KR101170718B1 - refrigerator for grain - Google Patents

Abstract

The present invention relates to a grain refrigerator in which moisture inside the cooling device can be safely drained to the outside of the grain storing part while preventing moisture from flowing out into the grain storing part inside the cooling device of the grain refrigerator in which the evaporator is installed, It is a combined grain refrigerator that can use common refrigerant of cereal refrigerator.

Description

A refrigerator for grain {

The present invention relates to a grain refrigerator capable of storing and storing cereals such as rice at a low temperature.

Rice and other grains have been proven to be superior in taste and nutrition without deterioration of grain when stored at 13 to 16 ° C. Therefore, many inventions have been developed to maintain this temperature during storage of grain. However, the refrigerator for storing the grain is different from the refrigeration of the grain by the convection phenomenon in the general refrigerator. When the evaporator and the grain are in direct contact with each other, the condensation phenomenon often causes the cereals to decay or deteriorate.

The present applicant has developed a cereal refrigerator in which a cooling rod is made of a loess material in a grain storing part and acquired rights as a patent registration No. 10-0877525 (title of invention: cereal refrigerator). In Patent Registration No. 10-0877525, The same technical structure is disclosed. 1 is an exploded perspective view illustrating the technique of Patent Registration No. 10-088525. The interior of the housing 1 of the refrigerator is provided with a hopper-shaped diaphragm 2 having a through hole at the center thereof and is provided in the housing 1 and the upper portion of the diaphragm 2 is provided with a grain storing portion 5, A partition wall is provided horizontally on the ground below the hopper-shaped diaphragm 2, and on the upper part of the partition wall there is disposed a discharge cylinder 4 for containing the grain discharged through the passage hole of the diaphragm 2. [ (7) is installed in the lower space of the partition wall (2), and the passage hole of the partition plate (2) is connected by the discharge handle (3) to seal the through hole or to open A cooler 100 is installed in the upper center of the diaphragm 2 to house an evaporator and a heater therein. The cooler 100 is made of loess, which is a far-infrared ray emission, and a heater for removing the evaporator and the internal malformation is installed inside. The evaporator cools the cooler and cools the stored stored grains by the cooler 100 Thereby keeping the grain in a low temperature state. However, in the cereal refrigerator having such a structure, since the cooler is manufactured by sintering the loess material, which is an air quality material, when the heater is operated in order to remove the malformation generated inside, the moisture passes through the cooler wall and reaches the grain So the stored grains are rotten.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to prevent the moisture inside the cooling device of the cereal refrigerator in which the evaporator is installed from flowing out to the grain storing part by the opaque layer of the cooling device.

Another object of the present invention is to allow the lower end portion of the cooling device to protrude to the lower portion of the diaphragm so that moisture is discharged from the grain storing portion without contact with the grain when moisture is generated in the cooling device.

Another object of the present invention is to provide a refrigerator having a water purifier installed in a cereal refrigerator and circulating an evaporator installed in a cooling cylinder of a water purifier so that a refrigerator can be manufactured compactly without using a double- .

The above object of the present invention can be also achieved by a grain refrigerator in which a diaphragm is installed inside a housing and a top portion of the diaphragm forms a cereal storage portion in which cereals are stored, the refrigerator having a lower end protruding downward from a lower surface of the diaphragm And a cooling vessel in which an upper portion is located in the grain storage portion to receive therein a cooling device for cooling the grain of the grain storage portion,
The diaphragm is formed in a plate shape inclined upwards toward a wall of the housing with a straight bent portion as a center, the length of the diaphragm to one end of the diaphragm is longer than the length of the other end of the diaphragm A through hole is formed between the one end and the bent portion, and the cooling container passes through the through hole.

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According to the present invention having the above-mentioned problems and solutions, the cooling vessel of the cooling device provided with the evaporator inside the diaphragm is positioned in the grain storage space, and the lower end of the cooling vessel is cooled downward So that the moisture generated inside the cooling vessel is discharged to the lower part of the diaphragm rather than the space stored in the grain storing part to prevent the stored grain from being deteriorated.

In addition, the cooling container is formed with a glaze treatment or a layer of opaque material by synthetic resin to prevent the moisture inside the cooling container from being discharged to the outside of the cooling container, thereby preventing grain deterioration.

In addition, by making the water purifier co-use with the refrigerant, the manufacturing cost is reduced while making it compact.

