KR101011783B1 - Method for Operating Food Garbage Disposer And Food Garbage Disposer - Google Patents

Abstract

The present invention prior to checking the humidity and temperature conditions of the food waste to be dried in the storage of the food waste processor to effectively dry the food waste described above, and at the same time when there is an abnormality such as a short circuit or power failure It is characterized by providing a food waste processor and a method of operation using the same by maintaining the minimum power and stability by allowing the drying to occur.

Food, Garbage, Far Infrared, Dry, Blackout, Humidity, Temperature

Description

Food Garbage Disposer and How to Use it {Method for Operating Food Garbage Disposer And Food Garbage Disposer}

The present invention relates to a food waste processor and an operation method using the same, in which food waste can be dried even in an emergency such as a short circuit or power failure, along with efficient drying of a food waste machine in which the food waste processor is dried.

Generally, household waste and food waste generated at home are thoroughly collected and discharged. In particular, food waste should be discharged in a dry state by reducing the amount of food waste for recycling of resources, prevention of environmental pollution by leachate, effective collection, and transfer to a recycling facility.

Food waste generated at home is easy to decay due to the large amount and moisture, and is not easy to be separated and collected.It is expensive to transport to a recycling facility for recycling, and there are problems in environmental pollution caused by leachate and sanitation of residential environment. Doing.

In view of these problems, many food waste disposal systems that reduce the amount of food waste and remove moisture are commercially available. Recently, food wastes that are not only dried but also fermented with microorganisms are dried. There are also a lot of garbage disposals on the market.

The conventional food waste disposal device has a disadvantage of having to perform drying for a long time in order to dry food waste containing a large amount of moisture. When the food waste disposal device is operated for a long time, the drying efficiency is improved, but the electricity bill is increased accordingly, and the burden of the user's fee is increased, and there is a problem of waiting for a long time until the drying is completed.

This caused a user to wait for a certain time to dry another food waste, or to carry out drying by storing additional wet food waste on the dried food waste.

In addition, in the event of a sudden power outage, the food waste processor itself is shut off and safe, but the drying of the food waste stops, resulting in corruption of the food waste, which can cause severe odors, and the user may restart the food waste processor. There was no other countermeasure except the method that was left as it was until then, and urgent measures were needed.

An object of the present invention is a food waste processor which enables to dry food waste stably by continuing drying of the above food waste even in the event of an abnormal situation such as a power failure together with the effective drying of the food waste stored in the food waste processor and the same. It is to provide a method of operation.

In order to achieve the above object, a food waste disposal system according to the present invention includes: a storage unit provided with a loading plate to discharge a large amount of water contained in food waste; A heating unit which emits far-infrared rays so that the food wastes are dried to dry the food wastes; A duct part provided with a passage so that a part of the far infrared rays radiated from the heating part is moved and supplied to the receiving part; A humidity sensor installed on a main body of the food waste processor to sense humidity when the food waste processor is operated; A temperature sensor for sensing an operating temperature of the heating unit together with the humidity sensor; And receiving the humidity information and the temperature information inside the storage unit detected by the humidity sensor and the temperature sensor during operation of the food waste processor so that the food waste accumulated on the storage plate is dried to reach a target humidity range. It is comprised including the control part which controls the temperature of a heating part.

The base plate according to the present invention includes a first drainage zone in which a plurality of first drainage holes are formed, and a plurality of first drainage holes are formed in a section from each corner and side point of the upper entire area to an area spaced inwardly; And a second drainage zone having a plurality of second drainage holes penetrated in the center of the placement plate except for the first drainage zone.

The first and second drain holes of the first and second drain zones according to the present invention may be arranged in a matrix form.

Assuming that the diameter of the first drain hole according to the present invention is D, the diameter of the second drain hole is characterized in that the ratio relationship of 1.5 * D to 2.0 * D is established.

The second drainage hole according to the present invention is characterized in that the inclined portion is inclined toward the lower center in the longitudinal direction of the second drainage hole.

The mounting plate according to the present invention is characterized in that the handle groove is formed on the side of the mounting plate so that the user can easily withdraw to the outside of the housing.

The heating unit according to the present invention has a heating wire disposed therein, and a heating plate made of ceramic so that far infrared rays are emitted when power is applied to the heating wire, and the wavelengths of the far infrared rays emitted from the heating plate are refracted and placed on the base plate. And a reflecting plate for concentrating the above-mentioned far infrared rays on the collected food waste.

