KR101118714B1 - Food treater which can recycle food waste - Google Patents

Abstract

PURPOSE: A food waste treating apparatus is provided to shorten time required for drying food waste and to form the food waste into powder form by dehydrating the food waste. CONSTITUTION: A food waste treating apparatus includes a salinity reducing part(1000), a sterilizing and drying part(2000), and a deodorizing part(3000). The salinity reducing part includes a food waste introducing body(1100), a water spraying nozzle(1110), a cover(1200), and a washing member for washing the inner sidewall of the introducing body. The installing direction of the water spraying nozzle is upwardly slanted to spray water to the cover. A lower through path is formed at the introducing body and supplies water. The washing member is based on a flexible material.

Description

Food treater which can recycle food waste}

The present invention is to reduce the concentration of salt (Nacl) contained in the food waste, to dehydrate the water contained in the food waste, it is possible to recycle the food waste as fertilizer or feed, etc., rotate the compressed dehydrated food waste It provides rotational rotation at 360 ° in the entire drum to shorten the sterilization drying time of food waste, and also applies hot air to the rotating drum that is rotated in rotation so that food waste is sterilized and dried in powder form without burning. By mixing the fine humidifying particles with the odor particles generated during the waste disposal process, the odor particles are liquefied to be discharged to the sewer, so that the deodorizing function of food waste for a long time not only has excellent deodorizing efficiency but also does not perform additional work. Deodorizing function can be performed continuously without being humidified It relates to possible food waste Recycling of food waste to parts automatically to replenish the water.

In general, food waste generated at homes, large restaurants and catering establishments is easily decayed with water content of 80 to 85%, and odor and sewage are generated, making it difficult to separate and transport food waste. Although landfilling has been relied upon, the amount of food waste has increased exponentially, making it difficult to secure landfills and accelerating soil and water pollution, such as acidification of soil due to salts contained in food waste during landfilling. It also causes secondary pollution problems such as the generation of various odors and harmful gases. Here, the food wastes include animal and vegetable residues generated in the manufacturing process of foods, as well as food wastes generated in homes and restaurants.

In order to solve this problem, a food processor for drying and extinguishing food waste has been proposed.

1 is a cross-sectional view showing a schematic structure of a conventional food waste processor.

As shown in the drawing, the conventional food waste processor is provided with a stirring blade 2 inside the drying container 1 to agitate the food waste accumulated therein, and is heated by heating the heater 3 installed under the drying container 1. The garbage will dry out.

By the way, the conventional food processor is only capable of extinction of food waste, there is a problem that can not be recycled to resources such as fertilizer or feed.

For this reason, discarded food waste contains salt. High concentrations of salt (NaCl) in food waste causes plant growth disorders due to osmotic pressure, and sodium (Na) is the calcium in the soil. ) And magnesium (Mg), which results in the destruction of the grain structure of the soil and conversion to a monolithic structure resulting in poor breathability and drainage.

As a result, it becomes difficult to supply oxygen, which acts as a obstacle to the growth of crops, and it is difficult to compost food waste without removing salt below a certain concentration as well as a large amount even when using food waste as feed. Salts caused by salts not only contribute to the deterioration of meat quality, slow growth, and the death of livestock, but also contain a lot of moisture in the food waste, which makes it difficult to process the food waste into fertilizer or feed. have.

In addition, the conventional food waste processor is provided with two stirring blades (2) are installed for stirring food, because the central portion of the two stirring blades (2) provided is composed of a structure that is orthogonally coupled and rotated The interior of the drying container 1 is divided into four compartments. Because of this, there is also a problem that the mixing of food waste is not made well, it is difficult to dry food waste.

In addition, since the food waste accumulated in the drying container 1 is dried by the heating of the heater 3, not only the bottom of the food waste is burned, but also the food waste gets stuck in the stirring blade 2, causing odor. There is also. In order to solve this problem, a device for treating water to remove moisture by applying hot air to food waste has been developed, but most of the technology takes a long time to dry the food waste piled up by simply supplying hot air into the drying container. New problems are being derived.