1 is an exploded perspective view illustrating the technique of Patent Registration No. 10-088525.
2 is an exploded perspective view of a cereal refrigerator according to a first embodiment of the present invention.
3 is a cross-sectional view of a first embodiment of the present invention.
4 is a cross-sectional view illustrating the cooling apparatus of Fig.
5 is a flowchart illustrating a glaze processing process in an embodiment of the present invention.
6 is a perspective view showing another embodiment of the present invention.
FIG. 7 is a block diagram for explaining the cooling system of the embodiment shown in FIG.

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

FIG. 2 is an exploded perspective view of a cereal refrigerator of a first embodiment of the present invention, and FIG. 3 is a sectional view of a first embodiment of the present invention.

2, a diaphragm 109 is installed in the housing 102 of the refrigerator 100, a grain storage part 105 is formed in the space formed by the upper part of the inside of the housing 102 and the upper part of the diaphragm 109, The grain storing section 105 stores grains such as rice.

The diaphragm 109 is disposed inside the housing 102 and is formed in a plate shape that is inclined upwards toward the wall of the housing 102 with a curved portion having a straight shape formed with a through hole 113 as a center.

A through hole 114 is formed between one end of the diaphragm 109 and the bent portion of the diaphragm 109 so as to extend from the other end of the diaphragm 109 to the other end of the diaphragm 109, The upper end of the cooling vessel 155 is located in the upper part of the grain storage part 105 which is the upper part of the diaphragm and the lower end part of the cooling vessel 155 of the diaphragm 109 And is provided so as to protrude downward from the lower surface. Also, the cool stored in the grain storage part 105 is cooled by the cool air discharged from the upward protruding part of the upper surface of the partition plate 109 of the cooling vessel 155.

The lower part of the partition plate 109 is provided with a horizontal partition wall 115 parallel to the lower surface 119 of the housing 102. A cooling device 130 is installed upwardly on the upper surface of the partition wall 115, (155) passes through the through hole (114).

The reason why the lower end of the cooling vessel 155 is positioned below the diaphragm 109 is that when the water is formed in the cooling vessel 155 by water, To be discharged from the lower portion of the diaphragm 109 so as not to be contacted.

The through hole 113 of the partition wall 109 is opened and closed by the opening and closing device 111 operated by the discharge handle 103. When the discharge handle 103 is pushed to one side, the through hole 113 is opened, The grain stored in the tray 105 is discharged to the discharge cylinder 107 through the through hole 113 and the discharge handle 103 is pushed to the other side to close the through hole 113, It is not discharged.

The partition 115 is installed at a predetermined distance from the lower surface 119 of the housing 102 so that a space is formed and a discharge tube 117 is installed on the lower surface 119 of the housing 102.

A compressor 135 for compressing the refrigerant supplied to the cooling device 130 is installed in the lower space of the partition 115.

4 is a cross-sectional view illustrating the cooling apparatus of Fig.

The cooling apparatus 130 shown in FIG. 4 includes a support plate 139 installed on the upper surface of the partition 115, a support plate 115 installed on the support plate 139 and passing through the through hole 114 of the partition 109 to be separated from the upper surface of the partition 115 A cooling container 155 which protrudes upward to cool the grain of the grain storing section 105 and an evaporator 155 spirally wound on a support section 153 provided inside the cooling container 155 to cool the cooling container 155 (154).

A heater 151 is installed in a space between the cooling container 155 and the support unit 153 to remove ice and sexuality generated in the cooling container 155 by the periodic operation of the heater 151, An insulating layer 150 is provided between the heater 151 and the evaporator 154. A temperature sensor 169 is installed inside the cooling vessel 155. The controller 135 controls the operation of the apparatus such as the compressor 135 and the heater 151 by a controller not shown due to the sensed temperature of the temperature sensor 169, do.

A through hole is formed in the wall surface of the cooling vessel 155 or the support plate 130 to allow the drawer and the inlet of the evaporator 154 to pass therethrough, A through hole is formed so that the tubes 141 and 143 pass through.

Further, the cooling vessel 155 is formed in a tubular shape, preferably a cylindrical shape, with its bottom opened, and is installed on the support plate 130, and the outer surface of the portion protruding from the upper surface of the diaphragm contacts the grains to cool the grains.

In addition, the cooling container 155 is made of a far-infrared emitting material such as ceramics or loess material. The cooling container 155 is provided on one side of the inner wall or the outer wall of the cooling container 155 to prevent moisture in the cooling container, Or both of them are formed or installed.

The opaque layer 57 is formed by coating resin on the inner and outer walls of the cooling vessel so as not to allow moisture to pass therethrough, or by glazing and sintering.

