KR20090005804A - Foodwaste drier - Google Patents

Abstract

A food drying device is provided to allow the crops or food to be dried more rapidly without mechanical dehydrating process. A food drying device comprises a housing(100); an air pipe(118); an inner partition(130) which comprises two heat conductor plates connected electrically each other for absorbing or discharging the heat by a thermoelectric element(150), is installed vertically in the housing and is provided with a plurality of penetration holes for the circulation of air between a reservoir and a heat exchange room(120); a reservoir(111); a reservoir supporting member(112); and a lower base(113).

Description

Food Dryer {foodwaste drier}

The present invention relates to a food drying processor capable of quickly drying the moisture of grains or foods, and more particularly, to condensed water from moisture contained in grains or foods by using a thermoelectric element and a heat conduction plate while circulating air in a reservoir. By forming a so that it can be discharged to the outside, it relates to a food drying processor to be able to dry the grain or food in the storage more quickly.

In general, the grain storage for storing grains such as rice or grains is applied to the cooling means for maintaining the inside of the storage at a low temperature to maintain the freshness of the storage in the high storage, the cooling means is an evaporator provided with a refrigerant on the refrigerant line Compressors, condensers, expansion valves are sequentially configured to cool the storage inside the reservoir.

However, the conventional grain storage is not equipped with a separate drying means, and thus the contents stored in the grain storage are stored in a state containing water, there is a problem such that it is difficult to maintain the freshness of the grain for a long time.

On the other hand, when handling radishes, cabbages and other vegetables and vegetables at the Kimchi factory or the agricultural market, vegetable waste generated in large quantities or kitchen garbage, which has recently been a problem, is usually properly landfilled and rotted or dried by incineration. Has been processed.

However, according to the above treatment method, when the food waste is rotted or incinerated, it causes odor by the generated gas, and mosquito flies and the like provides a habitat for pathogens, thereby causing poor environmental conditions and causing hygiene problems. In particular, the kitchen waste has a problem such as that the soil contains a large amount of salt causing pollution.

For this reason, in recent years, incineration of food waste has become common, and since food waste has a relatively high water content, it is not only difficult to process by incineration without mechanical dehydration or a separate drying process, and thus incineration. The cost of supplying a heat source has been pointed out as a disadvantage.

Therefore, the present invention has been made to solve the above problems, the present invention condensed water present in the air inside the reservoir by using the heat absorption and heat generated by the thermoelectric element and the heat conduction plate attached thereto while circulating the air in the reservoir. It is an object of the present invention to provide a food drying processor which can dry and treat grains or foods in a storage room more quickly without a mechanical dehydration process.

The present invention for solving the above problems, the air inlet 115 and the air outlet 116 for the air intake and discharge is formed on the upper portion of the body, the first space for the storage of grain or food inside the body and circulation A housing (100) having a second space for heat exchange of air, the storage chamber (110) and the heat exchange chamber (120) being accommodated in each of the spaces; It is installed between the air inlet 115 and the air outlet 116, and accommodates the blower fan 180 on the air inlet side to form an air flow path between the air inlet and the air outlet according to the operation of the blower fan Air communication pipe 118; It consists of two heat conduction plates electrically connected to absorb or release heat by a thermoelectric element, and is installed vertically inside the housing to distinguish between the first space and the second space, and for air circulation between the storage chamber and the heat exchange chamber. An inner partition 130 having a plurality of through holes formed at a lower end thereof; A storage container 111 accommodated in an internal space of the storage room 110 to store grain or food, and having a plurality of through-holes 111a formed in the body to allow moisture or air to flow in; A storage container support member 112 installed at a lower portion of the storage container to serve as a support leg of the storage container; It is installed on the bottom of the housing to seat the storage container support member and the inner partition wall, it is installed to be inclined to one side so that the condensate generated from the outside of the storage container and the condensate generated from the inner partition can be collected in one place. It is a food drying processor including a lower base (113) forming at least one condensate drain (113a, 113b) for draining the condensate collected in one place.