In addition, in order to discharge the food waste dried in the drying container (1) to the outside, the problem that workability is deteriorated by allowing the user to manually discharge the food waste inside the drying container to the outside while the driving of the apparatus is stopped. have.

In addition, the conventional food waste treatment process is necessarily accompanied by a bad smell in the process, there is no way to remove this completely, the food waste treatment is not used a lot.

That is, in the conventional food waste processor, although not shown in the drawing, a plurality of deodorization chambers are installed to remove odors, and the odors are removed by a filter installed in the deodorization chamber. This is because the problem is caused.

In order to solve this problem, the deodorizer equipped with the humidification device of Patent Application No. 2002-4286, which is a conventional food processor for fermentation of food waste, has been improved in the fermentation tank. The deodorization tank is installed to deodorize the odor generated during the fermentation process, the deodorization tank is composed of one rectangular cylinder and at the bottom constitute a humidifier device to spray water to atomize, multi-stage at the top of the humidifier device After installing the partition with a vent at regular intervals to form a multi-stage deodorizing chip insertion space, the deodorizing chip inserted into the deodorizing microorganism containing the deodorizing microorganism in each of the deodorizing chip insertion space, the humidifier Fine water particles sprayed from the air make optimum conditions for the growth of deodorant microorganisms on deodorant chips. It may have been disclosed techniques for so.

However, the deodorizer equipped with the humidifier is divided into five to six stages while the deodorization tank is formed of one narrow cylinder, and then deodorized in the form of wood chips containing deodorant microorganisms from the bottom to their respective space parts. It is difficult and inconvenient to fill the chip and the subleaf soil, which leads to a problem of low productivity, and the replacement work is very cumbersome and time-consuming when replenishing deodorizing chips or defoliation or adding microorganisms after long-term use. This is causing.

In addition, there is a problem that the user must supply water from time to time can not automatically supply water to the humidifier.

The present invention is to solve the problems of the prior art, the first object of the present invention is to drop the concentration of salt (Nacl) contained in the food waste, and to dehydrate the water contained in the food waste, food waste It is to provide a food processor capable of recycling food wastes that are recycled as fertilizer or feed.

The second object of the present invention is to provide a compressed rotation of the dehydrated food waste 360 ° in the entire rotating drum to reduce the drying time of the food waste and to apply hot air into the rotating drum rotates the food waste It is to provide a food processor capable of recycling food waste, which allows it to be dried in powder form without burning.

The third object of the present invention is to mix the fine humidifying particles with the odor particles generated during the processing of food waste to liquefy the odor particles to be discharged to the sewer to have a good deodorizing efficiency even if the deodorizing function of food waste for a long time In addition, it provides a food processor that can recycle food waste that can continuously perform deodorization without any additional work.

It is a fourth object of the present invention to provide a food processor capable of recycling food wastes to automatically replenish water in a humidification tank.

As a technical idea for achieving the present invention, the food waste recycling apparatus of the present invention is capable of supplying water to food waste to be input, and dehydrating food waste containing water to reduce salts contained in the food waste (Nacl). Salinity reduction to reduce the concentration of; A drying unit communicating with the salinity reduction unit, drying the dehydrated food waste introduced from the salinity reduction unit to dry, and transferring the hot air to the rotated food waste to dry it; In communication with the drying unit, the deodorizing unit for collecting the odor particles generated from the food waste dried in the drying unit in the fine humidifying particles; consists of.

The salinity reduction unit, the input body into which food waste is put; It is provided on the inner wall of the injection body, water injection nozzle for injecting water; includes.

The food processor capable of recycling food waste of the present invention further includes a lid for an inlet body connected to the upper portion of the inlet body, and the installation direction of the water jet nozzle is inclined upwardly to be sprayed toward the inlet body cover. Lose.

The food processor of the present invention enables recycling of food waste, further comprising a lid for an inlet body connected to an upper portion of the inlet body, wherein an ultraviolet lamp is installed below the inlet body cover.

An ultraviolet transmission window is installed below the ultraviolet lamp provided in the lid for the input body, and the installation direction of the water injection nozzle is inclined upwardly to be sprayed toward the ultraviolet transmission window.

