collecting plate 115 and the heat dissipation plate 117 are connected to the heat dissipation plate to dissipate heat, and the heater 107 is wound around the outer surface of the insulating tube 105 to remove condensation generated during the cooling process. .

In addition, the receiving unit 103 is formed of a material of ocher or ceramic that can contain a certain amount of moisture generated in the cooling process while radiating far infrared rays.

In addition, the support member 109 is formed with a drain hole 111 inside the bottom surface between the insulating tube 105 and the cooling post 101, the drain hole 111 is formed so as to communicate with the side surface of the support member 109 heater 107 When the condensation is removed, the moisture generated is discharged to the back surface (heat dissipation surface) of the Peltier element 113.

As described above, the cooling device of the grain refrigerator does not directly contact the grains stored in the grain storage unit with the cooling post 101, and the cooling post 101 is installed inside the accommodating part 103 such that the accommodating part 103 is disposed on the grain. It was effective to prevent condensation by contacting, and the moisture generated by melting the condensation during heater operation to remove the condensation is absorbed by the receiving part 105 made of a material of far-infrared radiation material such as ocher or ceramic, thereby preventing the grain from rotting or deteriorating. The advantage is that the grain is stored safely.

However, the conventional cooling device 100 was more effective in preventing condensation than when the grains were in direct contact with the cooling post 101. However, the condensation is not completely prevented and the grains in contact with the receiving portion 103 are still condensed. The problem that was occurring was still having.

In addition, condensation generated on the outer circumferential surface of the accommodating part 103 has a problem in that when the heater 107 is heated, the condensation melts and is absorbed by the grain, thereby causing the grain to rot or deteriorate.

In addition, in the conventional cooling device 100, the receiving part 103 is made of far-infrared material such as ocher or ceramic to absorb a certain amount of water by itself, but when a predetermined amount or more of water is absorbed, the water is not absorbed any more, and is released to the outside. Since there is still a problem that the grains in contact with the outer circumferential surface of the receiving portion 103 is deteriorated.

An object of the present invention to solve the above problems is to install an isolator on the outside of the cooling unit installed vertically in the refrigerator so that the stored grains do not directly contact the cooling unit, condensation to the grain adjacent to the cooling unit. It is to prevent the deterioration caused by.

Another object of the present invention is to provide an easy to install and separate the isolation device is installed on the outside of the cooling unit installed vertically in the interior, so that when the grains or debris of the stored grains is caught in the isolation device easily from the cooling unit. It is to separate and remove grains of grain or grains stuck in the isolation device easily.

Another object of the present invention is to easily remove the grains or debris in the isolation device to prevent the deterioration of the grain due to condensation of the cooling unit, thereby allowing the cold air circulation in the interior smoothly through the isolation device To extend the shelf life of

Solution to Problem The present invention for solving the above problems is a storage bin for storing grains; A chiller that generates cold air; A cooling unit installed inside the reservoir to cool the inside of the cold air generated from the cooling device; And an isolation device installed outside the cooling portion to prevent grain from coming into contact with the cooling portion.

In the present invention, the cooling unit has a cylindrical shape and includes a vertical cylindrical portion installed vertically with respect to the ground, and the isolation device includes a separator of a network structure formed to surround the vertical cylindrical portion spaced apart.

In the present invention, the isolation device is characterized in that it further comprises a top plate of the network structure covering the upper surface of the separator.

In the present invention, the isolation device is characterized in that it further comprises a separation means for contacting the inner surface of the separator and the other surface is in contact with the outer surface of the vertical cylindrical portion to separate the separator and the vertical cylindrical portion.

In the present invention, the separation means is characterized in that it is provided with any one of a projection or bar shape.

In the present invention, the separator consists of two semi-cylindrical semi-cylindrical pieces, one end of the semi-cylindrical pieces are hinged to each other, the other end is provided with a switchgear coupled to each other, the opening and closing device The separator is installed in the open state so that the separator is closed after the separator is installed on the outside of the vertical cylindrical portion.

In the present invention, the separator includes at least one switch unit at one end.

In the present invention, the opening and closing device is characterized in that it is provided with a hook to form a hook on one side, the hook on the other side by engaging the elastic force.

