KR20100064625A - Food treatment apparatus including air flow means - Google Patents

Abstract

PURPOSE: A food processor including an air flow unit is provided to improve energy efficiency while reducing heating time by heating the surface and the inside of the food waste received in a cavity with microwaves. CONSTITUTION: A food processor includes the following: a cavity(100) receiving food waste; a microwave producing part(150) supplying microwaves to the cavity to heat and dry the food waste; and an air flow unit(400) improving drying efficiency of the food waste. The air flow unit blows the air in the cavity to the inner side of the cavity. The air flow unit comprises a fan(140), an air guide(160), an intake duct(170), and a vent duct(180).

Description

Food processor including air flow means {FOOD TREATMENT APPARATUS INCLUDING AIR FLOW MEANS}

The present invention relates to a food processor, and more particularly, to a food processor including air flow means for supplying air into the cavity or discharging the air inside the cavity to the outside.

Food wastes generated at homes and factories contain a lot of moisture, so they are bulky when discharged, and if left for a long time, they become decayed, causing odors or destroying the environment. Therefore, a food processor has been developed to remove the large amount of water contained in the food waste to reduce its volume, suppress corruption, and reduce environmental pollution.

The present invention provides a food processor of the direct heating method which reduces heating time and improves energy efficiency by simultaneously heating the surface and the inside of the food contained in the cavity.

In addition, to reduce the amount of water vapor inside the cavity to promote food drying, the outside air may be supplied into the cavity, or the humid air inside the cavity caused by the evaporation of water may be discharged to the outside to improve the drying efficiency of the food. Provides a food handler that can be used.

In addition, by recycling the heat obtained when cooling the microwave generating unit provided as a heating means of the food to the inside of the cavity provides a food processor that can shorten the drying time and reduce energy consumption.

In addition, it provides a food processor that can block the leakage of microwaves to the outside through the inlet or outlet passage of air.

The technical problem to be achieved by the present invention is not limited to the technical problem mentioned above, and other technical problems not mentioned above may be clearly understood by those skilled in the art from the following description. will be.

Food treatment apparatus of the present invention for realizing the above object, the cavity for receiving food; A microwave generator for supplying microwaves for heating and drying the food to the cavity; Air flow means for introducing air into the cavity or discharging the air inside the cavity to the outside; Including it may improve the drying efficiency of the food.

In one embodiment, the air flow means blows air outside the cavity through the microwave generator and then blows into the cavity.

In one embodiment, the air flow means shields external leakage of the microwaves supplied inside the cavity.

According to the food processor of the present invention configured as described above, by heating the surface and the inside of the food accommodated in the cavity at the same time with a microwave to reduce the heating time and improve the energy efficiency of the food processor of the direct heating method, By circulating the air, the amount of water vapor in the cavity can be lowered to promote drying of food, and the heat obtained when cooling the microwave generator can be recycled into the cavity to shorten the drying time and reduce energy consumption. Alternatively, the microwave may be prevented from leaking to the outside through the discharge passage.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In this process, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms that are specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. Definitions of these terms should be made based on the contents throughout the specification.

1 is a side cross-sectional view showing the structure of a food processor including an air flow means of the present invention. Figure 2 is a perspective view showing the main part of the food processor including the air flow means of the present invention. 1 and 2 together, the configuration and operation of the air flow means of the present invention and the food processor including the same will be described in detail.

The illustrated food 10 processor includes a main body 110 forming an exterior, a cavity 100 provided inside the main body 110 to accommodate the food 10, and a micro to supply microwaves to the food 10 to dry it. The wave generator 150 and the air flow means 400 for circulating the air in the cavity (100).

Food 10 is accommodated in the cavity 100, and both sides of the cavity 100 are blocked by a pair of side walls 105.

The microwave generator 150 is provided above the cavity 100. Although not shown, the microwave generator 150 includes a magnetron for generating a microwave, a high voltage transformer and a high voltage capacitor for generating a high voltage required to drive the magnetron. At this time, high heat is generated in electrical components such as magnetron, high voltage transformer, and high voltage capacitor, and a cooling fin 152 for cooling it and a fan 140 for circulating air in the cooling fin 152 are further provided. .

