KR19990062178A - Rice bucket - Google Patents

Abstract

The present invention relates to a rice container for cooling the rice storage tank using a thermoelectric semiconductor device. According to an aspect of the present invention, a rice container includes: a rice container including a rice storage container, comprising: a thermoelectric semiconductor element having a heat generating part located outside the rice storage container and a heat absorbing part exposed inside the rice storage container; It is coupled to the heat absorbing portion, and includes a heat transfer member protruding toward the inside of the rice storage container. As a result, the temperature inside the rice reservoir can be maintained uniformly, thereby improving the thermal efficiency of the thermoelectric semiconductor element.

Description

Rice bucket

The present invention relates to a rice container for cooling the rice storage tank using a thermoelectric semiconductor device.

The thermoelectric semiconductor device uses a thermoelectric phenomenon that generates and absorbs heat other than Joule heat when a current flows through a junction surface of a semiconductor and a metal. The amount and direction of heat absorption and heat generation can be controlled by the magnitude and direction of the current. In addition, there is no mechanically operating part, and also has an advantage that the installation position or direction does not affect its operation, and thus is widely used to heat or cool a load, and the configuration thereof is shown in FIG. 1.

1 is a schematic configuration diagram of a thermoelectric semiconductor device, and FIG. 2 is a schematic configuration diagram of a thermocouple of FIG. 1.

As shown in these figures, the thermoelectric semiconductor element 1 has a thermocouple portion 2 in which a plurality of semiconductor thermocouples are connected in series, and in the center of the thermocouple portion 2 is an N-type semiconductor 7 and There is a P-type semiconductor 8. The internal connection metal 9 and the external connection metals 10 and 11 are coupled to both sides of the N-type semiconductor 7 and the P-type semiconductor 8, and the internal connection metal 9 includes the semiconductors 7 and 8. In common with the external connection metal (10, 11) is coupled to the semiconductor (7, 8) independently. In particular, the external connection metals 10, 11 are extendable outward for series connection with other thermocouples. Here, which of the internal connection metal 9 and the external connection metals 10 and 11 is the heat generating side metal and which metal is the heat absorbing side metal is determined according to the direction of the current. That is, the metals 9 and 10 joined to the N-type semiconductor 7 generate heat from the metal on the side where the current flows and endothermic on the opposite side, and the P-type semiconductor 8 generates heat and endotherms in reverse. Insulating plates 3 and 4 are coupled to the metals 9, 10 and 11 of the thermocouple part 2, respectively, and the insulating plates 3 and 4 are metals 9, 10 and 11 of the thermocouple part 2. ) Is electrically isolated from the outside. The heater plates 5 and the cold sink 6 as the heat absorbing portion are respectively coupled to the insulating plates 3 and 4, and the heater sink 5 and the cold sink 6 are respectively connected to the thermocouple portion 2. ) Physically support the metal in the heat dissipation or absorption.

The calorific value and endothermic amount of the thermoelectric semiconductor element increase in proportion to the magnitude of the current and the absolute temperature of the semiconductor and the metal junction surface, respectively, and the temperature of the heat-generating metal is kept higher than the temperature of the heat absorbing metal by a constant difference. The thermoelectric semiconductor element can be used to cool the rice reservoir of the rice barrel using the.

3 is a schematic configuration diagram of a rice container.

As shown in this figure, the rice container has a main body 21 forming an appearance, and a viewing window 23 on which the rice storage amount can be seen from the outside on the side of the main body 21, the lower part of the viewing window 23. The rice withdrawal button 24 for extracting rice to the outside is formed at the lower portion of the rice withdrawal button 24, respectively. The upper portion of the main body 21 is covered with a lid 22, the lower portion of the other side of the main body 21 is formed with an air outlet 26 for discharging the hot air to the outside.

4 is a longitudinal sectional view of a conventional rice container using a thermoelectric semiconductor element.