In the present invention, the isolation device is made of any one of a grid or a porous network, characterized in that it comprises a cylindrical separator installed to the outside of the cooling unit.

In the present invention, the separator is characterized in that it is provided with any one of a metal or a synthetic resin.

In the present invention, the cooling device is a Peltier device for generating cold air; It includes a cold air transfer portion for transmitting the cold air generated from the Peltier element in the interior.

In the present invention, the cooling device includes a refrigerant cycle for generating cold air by a compression, condensation, expansion, and evaporation stroke.

According to the present invention having the above-mentioned problems and solving means, by providing an isolation device in the cooling unit installed in the inner center of the reservoir so that the grain is stored in contact with the isolation device spaced apart from the cooling unit, cold air directly into the grain It will not be delivered and will be stored without condensation on the grain.

In addition, since the grains are stored in contact with the isolation device at a distance from the cooling unit, condensation formed on the inner circumferential surface of the cooling unit melts, so that moisture generated does not penetrate into the grains, thereby preventing the grains from rotting or deteriorating due to moisture. Will be.

In addition, the cooling unit includes a heater and a cooling tube made of a far-infrared radiation material or a porous material, thereby heating and drying and absorbing moisture generated by melting condensation formed on the inner and outer circumferential surfaces of the cooling unit to prevent water from leaking into and out of the cooling unit. This will allow the storage of moisture while preventing the grain from rotting or deteriorating.

1 is a cross-sectional view of a conventional grain refrigerator

2 is a cross-sectional view of a cooling apparatus of a conventional grain refrigerator.

3 is a partially cutaway exploded perspective view of a grain refrigerator according to one embodiment of the present invention;

4 is a cross-sectional view of the present invention grain refrigerator combined

Figure 5 is an embodiment of the isolation device of the present invention grain refrigerator

6 is another embodiment of FIG.

7 is another use state of the isolation device of the grain refrigerator of the present invention

8 is a cross-sectional view of the grain refrigerator another embodiment of the present invention

9 is yet another embodiment of the isolation device of the grain refrigerator of FIG.

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

3 is a partially cutaway exploded perspective view of a grain refrigerator according to one embodiment of the present invention;

Grain refrigerator 300 is provided with a reservoir 310 for storing the grain at the upper portion, the lower portion is provided with grain extraction means 320 for extracting the grain stored in the front, the central portion of the lower reservoir 310 It is provided with a cooling device 330 for supplying cold air to and discharge the internal heat.

In the center of the reservoir 310 is provided with a cooling unit 340 for supplying cold air to the grain contained vertically upward.

The cooling unit 340 is formed in a cylindrical shape and is provided with a vertical cylindrical portion installed perpendicular to the ground.

The outside of the cooling unit 340 is provided with an isolation device 350 to prevent the grains contained in contact with the cooling unit 340 and to prevent the penetration of moisture due to condensation.

Therefore, the grain contained in the reservoir 310 is separated from the cooling unit 340 by an isolation device 350 provided on the outside of the cooling unit 340 that receives and cools the cold air from the cooling unit 330. Since no direct contact, the condensation and moisture of the cooling unit 340 is to be stored while preventing the grain from rot or deterioration.

Figure 4 is a cross-sectional view of the combined grain refrigerator of the present invention.

Storage 310 is provided with a discharge surface 311 which is inclined downward downward so that the grain is easily discharged to the lower portion inside, the discharge hole 312 is discharged to the lower surface of the discharge surface 311 is inclined It is provided.

Grain extraction means 320 is provided in the lower front of the discharge hole 312 of the reservoir 310 is discharge lever 321 and the discharge lever 321 for discharging the stored grain while opening and closing the discharge hole 312 It is provided with a grain tray 322 that contains the discharged grain at the bottom of the.

Therefore, by opening and closing the discharge hole 312 of the reservoir 310 by the discharge lever 321 of the grain extraction means 320, the grain stored in the reservoir 310 is discharged through the discharge hole 312 to receive the grain at the bottom (322).

Cooling device 330 is provided in the lower central portion of the reservoir 310 to generate cold air, the cold air generating means 330 is preferably an electric-heat conversion element Peltier element 331, and In contact with the Peltier element 331 is provided with a cold air transfer portion 332 for delivering cold air.