The duct part according to the present invention has one end connected to the heating part and branched to the left and right sides of the main body, respectively, the other end of which is connected to the left and right side wall surfaces of the main body, and one end connected to the first duct. It is provided and extended to the lower side of a main body part, and the other end is comprised including the 2nd duct connected below the accommodating part.

The duct part according to the present invention is characterized in that a duct fan is installed so that high-temperature far-infrared rays radiated from the heating part can flow to the moving passage of the duct part.

The main body according to the present invention is characterized in that a plurality of inlet holes are formed through the left and right sides of the side wall connected to the other end of the first duct through the food waste deposited on the base plate.

The inlet hole of the main body portion according to the present invention is characterized in that it penetrated downwardly toward the center of the receiving portion.

The control method for controlling the food waste processor according to the present invention includes a humidity sensing step of sensing the humidity of the food waste in a state in which the food waste is stored in the food waste processor; A food waste drying step of supplying far-infrared rays radiated from the heating unit to the food waste so that food waste is dried; A current amount adjusting step of changing an amount of current applied to the heating unit according to a humidity state of the food waste to be dried; And an abnormal operation adjusting step of preventing a malfunction of the device caused by an abnormal occurrence during the operation of the food waste processor.

The food waste drying step according to the present invention includes a first drying step in which the far-infrared ray of the heating unit is directly delivered to the food waste and dried, and a second drying step in which the far-infrared is delivered from the side of the food waste, and dried. And a third drying step in which far infrared rays are supplied to one side of the food waste and supplied to the food waste.

The current amount adjusting step according to the present invention includes the first current amount adjusting step of increasing the amount of current applied to the heating part when the humidity of the food waste is high humidity, and the amount of current applied to the heating part when the humidity of the food waste is low humidity. And a second current amount adjusting step of reducing the voltage.

The abnormal operation control step according to the present invention interrupts the power applied to the heating unit in the event of an abnormality such as a short circuit or a power outage, and applies emergency power to the duct fan so that far infrared rays are supplied to the food waste to continue the above food waste. It characterized in that it comprises an emergency drying step to dry.

Hereinafter, with reference to the accompanying drawings, an embodiment of a food waste processor and an operating method using the same according to the present invention will be described with reference to the accompanying drawings.

1 to 11C, the food waste processor and the operation method using the same according to the present invention include a storage unit 200 having a loading plate 100 to discharge a large amount of water contained in the food waste. Wow; A heating unit 300 which emits far-infrared rays so that the food wastes are dried to dry the food wastes; A duct part 400 formed so that a part of the far infrared rays radiated from the heating part 300 is moved to be supplied to the accommodating part 200; A humidity sensor 500 installed on the main body 10 of the food waste processor 1 to detect humidity when the food waste processor 1 is operated; A temperature sensor 600 for sensing an operating temperature of the heating unit 300 together with the humidity sensor 500; And receiving humidity information and temperature information of the inside of the storage unit 200 sensed by the humidity sensor 500 and the temperature sensor 600 when the food waste processor 1 operates, and storing them on the storage plate 100. Iii) a control unit 700 for controlling the temperature of the heating unit 300 to dry the food waste to reach the target humidity range.

The front of the food waste processor 1 according to the present invention is provided with a button unit 12 having a plurality of buttons. The button unit 12 is provided with various buttons including a power button and a time adjustment button.

The placement plate 100 according to the present invention includes a first drainage zone 110 in which a plurality of first drainage holes 112 are formed, and a plurality of first drainage holes 112 are formed in sections extending from the corners and side points of the entire upper area to the areas spaced inwardly. The second drainage is formed adjacent to the first drainage zone 110 and has a plurality of second drainage holes 122 penetrated in the center of the placement plate 100 except for the first drainage zone 110. It is configured to include a zone (120).

The first and second drain holes 112 and 122 of the first and second drain zones 110 and 120 according to the present invention may be arranged in a matrix form. The reason why the first and second drain holes 112 and 122 are arranged in a matrix form is to allow a large amount of moisture contained in the food waste to be stably drained on the storage unit 200. In the case where the first and second drain holes 112 and 122 are formed, since the moisture contained in the food waste is not drained, the drying performance is lowered.

When the diameter of the first drain hole 112 according to the present invention is assumed to be D, the diameter of the second drain hole 122 is characterized in that a ratio relationship of 1.5 * D to 2.0 * D is established.