The microwave generated by the microwave generator 150 may be supplied to the cavity 100 through the waveguide 154 to improve energy efficiency. Cavity 100 and waveguide 154 are connected to each other by waveguide connection 155. The waveguide connection 155 suppresses the food 10 or moisture inside the cavity 100 from penetrating into the waveguide 154 while the microwave supplied to the waveguide 154 is well delivered into the cavity 100. For example, a member of a membrane structure having a plurality of holes or slits is attached to an end of the waveguide 154.

Meanwhile, a large amount of water vapor is discharged when drying the food 10 in the cavity 100, and lowering the amount of water vapor in the cavity 100 may promote drying of the food 10. That is, the temperature of the food 10 is increased by direct heating of the food 10 by microwaves, and when the humidity inside the cavity 100 is lowered, the drying time is high and the drying time may be greatly shortened. To this end, by providing the air flow means 400 above the cavity 100, which may be a flow path of air as a free space in which the food 10 is not accommodated, it is possible to immediately discharge water vapor inside the cavity 100. desirable.

To this end, in order to lower the amount of water vapor in the cavity 100, an embodiment of simply supplying outside air into the cavity 100, and rapidly discharging air inside the cavity 100 to the outside of the cavity 100. Embodiment, while supplying relatively dry outside air into the cavity 100, it is possible to quickly discharge the humid air inside the cavity 100 to the outside. Here, by supplying hot air by recirculating the hot air discarded when cooling the microwave generator 150 into the cavity 100, it is possible to further promote the drying of the food (10).

In one embodiment, the air flow means 400, the fan 140 for blowing hot air generated at the same time as cooling the microwave generating unit 150 to the air guide 160, the air guide 160, the intake duct 170, exhaust duct 180. The intake port 163 connects the air guide 160 and the intake duct 170, and the exhaust port 183 connects the exhaust duct 180 and the deodorization filter 185. The flow path of air is shown by the dashed arrows in FIG. 1.

On the other hand, if a microwave leaks outside the cavity 100 through various air passages provided in the air flow means 400, a safety accident may occur. Therefore, it is preferable that the air inlets 171 and 181, which are minute holes of 0.5 to 3 mm in diameter, are formed in the intake duct 170 and the exhaust duct 180 so that microwaves are not leaked to the outside without disturbing the flow of air. . As an embodiment of blocking the leakage of the microwave, not only embodiments of reducing the diameters of the air holes 171 and 181 but also embodiments of increasing the depth of the air holes 171 and 181 are possible.

In addition to preventing the leakage of microwaves, the air holes 171 and 181 having a fine diameter may have food 10, moisture, and other foreign matter penetrated into the microwave generator 150 through the intake duct 170 or the exhaust duct 180. To prevent leakage to the outside or to contaminate the deodorizing filter 185 through.

On the other hand, there is a need for means that can prevent odor generated in the food 10 processing unit. To this end, it is preferable to provide anion generator 162 on the intake side of the cavity 100 and to provide a deodorization filter 185 on the exhaust side of the cavity 100.

In one embodiment, the hot air around the cooling fins 152 cooling the microwave generating unit 150 to promote drying of the food 10 and improve energy efficiency by hot air circulation. Drive to supply to the air guide 160, the air supplied to the air guide 160 receives the anion through the negative ion generating unit 162, the air discharged through the exhaust port 183 is a deodorization filter (185) ) To prevent odors.

The anion generator 162 generates an anion and supplies it to the cavity 100, and the anion supplied into the cavity 100 reacts with the malodorous component of the food 10 and replaces it with an odorless component. The malodorous component not detected by the negative ion generating unit 162 is filtered by the deodorizing filter 185 connected to the exhaust duct 180.

On the other hand, the food 10 is injected into the upper side of the cavity 100, the door 190 is provided for opening and closing the cavity 100. In one embodiment, the door 190 is rotatably connected by the main body 110 and the door hinge 114.