The Peltier element 331 is provided with a heat sink 333 for dissipating heat generated during heat exchange.

The heat sink 333 is preferably provided with a fan for more efficiently dissipating the heat inside.

When the Peltier element 331 is supplied with power from a power supply (not shown), one side (cooling surface) absorbs and cools the surrounding heat by the Peltier effect, and the other side (heating surface) has an effect of releasing absorbed heat. The heat exchange with the surroundings generates cold air.

In addition, the cold air delivery portion 332 is provided on one surface (cooling surface) of the Peltier element 331, and transmits cold air generated from one surface of the Peltier element 331 to the storage 310.

Cooling unit 340 is vertically installed in the central portion of the cold air transfer receiving portion 332 coupled to the Peltier element 331, the grain stored in the interior of the cold reservoir 310 is delivered from the Peltier element 331 A cooling post 341 to be supplied to the cooling post, an insulating tube 342 which is provided to be spaced outward from the cooling post 341, and is formed in a cylindrical shape having an upper portion opened, and wound around the outer circumferential surface of the insulating tube 342. A heater 343 for generating condensation and drying the condensation, and a cooling tube 344 provided outside the heater 343 and supplying cool air of the cooling post 341 to the inside of the refrigerator.

The cooling pipe 344 is fixed to the cold air transfer portion 332 while the upper portion is circular and the lower portion is open.

The cooling tube 344 is provided with or coated with a far-infrared radiation material such as ceramic or ocher material.

Condensation formed on the inner and outer circumferential surfaces of the cooling tube 344 absorbs moisture generated by melting, and is preferably made of a porous material to increase moisture absorption ability.

Therefore, the cooling unit 340 is one surface is cooled from the Peltier element 331 of the cooling device 330 provided in the lower portion of the reservoir 310, the other surface is a cold air transfer support portion generated by the Peltier effect that generates heat Received through the cooling post 341, the insulating tube 342, the cooling tube 344 through the 332 to cool the grain stored in the reservoir (310).

The isolation device 350 is installed outside the cooling pipe 344 of the cooling unit 340, and the lower part of the isolation device 350 is installed in the cooling transmission support part 332 of the cooling device 330. By fixing and storing the grains stored in the reservoir 310 so as not to directly contact the cooling tube 344, the grains due to condensation or moisture of the cooling tube 344 are prevented from being rotted or deteriorated.

Figure 5 is an embodiment of the isolation device of the grain refrigerator of the present invention.

The isolation device 350 is made of a strong corrosion resistant iron material, preferably stainless steel, but made of synthetic resin to prevent erosion and corrosion even when contacted with moisture and condensation.

In addition, the isolation device 350 is provided in a circular shape at an upper portion thereof, and has a cylindrical shape in which a lower portion thereof is opened so that the cooling tube 344 of the cooling unit 340 can be accommodated inside the lower portion.

The isolation device 350 is a longitudinal frame 351 is formed in the vertical direction in the vertical direction, the upper and side surfaces of the vertical frame 351 is formed with a large diameter from a small diameter, the side is the diameter of the upper By combining the horizontal frames 352 having a larger diameter with each other as a grid-like separator 353, grains in the separator 353 are not directly contacted with the cooling unit 340. Cold air of the portion 340 is coupled to be smoothly circulated to the grain.

Accordingly, the grains of the reservoir 310 are stored without being directly in contact with the cooling tube 344 of the cooling unit 340, so that condensation may occur in the grains or the condensation formed in the cooling tube 344 may melt and flow out. It will not penetrate the grains and will fundamentally solve the mixing and alteration of the grains.

In addition, the isolation device 350 is provided on the inner circumferential surface of the separator plate with spaced apart means 354 spaced apart in contact with the cooling part 340 protruding inwardly, so that the grain blocks direct contact with the cooling part 340. In addition, the separation device 354 allows the isolation device 350 to be firmly fixed without flowing or shaking from the cooling unit 340.

6 is another embodiment of FIG. 5.