5 is a flowchart illustrating a glaze processing process in an embodiment of the present invention.

First, a material (far-infrared radiation material such as yellow soil or ceramics) is formed according to the specified shape and size (S100). After the primary molding, the molded product is naturally dried for 30 hours using sunlight and wind (S110). The naturally dried shaped material is firstly fired at a high temperature of 900 DEG C to 950 DEG C for 12 hours (S120). The inner peripheral surface of the roughly cooled container 155 is mixed with the glaze solution mixed at a weight ratio of 75 to 80% by weight of water and 20 to 25% by weight of glaze. In this case, feldspar, which is the main component of igneous rock, is often used as glaze (S130). The cooling container 55 with the glaze solution is fired at 1150 DEG C for 12 hours at a high temperature of 1220 DEG C for 15 hours so that the glaze is fired on the inner circumferential surface and fired, .

At this time, the glaze may be applied to the inner wall or the outer wall of the cooling vessel 155 and may be applied to both the inner and outer walls. However, when only the inner wall is used, It is most preferable because it can contain some moisture in the cooling vessel 155 itself even though it can not pass through the wall.

6 is a perspective view showing another embodiment of the present invention.

In the embodiment shown in FIG. 6, the water purifier 200 is installed in addition to the grain refrigerator 100 of the embodiment shown in FIGS. 2 to 5, and the cooling refrigerant is supplied to the cereal refrigerator 100 and the water purifier 200 It is advantageous in that the cost is much lower and the installation space is much smaller than that in the case where the cooling system is separately formed in the cereal refrigerator 100 and the water purifier 200 because the circulation structure is formed.

FIG. 7 is a block diagram for explaining the cooling system of the embodiment shown in FIG.

The refrigerator 100 is provided with a compressor 135 and a condensation depressurization unit 136. The low temperature liquid refrigerant discharged from the condensation depressurization unit 136 is distributed from the three- The refrigerant is vaporized by the evaporator 154 and the evaporator 207 which cools the cold water tank 203 of the water purifier 200. The vaporized refrigerant then returns to the compressor 135 and is converted into high temperature and high pressure refrigerant.

A temperature sensing sensor 209 is installed in the cooling container 155. A temperature sensing sensor 211 is installed in the cold water container 203. The temperature sensed by the temperature sensing sensors 209 and 211 is controlled by the control unit Way valve 201 and the compressor 215 by supplying a control signal to the valve driving unit 213 and the compressor driving unit 215 according to the sensed temperature and the program by the control unit 205 .

The control unit 205 controls the temperature of the inside of the cooling container 155 to be maintained at -15 캜 to 3 캜 and maintains the temperature of the water stored in the cold water container 203 to be 0 캜 to 6 캜. When the internal temperature of the cooling container 155 exceeds 3 DEG C and the water temperature of the cold water container 203 exceeds 6 DEG C, the control unit 205 controls the evaporator 154 to cool the refrigerant discharged from the condensation / And the evaporator 207. When the internal temperature of the cooling container 155 becomes lower than -15 ° C and the water temperature of the cold water container 203 becomes lower than 0 ° C So that the refrigerant discharged from the condensation / depressurization portion 136 is not supplied to both the evaporator 154 and the evaporator 207.

When the internal temperature of the cooling container 155 is between -15 DEG C and 3 DEG C and the water temperature of the cold water container 203 is between 0 DEG C and 6 DEG C, And controls the valve driving unit 213 and the compressor driving unit 215 so that the refrigerant is supplied to the evaporator 154 and the evaporator 207 by the time.

100: grain refrigerator 102: housing
105: grain storage section 109: diaphragm
130: Cooling unit 135: Compressor
155: cooling vessel

Claims (5)

A grain refrigerator in which a diaphragm is provided inside a housing, and inside of the housing and an upper part of the diaphragm form a grain storage part for storing grain, the refrigerator comprising:
And a cooling vessel for accommodating therein a cooling device which has a lower end protruding downward from a lower surface of the partition plate and an upper end located in the grain storing part to cool grain in the grain storing part,
The diaphragm is formed in a plate shape inclined upwards toward a wall of the housing with a straight bent portion as a center, the length of the diaphragm to one end of the diaphragm is longer than the length of the other end of the diaphragm And a through hole is formed between the one end and the bent portion, and the cooling vessel passes through the through hole. The grain refrigerator of claim 1, wherein a wall of the cooling vessel is formed with a non-permeable layer through which water can not pass. delete delete delete

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