As shown in this figure, the conventional rice barrel has a cold sink on the bottom surface of the main body 31 forming the appearance, the rice reservoir 38 formed inside the upper portion of the body 31, and the rice reservoir 38 It has a thermoelectric semiconductor element 41 to which 43 is coupled. A viewing window 33, a rice withdrawal button 34 and a rice outlet 35 are formed on the side of the main body 31, and the upper part is covered with a lid 32. The thermocouple portion 42 and the heat sink 44 of the thermoelectric semiconductor element 41 are provided below the bottom surface of the rice storage container 38. The cold sink 43 and the heat sink 44 are joined by a screw 45, and the bushing 46 is coupled with the screw 45 and the heater sink to block heat transfer from the heat sink 44 to the cold sink 43. Between 44. The cooling fan 48 is provided in the lower part of the heat sink 44, and the air filter 49 is provided in the lower part of the cooling fan 48, respectively. The surface of the rice reservoir 38 is attached to the rice reservoir temperature sensor 47 for detecting the temperature inside the rice reservoir 38, the outer wall of the rice reservoir 38 is surrounded by a heat insulating wall 37.

The temperature inside the rice reservoir of the rice container having such a configuration is controlled by the controller, when the thermoelectric semiconductor element 41 is operated, the cold sink 43 absorbs the heat in the rice reservoir 38, that is, the rice reservoir 38 ) Is cooled and heat is released from the heater sink 44. At this time, the cooling fan 48 blows cooling air toward the heat sink 44 to increase heat dissipation. When the temperature inside the rice reservoir 38 falls below a predetermined storage temperature of the rice, the controller stops the operation of the thermoelectric semiconductor element 41 and the cooling fan 48.

By the way, in the conventional rice container, the heat exchange between the rice storage container 38 and the thermoelectric semiconductor element 41 is mainly made through the cold sink 43 exposed inside the rice storage container 38, and the inside of the rice storage container 38 is made. The temperature deviation is high. Therefore, the thermoelectric semiconductor device has to be operated for a long time in order to maintain the lowest temperature in the rice storage container 38 below the predetermined storage temperature of the rice, thereby reducing the thermal efficiency of the thermoelectric semiconductor device.

Accordingly, an object of the present invention is to provide a rice container that can maintain a uniform temperature inside the rice storage container to improve the thermal efficiency of the thermoelectric semiconductor device.

1 is a schematic configuration diagram of a thermoelectric semiconductor device,

2 is a schematic configuration diagram of the thermocouple of FIG.

3 is a schematic configuration diagram of a rice container,

4 is a longitudinal sectional view of a conventional rice container using a thermoelectric semiconductor element,

5 is a longitudinal sectional view of a rice container according to the present invention;

Figure 6 is a control block diagram of the temperature inside the rice reservoir according to the present invention.

Explanation of symbols for main parts of the drawings

1, 41, 71: thermoelectric semiconductor elements 2, 42, 73: thermocouple portion

3, 4: insulation plates 5, 44, 75: heater sink

6, 43, 74: Cold sink 7: N-type semiconductor

8: P-type semiconductor 9: Internal connection metal

10, 11: external connection metal 21, 31, 51: main body

23, 33, 53: sight glass 37, 57: heat insulation wall

38, 58: rice storage 47, 63: rice storage temperature sensor

48, 61: cooling fan 49, 62: air filter

81: control unit 82: thermoelectric semiconductor element start switch

84: thermoelectric semiconductor element driving circuit 85: cooling fan drive circuit

According to the present invention, there is provided a rice container having a rice storage container, comprising: a thermoelectric semiconductor element having a heat generating portion located outside the rice storage container and an endothermic portion exposed inside the rice storage container; Is coupled to the heat absorbing portion, and is achieved by a rice barrel including a heat transfer body protruding toward the inside of the rice reservoir.

Here, the heat transfer member may be configured to be screwed to the heat absorbing portion.

In addition, the rice reservoir temperature sensor for detecting the internal temperature of the rice reservoir; It may be configured to further include a control unit for controlling the thermoelectric semiconductor element to stop the operation, when the temperature inside the rice reservoir falls below a predetermined temperature.

In addition, a cooling fan for blowing cooling air toward the heat generating portion; The higher the internal temperature of the rice reservoir, it can be configured to further include a control unit for controlling the cooling fan to increase the rotational speed.

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

5 is a longitudinal sectional view of a rice container according to the present invention.