Food drying processor according to the present invention, the first temperature sensor 171 and the second temperature sensor 172, respectively installed in the upper portion of each space for measuring the temperature of the storage compartment 110 and the heat exchange chamber 120, And a controller 200 electrically connected to the two temperature sensors, the thermoelectric element, and the blower fan to control the current flowing through the thermoelectric element and the operation of the blower fan according to the temperatures of the storage chamber and the heat exchange chamber measured by each sensor. To configure other embodiments.

The food drying processor according to the present invention further includes a first heat insulator 141 and a second heat insulator 142 which are respectively installed on both side surfaces of the inner partition 130 to insulate between the storage compartment and the heat exchange chamber. Embodiments may be constructed.

The food drying processor according to the present invention further includes a heat sink 160 installed at the heat exchange chamber side of the inner partition wall and radiating heat emitted from the heat conduction plate by the thermoelectric element to the space of the heat exchange chamber. Embodiments may be constructed.

In the food drying processor according to each embodiment of the present invention, the air communication pipe 118 may be formed to protrude a predetermined interval from the upper surface of the housing 100 to the outside, the two thermal conductive plates connected to the thermoelectric element In one of the plurality of small bulkheads 132b may be formed to maintain the gap between the two heat conduction plates.

According to the present invention, by circulating the air in the reservoir through the thermoelectric element and the heat conduction plate attached to it to form condensed water from the moisture contained in the grain or food to be discharged to the outside, mechanical dehydration or separate drying process It is useful to be able to dry and store grains or foods in the store more quickly without going through.

These objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the preferred embodiment of the present invention.

1 is a cross-sectional view of the food drying processor according to a preferred embodiment of the present invention, Figure 2 is a cross-sectional view of Figure 1, Figures 3 and 4 illustrate the first and second heat conduction plates constituting the inner partition, respectively. As a detailed view, the food drying processor according to the present invention, as shown in the figure, the housing 100 having a storage chamber 110 and the heat exchange chamber 120 in the inner space, and forming a flow path between the heat exchange chamber and the storage chamber The air communication pipe 118, the storage container 111 accommodated in the interior space of the storage chamber 110, and its support member 112, is installed inclined at the bottom of the housing to condensate in the storage chamber condensate drains (113a, 113b) The first base sensor 171 and the second temperature sensor 172 for measuring the temperature of the lower base 113, the storage chamber 110 and the heat conduction plate 131 discharged to the outside through the heat radiation to the heat exchange chamber Heat sink 160, heat as a result of the detection of the two temperature sensors It is configured to include a controller 200 for controlling the operation of the current and the blower fan of the device.

The inner space of the housing 100 is divided into two spaces by the inner partition 130, and each of the divided spaces has a heat exchange chamber for heat exchange between the storage compartment 110 for storing grain or food and the circulating air. 120 are each formed.

The inner partition wall 130 is composed of two first and second thermal conductive plates 131 and 132 electrically connected to absorb or dissipate heat by the thermoelectric element 150. The housing divides the housing and the heat exchange chamber. It is installed vertically inside the 100. A plurality of through holes 131a and 132a are formed at the lower end of the inner partition wall for air circulation between the storage compartment 110 and the heat exchange chamber 120. Here, the first heat insulator 141 and the second heat insulator 142 may be installed at both sides of the two heat conductive plates to insulate between the storage compartment and the heat exchange chamber. Here, any one of the two thermal conductive plates 131 and 132 connected to the thermoelectric element 150 may be provided with a plurality of small partition walls 132b for maintaining a gap between the two plates, and in the drawing, the second thermal conductive plate 132 may be formed on the second thermal conductive plate 132. The case where the small partition 132a is formed is illustrated. In particular, the two heat conduction plates 131 and 132 electrically connected to the thermoelectric element 150 generate heat and endotherm, respectively. Preferably, in the first heat conduction plate 131, the endotherm occurs, and the second heat conduction plate 132. In the heat generation is preferably configured.