The reason for such a ratio relationship is that the diameter of the second drain hole 122 has a diameter relatively larger than that of the first drain hole 112, but the diameter of the second drain zone 120 of the placement plate 100 is increased. Since a large amount of food waste is trapped in the position, and a small amount of food waste is trapped in the position of the first drainage zone 110, it is preferable to have a diameter ratio as described above.

The second drain hole 122 according to the present invention is characterized in that the inclined portion 122a inclined toward the lower center along the longitudinal direction of the second drain hole 122 is formed. The angle of inclination of the inclined portion 122a is not particularly limited, but water or water drained may be inclined at an inclined angle stably along the inclined portion 122a.

The placing plate 100 according to the present invention is characterized in that the handle groove 102 is formed on the side of the placing plate 100 so that the user can easily withdraw to the outside of the housing 200. In addition to the handle groove 102 described above, a separate handle bar (not shown) may be formed to protrude outward from the base plate 100.

The heating unit 300 according to the present invention has a heating wire disposed therein, and a heating plate 310 made of ceramic so that far infrared rays are emitted when power is applied to the heating wire, and radiated from the heating plate 310. It comprises a reflecting plate 320 for refraction of the wavelength of the far infrared rays to concentrate the above-mentioned far infrared rays on the food waste deposited on the base plate 100.

Unlike the conduction or convection, the far-infrared radiation does not require an intermediate heat medium and emits radiant heat directly, and the radiant heat directly generates heat by heating the object to be heated regardless of the intermediate air layer. .

The far-infrared ray has a property of generating heat inside the material by causing resonance in the molecule when it touches a molecule of a material having a frequency, so that energy is radiated from the object to be heated. Since it is particularly advantageous for heating, it is preferable to use far infrared rays.

The duct part 400 according to the present invention has one end connected to the heating part 300 and branched to the left and right sides of the main body part 10, respectively, and the other end of the duct part 400 of the left and right side wall surfaces of the main body part 10. A first duct 410 connected to the first duct 410, one end of which is connected to the first duct 410, extending downward of the main body 10, and a second duct connected to the lower side of the housing 200. 420).

The duct unit 400 according to the present invention is characterized in that a duct fan 402 is installed to enable high-temperature far-infrared rays radiated from the heating unit 300 to flow to the moving passage of the duct unit 400.

The main body portion 10 according to the present invention has a plurality of inflow holes 11 formed through the left and right side wall surfaces connected to the other ends of the first duct 410 toward the food waste deposited on the placement plate 100. It is characterized by.

The inflow hole 11 of the main body portion 10 according to the present invention is characterized in that penetrated downwardly toward the center of the receiving portion.

The control method for controlling the food waste processor according to the present invention includes a humidity sensing step (ST100) of detecting the humidity of the food waste in a state in which the food waste is stored in the food waste processor; A food waste drying step (ST200) of supplying far-infrared rays radiated from the heating unit to the food waste so that the food waste is dried; A current amount adjusting step of changing the amount of current applied to the heating part according to the humidity of the food waste to be dried (ST300); And an abnormal operation adjusting step (ST400) for preventing a malfunction of the device due to an abnormal occurrence during the operation of the food waste processor.

Food waste drying step (ST200) according to the present invention is the first drying step (ST210) is the far-infrared ray of the heating unit is directly delivered to the food waste is dried, and the far-infrared ray is delivered from the side of the food waste is dried And a second drying step ST220 and a third drying step ST230 in which far infrared rays are supplied to the lower side of the food waste and supplied to the food waste.

The current amount adjusting step ST300 according to the present invention includes a first current amount adjusting step ST310 for increasing the amount of current applied to the heating part when the humidity of the food waste is high humidity, and heating when the humidity of the food waste is low humidity. And a second current amount adjusting step ST320 for reducing the amount of current applied to the unit.

The abnormal operation control step (ST400) according to the present invention cuts off the power applied to the heating unit in the event of an abnormality such as a short circuit or power failure, and applies emergency power to the duct fan so that far infrared rays are supplied to the food waste. It characterized in that it comprises an emergency operation step of continuing to dry.

A detailed description of the food waste processor and the operating method using the same according to the present invention configured as described above will be described with reference to the drawings.