The food processor of the present invention enables recycling of food waste, the shredding unit for shredding the food waste inside the input body; further includes.

A food processor capable of recycling food waste of the present invention further includes a weight reduction unit communicating with a lower end of the feeding body to reduce moisture containing salt in the food waste dropped from the feeding body.

The weight reduction unit, the side wall is in communication with the lower end of the input body, the dehydration holes are formed, the inner diameter is reduced from one side to the other side, the dehydration pipe opening both sides; A compression screw rotatably embedded in the dehydration pipe, wherein a spiral or linear stirring blade is fixed on a rotating shaft; It is connected to the rear end of the crimping screw driving unit for transmitting power.

A food processor capable of recycling food waste of the present invention further includes an inner wall cleaning member which is provided on the inner wall of the feeding body and washes the inner wall of the feeding body.

The inlet body is provided with a lower passageway through which water is supplied, and the inner wall cleaning member has a flexible material, and one side is connected to the lower passageway, and is a washing tube slid downward by its own weight.

The drying unit may be in communication with the salinity reducing unit, a conveying unit in which food waste passing through the salinity reducing unit is transported and in communication with the transporting channel, and a hot air supply path in which hot air is supplied; Hot air supply means comprising a heater and a blowing fan to supply hot air to the hot air supply path; Food waste and hot air that has passed through the transfer unit is introduced, the rotating drum body is rotated and the food waste introduced into the interior collides with each other and reaches the upper portion of the rotating drum body by sterilization for high temperature hot air while falling by its own weight. Rotating drum sterilization drying unit to be dried; It includes a drive means for rotating the rotating drum sterilization drying unit.

The rotary drum sterilization drying unit, the cover is coupled to both sides of the rotating drum body, the through hole is formed in the center of the cover, one side of the cover is supported by the conveying flow path of the transfer portion, the other cover is the outlet through which wet steam passes Are supported.

An inclined surface is formed at the front end of the transfer part to discharge residual discharge water generated from the compressed food waste.

The rotating drum sterile drying unit, at least one wing is attached to the inner wall.

The drying-side drive means, the drive motor; A prime mover axially coupled to the drive motor; A driven body formed integrally with the outer side of the rotating drum sterilization drying unit; It is composed of; a connecting member for connecting the driving body and the driven body.

The rotary drum sterilization drying unit has an opening is formed to discharge the sterile dried waste to the outside, the door opening and closing the opening; And a door automatic opening and closing means for automatically opening and closing the door.

The deodorization unit, the inlet for the odor particles generated in the process of processing food waste, the atomization unit for converting the fresh water to fine humidified particles to supply water to the odor particles introduced into the inlet and the atomization occurs in the atomization unit A humidification tank including a discharge port for collecting and discharging odor particles introduced from the inlet port; And a water tank connected to the humidification tank and communicating with the water supply tank to supply water.

Odor particles introduced into the humidification tank is forced to exhaust by the external air forced inlet fan.

At least one humidification tank side water level sensor is installed in the humidification tank.

The atomization part includes an ultrasonic vibrator.

The water tank is provided with a water supply port for supplying tap water, and the water supply is provided with a solenoid valve for water supply.

The water tank is formed with an air flow port for supplying air.

The communication path is provided with a communication solenoid valve.

The present invention is to reduce the concentration of salt (Nacl) contained in the food waste, and to dehydrate the water contained in the food waste, it is possible to recycle the food waste as a fertilizer or feed exhibits the effect.

The present invention provides a rotational rotation of the dehydrated food waste 360 ° in the entire rotating drum to shorten the drying time of food waste and to apply a high temperature hot air into the rotating drum rotates the food waste It also has the effect of making it dry and sterilized in powder form.

The present invention by mixing the fine humidifying particles with the odor particles generated during the processing of food waste to liquefy the odor particles to be discharged to the sewer not only has a good deodorization efficiency even if the deodorizing function of the food waste for a long time There is also the effect that the deodorizing function can be carried out continuously without any additional work.

The present invention also has the effect of automatically replenishing the water inside the humidifier.