In addition, a portion of the door 190 and the cavity 100 in contact with each other is preferably provided with a shielding layer 194 for blocking the microwave so that the microwave does not leak to the outside. As one of methods for blocking microwaves, a conductive material or a radio wave absorber may be used. For example, the shielding layer 194 may be formed of conductive rubber, the ferrite radio wave absorber may be mixed with rubber or plastic to form the shielding layer 194, or the ferrite powder and the conductive carbon powder may be mixed with a binder to shield the layer 194. In some embodiments, the shielding layer 194 may be formed by mixing the ferrite powder and the conductive fiber of the long axis, or the shielding layer 194 may be formed of the uneven structure so that the microwaves are reflected to cancel each other.

In addition, the bottom surface of the cavity 100 is provided with a discharge port 130 for discharging the dried food 10 to the outside. The outlet 130 is opened and closed by the shutter 120. Although the embodiment in which the shutter hinge 122 is provided as the opening / closing means of the shutter 120 and the shutter 120 is rotated is illustrated, an unillustrated embodiment in which the shutter is opened and closed by sliding left and right or lifting up and down is also possible.

And it is preferable that the stirring means 200 which stirs the food 10 is further provided. When only a specific portion of the food 10 is heated, a fire occurs locally or the drying efficiency is lowered, so that the stirring means 200 is provided to evenly stir the food 10. That is, the microwave generator 150 is provided to implement a direct heating structure for heating the outside and the inside of the food 10 at the same time, and the stirring means 200 is provided for the uniform heating of the food 10. The stirring means 200 has a rotating shaft 210 which is rotated inside the cavity 100 and a stirring blade 220 which is fixed to the rotating shaft 210 and rotates together.

In addition, the optical sensor 500 is provided on the upper side of the cavity 100 to detect whether the door 190 is opened or whether sparks are generated in the cavity 100, and the door 190 is opened or the cavity ( It is preferable to stop the operation of the microwave generator 150 when sparking occurs in 100.

Although embodiments according to the present invention have been described above, these are merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments of the present invention are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the following claims.

1 is a side cross-sectional view showing the structure of a food processor including an air flow means of the present invention.

Figure 2 is a perspective view showing the main part of the food processor including the air flow means of the present invention.

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

10 ... Food 100 ... Cavity

105.Side wall 110 ... Body

114 door hinge 120 shutter

122.shutter hinge 130 ... outlet

140 ... fan 150 ... microwave generator

152 cooling fin 154 waveguide

155 ... waveguide connection 160 ... air guide

162 Anion generator 163 Intake vent

170 Intake duct 171,181 Air hole

180 Exhaust duct 183 Exhaust vent

185 ... deodorant filter 190 ... door

194 Shielding layer 200 Stirring means

210 ... rotating shaft 220 ... stirring wing

400.air flow means

Claims (7)

Cavities for receiving food; A microwave generator for supplying microwaves for heating and drying the food to the cavity; Air flow means for introducing air into the cavity or discharging the air inside the cavity to the outside to improve drying efficiency of the food; Food processor comprising a. The method of claim 1, And the air flow means blows air outside the cavity through the microwave generator and then blows the air into the cavity. The method of claim 2, The air flow means includes a fan for supplying air outside the cavity to the microwave generator, an air guide for guiding heated air through the microwave generator, and one side is connected to the air guide and the other side is And an intake duct connected to the cavity, and an exhaust duct for discharging air inside the cavity to the outside. The method according to any one of claims 1 to 3, The air flow means is a food processor, characterized in that for shielding the external leakage of the microwave supplied to the inside of the cavity. The method of claim 4, wherein The intake duct and the exhaust duct are formed with a plurality of air holes for the passage of the air, The air hole is a food processor, characterized in that formed in a fine diameter of a size capable of blocking the passage of the microwave. The method of claim 5, The air flow means further comprises a negative ion generating unit for supplying negative ions in the cavity. The method of claim 6, The air flow means further comprises a deodorizing filter connected to the exhaust duct so as to filter the air discharged to the outside of the cavity.

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