Referring to FIG. 8, the food waste 1 according to the present invention accommodates the food waste in the placing plate 100 provided in the storage unit 200 as shown in the drawing. Since the food waste contains a large amount of water, it is preferable to drain the water contained in the food waste on the bottom surface of the storage unit 200 for effective drying.

This is because it is difficult to dry in a state in which a large amount of moisture in the food waste, and the food waste processor should be operated for a long time, it is preferable to drain the water first.

As the food waste is accommodated in the storage plate 100, the large amount of moisture contained in the food waste is discharged from the first drain hole 112 and the second drain zone 110 and the second drain zone 120. The water is discharged onto the accommodating part 200 through the drain hole 122.

As such, the reason for dividing the entire area of the upper portion of the placing plate 100 into the first draining zone 110 and the second draining zone 120 is that when the user places food waste on the placing plate 100, the placing is usually carried out. A large amount of food waste is stored at the central position of the plate 100, and a relatively small amount of food waste is accumulated at the outer side portion of the loading plate 100 as compared to the central position.

Therefore, the diameter of the second drain hole 122 in which the second drain zone 120 is formed has a diameter that is relatively larger than the diameter of the first drain hole 112 formed in the first drain zone 110. In the exemplary embodiment of the present invention, the diameter of the second drain hole 122 is 1.5 * D to 2.0 * D compared to the diameter D of the first drain hole 112, so that the bottom surface of the accommodating part 200 is provided. Smooth drainage is achieved on the bed.

In the base plate 100 according to the present invention, the first drainage zone 110 is formed by being spaced apart by a predetermined distance from corners and side points, and a separate hole is formed at an edge of the base plate 100 in which drainage is not made. By forming the first and second drain holes 112 and 122 at a position where drainage is absolutely necessary, the drainage of food wastes is effectively drained.

In addition, the first and second drain holes 112 and 122 according to the present invention are formed to be arranged in a matrix form, whereby drainage is made by utilizing the area of the limited placement plate 100 to the maximum.

As described above, the handle groove 32 of the storage door part 30 is moved inward while the food waste is accumulated on the housing part 200, and thus, the food waste is placed on the main body 10 as shown in the drawing. Close to close contact with In this state, the power button provided in the button unit 12 is operated. The power button is turned on by the user to operate the food waste processor 1.

1 to 11A, the food waste processor 1 is operated while moisture contained in the food waste processor located inside the receiving unit 200 is detected by the humidity sensor 500, and the temperature is measured by the temperature sensor. It is detected by the 600 and transmitted to the control unit 700 (ST10).

The control unit 700 according to the present invention receives the sensor values from the humidity sensor 500 and the temperature sensor 600 to apply power to the heating unit 300 to control the far-infrared radiation to the food waste (ST200).

The relative humidity (RH) of the food waste input through the humidity sensor 500 at the beginning of the operation of the food waste processor 1 according to the present invention typically has a range of about 70% RH. The control unit 700 is far-infrared generated in the heating unit 300 to change the relative humidity range (15% to 20% RH) of the food waste having the relative humidity range (70% RH) as the target While controlling the radiation to the food waste, the high temperature far infrared rays are directly radiated toward the upper surface of the food waste by applying a current to the heating wire disposed in the heating unit 300 to generate heat.

Referring to FIG. 11A, the heating unit 300 according to the present invention has far infrared rays in the “a” direction in which far infrared rays radiated from the heating plate 310 are directly moved toward food waste, and wavelengths are reflected on the reflecting plate 320. Far infrared rays in the “b” direction that are refracted toward the food waste are simultaneously radiated to form the first drying ST210.

At the same time, the control unit controls the food waste processor as follows to quickly dry food waste in a high humidity state.

Referring to FIG. 11B, the control unit 700 changes the flow of high temperature far-infrared rays generated in the heating plate 310 as shown in the drawing through the first duct 410 to improve drying for food waste. The duct fan 402 is operated to move to the left and right side wall surfaces of the main body 10.

As shown in Figure 6 attached to the inlet hole 11 formed to be inclined toward the food waste is radiated toward the food waste is made second drying (ST220). Because of this, the food waste located on the base plate 100 is dried at the same time from the top and side.

Referring to FIG. 11C, the control unit 700 according to the present invention is a high temperature far-infrared ray generated from the heating plate 310 to improve drying for food waste. The duct fan 402 is provided in the duct unit 400. By the flow is changed by the second duct 420 is supplied to the lower side of the receiving portion 200, as shown in the figure.