1 is a cross-sectional view showing a schematic structure of a conventional food waste processor;
Figure 2 is an overall configuration showing a food processor capable of recycling the food waste of the present invention,
Figure 3 is an external perspective view showing a salinity reduction portion of the configuration of a food waste processor capable of recycling the food waste of the present invention,
Figure 4 is a cross-sectional view showing a salinity reduction portion of the configuration of the food waste treatment equipment capable of recycling the food waste of the present invention,
Figure 5 is a cross-sectional view showing an additional application example of the salt reduction portion of the configuration of the food waste treatment machine capable of recycling the food waste of the present invention,
6 and 7 is a state of use according to the additional application example of the salinity reduction portion of the configuration of the food waste treatment machine capable of recycling the food waste of the present invention,
8 is a sectional view showing the main part of the shredding part included in the salinity reduction part of the configuration of the food waste treatment machine capable of recycling the food waste of the present invention;
9 is a sectional view showing the main part of the weight reduction unit included in the salinity reduction unit in the configuration of a food waste processor capable of recycling food waste of the present invention;
10 is an exploded perspective view showing a drying unit in the configuration of a food processor capable of recycling food waste of the present invention;
FIG. 11 is an exploded perspective view illustrating a rotating drum sterilization drying unit among the drying units of FIG. 10; FIG.
12 is a perspective view showing the combination of the rotating drum sterilization drying unit of the drying unit of Figure 10,
Figure 13a is a view for explaining the automatic door opening and closing process of the rotating drum sterilization drying unit installed in the drying unit of the food waste treatment system capable of recycling the food waste of the present invention, a cross-sectional view of the state before the door is opened and closed,
Figure 13b is a view for explaining the automatic door opening and closing process of the rotary drum sterilization drying unit installed in the drying unit of the food waste treatment system capable of recycling the food waste of the present invention, the process of the electronic valve is advanced to open the door Section for
Figure 13c is a view for explaining the automatic door opening and closing process of the rotary drum sterilization drying unit installed in the drying unit of the food waste treatment system capable of recycling the food waste of the present invention, a cross-sectional view showing a state in which the door is opened by the solenoid valve ,
Figure 13d is a view for explaining the automatic door opening and closing process of the rotating drum sterilization drying unit installed in the sterilization drying unit of the food waste recycling system of the food waste recycling of the present invention, the process of discharging food waste by opening the door Section for illustration,
Figure 13e is a view for explaining the automatic door opening and closing process of the rotating drum sterilization drying unit installed in the sterilization drying unit of the food waste recycling apparatus of the present invention can be recycled, for explaining the process of closing the open door drawing,
14 is a cross-sectional view showing the operation flow of the rotating drum sterilization drying unit installed in the sterilization drying unit of the food waste recycling apparatus capable of recycling the food waste of the present invention,
Figure 15 is a side cross-sectional view of the rotating drum sterilization drying unit installed in the sterilization drying unit of the food waste treatment system capable of recycling the food waste of the present invention,
16 is a main portion perspective view showing the blockage preventing means provided in the sterilization drying unit of the food waste treatment apparatus capable of recycling the food waste of the present invention,
Figure 17 is a side cross-sectional view showing the blockage preventing means provided in the sterilization drying unit of the food waste treatment apparatus capable of recycling the food waste of the present invention,
Figure 18 is a side cross-sectional view showing another embodiment of the wing installed in the rotating drum body provided in the sterilization drying unit of the food waste treatment apparatus capable of recycling the food waste of the present invention,
Figure 19 is a side cross-sectional view showing another embodiment of the wing installed in the rotating drum body provided in the sterilization drying unit of the food waste treatment apparatus capable of recycling the food waste of the present invention,
20 is a cross-sectional view showing a deodorizing portion of the configuration of a food waste processor capable of recycling food waste of the present invention;
21 is a view for explaining the automatic water replenishment process of the humidification tank provided in the deodorizing portion of the configuration of the food waste treatment machine capable of recycling the food waste of the present invention.