The isolation device 350 is to be inserted into the side of the cooling tube 344 to be installed, the isolation device 350 is provided with a separator plate 353 in two semi-cylindrical shape, the two semi-cylindrical shape One end of the separator 353 of the separator 353 is coupled to each other so as not to be separated by at least one hinge portion 355, and at least one switch device 356 is provided at both ends of the two semi-cylindrical separators 353. Will be combined.

The opening and closing device 356 is formed with a hook 358 to one side to form a ring 357, the other side to fasten the hook 357 by the elastic force.

In the state in which the opening and closing device 356 is opened, the separator 353 of the isolation device 350 is installed on the outside of the vertical cylindrical portion of the cooling unit 340 and then closes the opening and closing device 356. The isolation device 350 is to be installed.

7 is a state diagram used in the isolation device of the grain refrigerator of the present invention.

The isolation device 350 is installed while wrapping the cooling tube 344 on the side of the cooling tube 344, and used while storing the grain in the reservoir 310, generated from the grain stored in the reservoir 310 during use. When the debris or grains are caught in the separator plate 353 of the isolation device 350, the release device 356 of the isolation device 350 is released and opened, and the isolation device 350 has one hinge portion ( 355) to open the shaft.

After separating from the cooling tube 344 through the other side of the open isolation device 350 and withdrawing it from the reservoir 310, the grains of the grain stuck to the separator plate 353 of the isolation device 350 or It will remove the pellets.

Subsequently, the separator 353 of the isolation device 350 is opened and inserted into the side of the cooling pipe 344 and then fastened to the opening and closing device 356 to the cooling pipe 344 of the cooling unit 340. By installing the cold air from the cooling pipe 344 through the separator 353 of the separator 350 to facilitate the supply and circulation of cold air to the grain to improve the storage.

8 is a cross-sectional view of a grain refrigerator according to another embodiment of the present invention.

The grain refrigerator is a cooling unit 330 for generating cold air shown in FIGS. 3 and 4 and a cooling unit installed in the inner center of the storage room 310 to cool the inside of the refrigerator with the cold generated from the cooling device 330. This is generally the same as 340.

In this case, the cooling device 330 is installed at a lower portion of the reservoir 310 so as to generate cold air in the reservoir 310 as a refrigerant cycle that generates cold air by compression, condensation, expansion, and evaporation.

As shown in FIGS. 3 and 4, the cooling unit 340 is installed vertically at a central portion of the refrigerator to discharge cold air absorbed uniformly into grains and to the outside from the cooling post 341. An insulating tube 342 which is spaced apart and formed into a cylindrical shape having an upper portion opened, a heater 343 wound around the outer circumferential surface of the insulating tube 342 to generate heat to dry condensation, and an outer side of the heater 343. Is provided as a cooling tube 344 for supplying the cold air of the cooling post 341 is the same point.

Here, the cooling pipe 344 generates cold air as a refrigerant cycle of the cooling device 330, spirally wound on the outer surface of the cooling post 341, and evaporates liquid refrigerant from the cooling device 330 to generate cold air. It includes an evaporator 345 and an induction pipe 346 into which the discharge pipe for discharging the refrigerant of the evaporator 345 is inserted.

Therefore, the reservoir 310 has a cooling post 341 and the cooling post provided at the center of the cooling pipe 344 in a compression, condensation, expansion, and evaporation process through the refrigerant cycle of the cooling device 330 provided at the bottom. Cold air is generated through the evaporator 345 wound spirally on the outer surface of the 341 to cool the grains stored in the reservoir 310 by the cooling unit 340.

As such, when cooling the grains stored in the reservoir 310 with the cold of the cooling unit 340, the stored grains are prevented from decaying or deteriorating due to condensation and moisture due to direct contact with the cooling unit 340. The cooling tube 344 is provided with an isolation device 350 to prevent the stored grain contact.

Figure 9 is another embodiment of the isolation device of the grain refrigerator of the present invention.

The isolation device 350 includes a separator 353 of any one of a mesh or a porous network having a size smaller than that of grain, and the isolation device 350 has a network structure covering an upper surface thereof. It may further include a top plate.