An upper portion of each of the storage chamber 110 and the heat exchange chamber 120 is provided with an air inlet 115 and an air outlet 116 for air intake and discharge, and between the air inlet 115 and the air outlet 116. An air communication pipe 118 is installed and accommodates a blower fan 180 inside the air inlet port side of the air communication pipe 118 to form an air flow path between the air inlet port and the air outlet port according to the operation of the blower fan. Configure it to be. The air communication pipe 118 is formed to protrude a predetermined interval to the outside from the upper surface of the housing 100. In addition, the air communication pipe 118 may be configured by forming an opening so as to draw in the outside air, if necessary.

The storage container 111 is accommodated in the inner space of the storage compartment 110 to store the dry object 101 such as grain or food, and a plurality of through-holes (111a) in the body so that moisture or air can enter And a lower portion thereof is supported by the storage container supporting member 112.

The lower base 113 is installed at the bottom of the housing 100 to allow the storage container support member 112 and the inner partition 130 to be seated, and condensed water generated outside the storage container 111. It is installed to be inclined to one side so that the condensed water generated in the inner partition 130 can be collected in one place. And to form at least one condensate drain (113a, 113b) for the drainage of the condensate (114) gathered in one place, each condensate drain (113a, 113b) is connected to the condensate discharge pipe 117, in the middle By connecting the solenoid valve 117a is configured to control the opening and closing operation by the control unit 200.

The first temperature sensor 171 and the second temperature sensor 172 are installed in the upper portion of each space for measuring the temperature of the storage compartment 110 and the heat conduction plate 131, respectively.

The heat dissipation plate 120 of the inner partition 130 is provided with a heat dissipation plate 160 capable of radiating heat emitted from the heat conduction plates 131 and 132 by the thermoelectric elements 150 into the space of the heat exchange chamber.

The two temperature sensors 171 and 172, the thermoelectric element 150, the blower fan 180, and the solenoid valve 117a are electrically connected to a control unit 200 for controlling their operation, and to the two temperature sensors 171 and 172. It is configured to control the current flowing through the thermoelectric element 150 and the operation of the blower fan 180 and the solenoid valve 117a according to the temperature of the storage chamber 110 and the heat conduction plates 131 and 132 sensed by the heat sink.

Referring to the operation and effect of the present invention configured as described above are as follows.

First, when the dry matter 101 such as grain or food is put into the storage container 111 accommodated in the storage chamber 110 of the housing 100, and the blower fan 180 is operated through the control unit 200, the heat exchange chamber The dry air of the 120 is sucked through the air inlet 115 and then supplied to the storage compartment 110 through a flow path formed along the air communication pipe 118 and the air outlet 116. At this time, when there is a dry object 101 containing moisture in the storage container 111, the moisture contained in the dry object 101 is converted into wet air while absorbing the introduced dry air. The moist air passes through the through holes 131a and 132a formed in the inner partition 130 and the heat sink 160 of the heat exchange chamber 120 in order to form condensed water and is converted back into dry air. 1) while repeating the flow into the air flow occurs in the direction of the arrow as shown in Figure 1, while the rotation of the air is repeatedly formed to form condensed water to the dry object 101 in the storage container 111 It can dry quickly.

That is, in the air flow process, the moisture contained in the dry matter 101 placed in the storage container 111 inside the storage chamber is mixed with the dry air introduced from the heat exchange chamber 120 while the through hole 111a of the storage container 111 is provided. The air exiting the air is changed into wet air, and a part of the air is introduced into the heat exchange chamber 120 through the through holes 131a and 132a formed in the lower portion of the inner partition 130 and dried while passing through the protrusions of the heat sink 160. Changed to air.

In addition, a part of the moisture contained in the humid air is converted into condensate at the outer wall of the storage container 111 is collected along the bottom surface of the lower base 113 of the lower part of the storage chamber to the condensate drain 113a, and also in the humid air Some of the moisture included is converted into condensed water in the space between the two heat conductive plates held by the plurality of small partition walls 132b by the heat insulating materials 141 and 142 and the first and second thermal conductive plates 131 and 132. The condensate drain 113b is collected.