The second duct 420 is extended so that the end portion is inserted into the lower side of the accommodating part 200 so that the far-infrared rays of the heat generating part 300 are formed through the first and second drain holes 112 and 122 formed in the base plate 100. It is supplied from the lower side of the food waste to the upper side to perform a third drying of the food waste (ST230).

As the drying is performed in the food waste as described above, the humidity state of the food waste in the current state is sensed (ST10) and input to the controller 700. The control unit 700 changes the amount of current applied to the heating unit 300 according to the dry state of the food waste (ST200) (ST300).

This is because when the same current is supplied to the heating wire provided in the heating unit 300 without changing the amount of current for a long time, the electricity consumption increases, causing an economic burden to the user. It is preferable to check the humidity to change the amount of current accordingly (ST300).

During the food waste operation, the humidity state of the food waste detected by the humidity sensor 500 while being dried as described above is input to the control unit 700, and the control unit 700 has a high relative humidity of the food waste even after a predetermined time has elapsed. If it is determined that the current is applied to the heating unit 300 is increased (ST310) to apply the current to the heating unit 300.

The change in the amount of current of the heating unit 300 is connected to the heating line provided in the heating unit 300 by using a relay (not shown) or a FET (field effect transistor) or TR (transistor) provided separately. Can be adjusted selectively. In addition to the relay described above, a rotary switch or a contact switch may be installed to allow the user to arbitrarily adjust it.

According to the current applied to the heating wire according to the present invention, the above-described heating wire generates heat at a high temperature of more than 200 ° C., and far-infrared rays are radiated from the heating plate 310.

The humidity sensor 500 according to the present invention continuously detects the humidity state of the food waste and transmits it to the control unit 700. When the control unit 700 determines that the humidity state of the food waste is reduced (ST20), The current is applied to the heating line so that the amount of current applied to the heating unit 300 is reduced. Here, the relative humidity of the food waste that can be judged to be in a dried state is 15 to 20% RH, and when the relative humidity of the food waste detected by the humidity sensor 500 reaches the relative humidity range (15 to 20% RH). The control command is transmitted from the control unit 700 to the heating unit 300 to reduce the amount of current applied to the heating unit 300 (ST320).

When an abnormal operation situation such as a power failure or an electrical leak (ST30) occurs in the above state (ST400), the power applied to the heating unit 300 is cut off by the control unit 700, and for the food waste being dried Emergency power is applied to the duct fan 402 in the control unit 700 so that the high temperature far infrared rays or hot air is continuously supplied.

The duct fan 402 according to the present invention is continuously operated until the temperature of the heating unit 300 is lowered by the power applied from the control unit 700 so that high temperature hot air is supplied through the first and second ducts 410 and 420. Supply is made to dry food waste (ST410).

Therefore, the food waste stored in the food waste processor 1 is stably dried, and drying is performed without stopping the operation even in an abnormal situation such as a power failure.

Although the above has been shown and described with respect to the preferred embodiments of the present invention, the present invention is not limited to the above-described embodiment, in the technical field to which the present invention pertains without departing from the spirit of the invention as claimed in the claims. Various modifications can be made by those skilled in the art, and such changes are within the scope of the claims.

As described above, the food waste processor according to the present invention and the operation method using the same by drying the food waste disposed in the food waste processor in accordance with the moisture content state, thereby drying the food waste in a short time There is an effect that can be carried out.

In addition, there is an effect that can be carried out in a stable drying for food waste by continuously drying the food waste even in an abnormal situation such as a short circuit or power outage.

1 is a perspective view showing a food waste processor according to the present invention.

2 to 3 is a view showing a duct installed in the food waste disposal system according to the present invention.

Figure 4 is a view showing a loading plate provided in the food waste disposal system according to the present invention.

5a to 5b is a view showing a heating unit provided in the food waste disposal system according to the present invention.

Figure 6 is a view showing the receiving portion of the food waste disposal system according to the present invention.

7 is a flow chart illustrating a method of operating a food waste processor according to the present invention.

8 is a flow chart showing an operating state of the food waste disposal system according to the present invention.

9 to 10 is a view showing the initial operating state of the food waste disposal system according to the present invention.

11a to 11c is an operating state of the food waste disposal system according to the present invention.