As shown in this figure, the rice container according to the present invention has a main body 51 forming an appearance, a rice storage container 58 formed inside the upper part of the main body 51, and a bottom surface of the rice storage container 58. The thermoelectric semiconductor element 71 to which the cold sink 74 is coupled, and the heat transfer rod 64 screwed with the cold sink 74 of the thermoelectric semiconductor element 71 are included. A viewing window 53, a rice withdrawal button 54, and a rice withdrawal port 55 are formed on the side of the main body 51, and an upper portion thereof is covered with a lid 52. The thermocouple portion 73 and the heat sink 75 of the thermoelectric semiconductor element 71 are provided below the bottom surface of the rice storage container 58. The cold sink 74 and the heat sink 75 are joined by a screw 76, and the bushing 77 has a screw 76 and a heater sink to block heat transfer from the heat sink 75 to the cold sink 74. It is mounted between 75. The cooling fan 61 is provided in the lower part of the heat sink 75, and the air filter 62 is provided in the lower part of the cooling fan 61, respectively. The surface of the rice reservoir 58 is attached to the rice reservoir temperature sensor 63 for detecting the temperature inside the rice reservoir 58, the outer wall of the rice reservoir 58 is surrounded by a heat insulating wall (57).

The temperature inside the rice reservoir of the rice container having such a configuration is controlled by the controller, Figure 6 is a control block diagram of the internal temperature of the rice reservoir according to the present invention.

The control unit 81 in charge of the overall control, the temperature in the rice storage container 58 and the start signal of the thermoelectric semiconductor device 71 is input from the rice storage container temperature sensor 63 and the thermoelectric semiconductor device start switch 82, respectively, The driving circuits 84 and 85 are connected to the thermoelectric semiconductor element 71 and the cooling fan 61 to control driving.

The control unit 81 having such a peripheral configuration drives the thermoelectric semiconductor element 71 by controlling the thermoelectric semiconductor element driving circuit 84 when the start signal is input to the thermoelectric semiconductor element starting switch 82. When the thermoelectric semiconductor element 71 is operated, the cold sink 74 and the heat transfer rod 64 absorb the heat in the rice reservoir 58, that is, cool the rice reservoir 58, and heat is removed from the heater sink 75. Is released. At this time, the heat exchange with the inside of the twin reservoir 58 is made evenly through the heat transfer rod 64 protruding into the rice reservoir 58, as well as the cold sink 74 exposed inside the rice reservoir 58. The temperature inside the rice reservoir 58 is kept uniform. The control unit 81 also controls the cooling fan drive circuit 85 to blow cooling air toward the heat sink 75. At this time, the higher the internal temperature of the rice storage container 58, the cooling fan 61 is controlled to increase the rotational speed. When the temperature inside the rice reservoir 58 falls below a predetermined storage temperature of the rice, the controller 81 controls the thermoelectric semiconductor element driving circuit 84 and the cooling fan driving circuit 85 to control the thermoelectric semiconductor element 71. And the operation of the cooling fan 61 is stopped.

Therefore, according to the present invention, in cooling the rice storage container, it is possible to improve the thermal efficiency of the thermoelectric semiconductor device by maintaining a uniform temperature inside the rice storage container.

Claims (5)

In a rice barrel with a rice reservoir, A thermoelectric semiconductor element having a heat generating part positioned outside the rice storage container and an endothermic part exposed inside the rice storage container; Coupled to the heat absorbing portion, characterized in that the rice barrel comprising a heat transfer body protruding toward the inside of the rice reservoir. The method according to claim 1, The heat carrier is a rice barrel, characterized in that the threaded portion coupled to the heat absorbing portion. The method according to claim 1 or 2, A rice reservoir temperature sensor for detecting an internal temperature of the rice reservoir; And a control unit for controlling the thermoelectric semiconductor element to stop the operation when the temperature inside the rice storage container drops below a predetermined temperature. The method according to claim 1 or 2, A cooling fan for blowing cooling air toward the heat generating unit; The rice container further comprises a control unit for controlling the cooling fan to increase the rotational speed, the higher the internal temperature of the rice reservoir. The method according to claim 3, A cooling fan that blows cooling air toward the heat generating unit; The control unit, the rice container, characterized in that for controlling the cooling fan so that the rotational speed increases as the internal temperature of the rice storage container is higher.