In this case, the controller 200 senses the temperature detected by the first temperature sensor 171 and the second temperature sensor 172 respectively installed in the upper portion of each space for measuring the temperature of the storage chamber 110 and the heat exchange chamber 120. By controlling the current flowing through the thermoelectric element 150 and the operation of the blower fan 180 it is possible to control the drying of the dry object according to the air flow, the control unit 200 of the solenoid valve 117a It is possible to discharge the condensate to the outside through the condensate discharge pipe 117 by controlling the opening and closing operation.

1 is a cross-sectional view of the food drying processor according to a preferred embodiment of the present invention,

2 is a plan sectional view of FIG. 1;

3 and 4 are detailed views illustrating the first and second thermal conductive plates constituting the inner partition wall, respectively.

<Explanation of symbols for the main parts of the drawings>

100 housing 101 to be dried

110: storage chamber 111: storage container

111a, 131a, 132a: Through hole 112: Storage container support member

113: lower base 113a, 113b: condensate drain

114: condensate 115: air intake

116: air outlet 117: condensate discharge pipe

117a: solenoid valve 118: air communication piping

120: heat exchange chamber 130: internal partition

131, 132: first and second heat conduction plate 132b: small bulkhead

141, 142: heat insulating material 150: thermoelectric element

160: heat sink 171,172: temperature sensor

180: blowing fan 200: control unit

Claims (6)

An air inlet 115 and an air outlet 116 for air intake and exhaust are formed on the upper portion of the body, and a storage container 111 for storing a dry object in an inner space divided by an inner partition 130 is accommodated. A housing 100 in which a heat exchange chamber 120 for heat exchange between the storage chamber 110 and the circulating air is formed; It is installed between the air inlet 115 and the air outlet 116, and accommodates the blower fan 180 on the air inlet side to form an air flow path between the air inlet and the air outlet according to the operation of the blower fan Air communication pipe 118; It consists of two heat conduction plates 131 and 132 electrically connected to absorb or release heat by the thermoelectric element 150 and is installed vertically in the housing, and includes a plurality of through holes for air circulation between the storage compartment and the heat exchange chamber. Internal partitions 130 having 131a and 132a formed at lower ends thereof; A storage container 111 accommodated in an internal space of the storage room 110 to store a dry item, and having a plurality of through-holes 111a formed in the body to allow moisture or air to flow in and out; A storage container support member 112 installed at a lower portion of the storage container to serve as a support leg of the storage container; It is installed on the inner bottom of the housing to seat the storage container supporting member and the inner partition wall, and is installed to be inclined to one side so that the condensate generated from the outside of the storage container and the condensate generated from the inner partition wall can be collected in one place. And a lower base (113) for forming at least one condensate drain (113a, 113b) for draining the condensate collected in one place. The method of claim 1, A first temperature sensor 171 and a second temperature sensor 172 respectively installed at an upper portion of each space for measuring the temperature of the storage compartment 110 and the heat conduction plate 131; And a controller 200 electrically connected to the two temperature sensors, the thermoelectric element, and the blower fan to control the current flowing through the thermoelectric element and the operation of the blower fan according to the temperatures of the storage chamber and the heat exchange chamber measured by each sensor. Food drying processor, characterized in that configured. The method of claim 1, And a first heat insulator 141 and a second heat insulator 142 which are respectively installed on both sides of the inner partition 130 to insulate the storage compartment and the heat exchange chamber. The method of claim 1, And a heat dissipation plate (160) installed at the heat exchange chamber side of the inner partition and radiating heat emitted from the heat conduction plate by the thermoelectric element to the space of the heat exchange chamber. The method of claim 1, The air communication pipe 118 is a food drying processor, characterized in that formed to protrude a predetermined interval to the outside from the upper surface of the housing (100). The method of claim 1, And a plurality of small partition walls 132b for maintaining a gap between the two thermal conductive plates on any one of the two thermal conductive plates connected to the thermoelectric elements.

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