The separator 353 of the isolation device 350 includes two semi-cylindrical pieces having a semi-cylindrical shape, the upper part and the lower part of which are opened to be inserted and installed in the side of the cooling tube 344 of the cooling unit 340. However, one end of the semi-cylindrical pieces are coupled not to be separated from each other by at least one or more hinges 355, the other end is provided with at least one or more opening and closing device 356 are coupled to each other, the isolation device 350 At the top of the) is provided with an inlet 359 is inserted into the induction pipe 346 provided in the cooling pipe 344.

The isolation device 350 is provided with a separation means 354 inwardly, wherein the separation means 354 has one surface in contact with the inside of the isolation device 350, and the other surface is perpendicular to the cooling unit 340. It is provided in the shape of a rod in contact with the outer surface of the cylindrical portion, provided to extend from the inner upper portion to the lower portion of the isolation device 350 to space the vertical cylindrical portion of the isolation device 350 and the cooling unit 340.

The isolation device 350 opens and closes the opening and closing device 356 to one side and the other side of the separator 353 about the hinge portion 355 on the side of the cooling tube 344 of the cooling unit 340. By inserting the fastening device 356 with the insertion hole 359 of the isolation device 350 inserted into the induction pipe 346 of the cooling pipe 344, the isolation device 350 is a cooling unit. It is installed in the cooling tube 344 of the 340, so that the grain is blocked in direct contact with the cooling tube 344 is stored while preventing the grain from rot or deterioration due to condensation and moisture infiltration.

When grains or grains are caught in the separator 353 of the separator 350 in the process of storing grains, the separator is opened by opening and closing the device 356 of the separator 350. The 353 is separated from the cooling tube 344 of the cooling unit 340 to remove the grains or grains of the grains stuck in the separator 353 of the isolation device 350, and then inserted into the cooling tube 344 again. The opening and closing device 356 is fastened.

Therefore, the cold air from the cooling pipe 344 can store the grains while smoothing the supply and circulation of the cold air to the grains through the isolation device 350 to improve the storage of the grains.

Claims (12)

1. A cellar in which grain is stored;

   A chiller that generates cold air;

   A cooling unit installed inside the reservoir to cool the inside of the cold air generated from the cooling device; And

   And a separator installed outside the cooling unit to prevent grain from coming into contact with the cooling unit.
2. The method of claim 1,

   The cooling unit has a cylindrical shape and comprises a vertical cylindrical portion installed vertically with respect to the ground, wherein the isolation device is a grain refrigerator, characterized in that it comprises a separator of the network structure is formed so as to surround the vertical cylindrical portion spaced apart.
3. The method of claim 1,

   The isolation device further comprises a top plate of a network covering the top surface of the separator.
4. The method of claim 2 or 3,

   The separator further comprises a separation means for separating the separator from the vertical cylinder by contacting an inner surface of the separator and an outer surface of the separator.
5. The method of claim 4, wherein

    The separation means is a grain refrigerator, characterized in that provided with any one of a projection or bar shape.
6. The method of claim 2,

   The separator consists of two semi-cylindrical semi-cylindrical pieces, one end of the semi-cylindrical pieces are hinged to each other, the other end is provided with a switchgear coupled to each other, the state of opening and closing the switch And the separator is installed on the outside of the vertical cylindrical portion to close the opening and closing device, thereby installing the separator.
7. The method of claim 2,

   The separator has a grain freezer comprising at least one switch at one end.
8. The method of claim 6,

   The opening and closing device is a grain refrigerator, characterized in that provided with a hook to form a hook on one side, the hook on the other side by the elastic force.
9. The method of claim 1,

   The isolation device is made of any one of a grid or a porous network, grain freezer, characterized in that it comprises a cylindrical separator installed to the outside of the cooling unit.
10. The method of claim 1,

    The isolation device is made of any one of a grid or a porous network, grain freezer, characterized in that it comprises a cylindrical separator installed to the outside of the cooling unit.
11. The method of claim 1,

    The cooling device includes a Peltier element for generating cold air; A grain refrigerator comprising a cold air transfer portion for transmitting the cold air generated from the Peltier element in the interior of the refrigerator.
12. The method of claim 1,

    The cooling device includes a cereal refrigerator comprising a refrigerant cycle for generating cold air by compression, condensation, expansion and evaporation stroke.

Images