* Description of the symbols for the main parts of the drawings *

100: base plate 110: first drainage zone

112: first drain hole 120: second drain zone

122: second drain hole 200: storage portion

300: heating unit 310: heating plate

320: reflector plate 400: duct portion

410: first duct 420: second duct

500: humidity sensor 600: temperature sensor

700: control unit

Claims (15)

An accommodating part including a storage plate capable of discharging moisture contained in the food waste; A heating unit which emits far-infrared rays to dry the food wastes so as to dry them; One end is connected to the heating part and is branched to the left and right sides of the accommodating part, respectively. The end of the extended portion extending to the lower side of the accommodating part and connected to the first duct includes a second duct connected to the lower part of the main body part corresponding to the lower part of the accommodating part, so that the supply passage to the accommodating part of the far infrared rays radiated from the heating part is provided. Duct part to perform the function of; A humidity sensor installed on an accommodating portion of the food waste processor to sense humidity when the food waste processor is operated; A temperature sensor for sensing an operating temperature of the heating unit together with a humidity sensor; And When the food waste processor operates, it receives the humidity information and the temperature information inside the storage unit detected by the humidity sensor and the temperature sensor, and the food waste accumulated on the loading plate dries to reach the target humidity range. Including a control unit for controlling the temperature, The far-infrared rays radiated from the heating unit are supplied to both sides and the lower part of the accommodating part through the first duct and the second duct of the duct part, and the far infrared rays are transmitted to both sides and the lower part of the food waste in the accommodating part. . According to claim 1, The placement plate may include a first drainage zone having a plurality of first drainage holes penetrating through a section extending from an edge and a side point of the entire upper area to an area spaced inwardly; And a second drainage zone disposed adjacent to the first drainage zone and having a plurality of second drainage holes penetrated in the center of the loading plate except for the first drainage zone. . The method of claim 2, The first and second drain holes of the first and second drain zones are arranged in a matrix form. The method of claim 2, Assuming that the diameter of the first drain hole is D, the diameter of the second drain hole is a food waste processor, characterized in that the ratio relationship of 1.5 * D ~ 2.0 * D is established. The method of claim 2, And the inclined portion inclined toward the lower center along the length direction of the second drain hole. According to claim 1, The waste disposal plate is a food waste processor, characterized in that the handle groove is formed on the side of the placement plate so that the user can easily withdraw to the outside of the housing. According to claim 1, The heating unit has a heating wire disposed therein, a heating plate made of ceramic so that far infrared rays are emitted when power is applied to the heating line, and refracting the wavelength of far-infrared radiation emitted from the heating plate to the food waste deposited on the loading plate. Food waste processor comprising a reflector to enable the concentration of the far infrared rays. delete According to claim 1, And a duct fan installed at the duct to allow a high temperature far-infrared ray radiated from the heating part to flow into a moving passage of the duct part. The method of claim 1, And a plurality of inflow holes formed in the main body portion through the left and right side wall surfaces connected to the other ends of the first duct toward the food waste deposited on the base plate. The method of claim 10, The food waste processor of the main body portion is inclined downward downward toward the center of the receiving portion. A humidity sensing step of sensing humidity of the food waste in a state in which food waste is stored in a food waste processor; A food waste drying step of supplying far-infrared rays radiated from the heating unit to the food waste so that the food waste is dried; A current amount adjusting step of changing an amount of current applied to the heating unit according to a humidity state of the food waste to be dried; And Method for operating a food waste processor, characterized in that it comprises an abnormal operation adjustment step of preventing the malfunction of the device due to the occurrence of abnormalities during the operation of the food waste processor. The method of claim 12, The food waste drying step is a first drying step in which the far-infrared rays of the heating unit are directly delivered to the food wastes and dried, and a second drying step in which the far infrared rays are dried in the side of the food wastes and dried, the lower side of the food wastes. And a third drying step of supplying far-infrared light to the food waste. The method of claim 12, The current amount adjusting step may include a first current amount adjusting step of increasing the amount of current applied to the heating unit when the humidity of the food waste is high humidity, and a second amount of decreasing current amount applied to the heating unit when the humidity of the food waste is low humidity. Method of operating a food waste processor characterized in that it comprises a current amount adjustment step. The method of claim 12, The abnormal operation control step is to emergencyly dry the food waste by applying power to the duct fan so as to cut off the power applied to the heating unit in the event of an abnormality such as a short circuit or a power failure, and to supply far infrared rays to the food waste. Method of operating a food waste handler characterized in that it comprises a drying step.

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