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

2 is an overall configuration diagram showing a food waste processor capable of recycling the food waste of the present invention, Figure 3 is an external perspective view showing a salinity reduction portion of the configuration of the food waste recycling apparatus of the present invention, Figure 4 is 6 is a cross-sectional view showing a salinity reduction part of the configuration of the food waste treatment equipment capable of recycling food waste, FIG. Figure 8 is a state of use according to an additional application example of the salinity reduction unit of the configuration of the food waste treatment can be recycled food waste of the present invention, Figure 8 is included in the salinity reduction portion of the configuration of the food waste recycling process of the present invention 9 is a partial cross-sectional view of a main portion of the food waste processor of the present invention capable of recycling the food waste of the present invention. Fig. 10 is an exploded perspective view showing a reduced part included in a salinity-reducing part of the present invention. Figure 12 is an exploded perspective view showing a drum sterilization drying unit, Figure 12 is a combined perspective view showing a rotating drum sterilization drying unit of the configuration of the sterilization drying unit of Figure 10, Figure 13a is installed in a sterilization drying unit of the configuration of the food waste recycling process of the present invention As a view for explaining the automatic door opening and closing process of the rotating drum sterilization drying unit, a cross-sectional view of the state before the door is opened and closed, Figure 13b is a rotation installed in the sterilization drying unit of the configuration of a food processor capable of recycling the food waste of the present invention A diagram illustrating the automatic door opening and closing process of the drum sterilization drying unit. 13C is a cross-sectional view for explaining a process of opening, a diagram for explaining the automatic door opening and closing process of the rotary drum sterilization drying unit installed in the sterilization drying unit constituting the food processor capable of recycling food waste of the present invention, the solenoid valve 13D is a view for explaining the automatic door opening and closing process of the rotating drum sterilization drying unit installed in the sterilization drying unit of the food waste processor of the present invention for recycling the food waste of the present invention. 13E is a cross-sectional view illustrating a process of discharging food waste by opening the door, and FIG. 13E illustrates an automatic door opening and closing process of a sterilization drying unit of a rotating drum installed in a sterilization drying unit of a food processor capable of recycling food waste of the present invention. As a diagram for explaining, a diagram for explaining a process of closing an open door, FIG. 14 is a cross-sectional view showing the operation of the rotary drum sterilization drying unit installed in the sterilization drying unit of the food waste recycling apparatus of the food waste recycling of the present invention, Figure 15 is a configuration of a food waste recycling of the food waste of the present invention Side cross-sectional view of the rotating drum sterilization drying unit is installed in the sterilization drying unit, Figure 16 is a main portion perspective view showing the blockage preventing means provided in the sterilization drying unit of the food waste treatment apparatus capable of recycling the food waste of the present invention, Figure 17 is the present invention Side cross-sectional view showing a blockage preventing means provided in the sterilization drying unit of the configuration of the food processor capable of recycling the food waste of Figure 18 is a rotation provided in the sterilization drying unit of the configuration of the food processor capable of recycling the food waste of the present invention Side cross-sectional view showing another embodiment of the wing installed in the drum body, Figure 19 is a food waste of the present invention Side cross-sectional view showing another embodiment of the wing installed in the rotating drum body provided in the sterilization drying unit of the configuration of the food waste treatment can be recycled, Figure 20 shows the deodorizing portion of the configuration of the food waste recycling apparatus of the present invention Sectional view, Figure 21 is a view for explaining the automatic water refilling process of the humidification tank provided in the deodorizing portion of the configuration of the food waste treatment machine capable of recycling the food waste of the present invention.

As shown, the food waste recycling apparatus of the present invention is largely composed of a salt reduction unit 1000, a sterile drying unit 2000 and a deodorization unit 3000.

The salinity reduction unit 1000 is a member that supplies water to the food waste to be introduced and dehydrates the food waste containing water to drop the concentration of salt (Nacl) contained in the food waste.

Detailed configuration of the salt reduction unit 1000 to perform this function is the injection body 1100, water injection nozzle 1110, the cover body 1200, the inner wall cleaning member 1120, shredder 1300 and weight loss Fire 1400 and the like.

First, the input body 1100 is a body into which food waste is put, the cover body 1200 for the input body is provided through the hinge connection at the top.

The water injection nozzle 1110 is provided on the inner wall of the injection body 1100, the food waste injected into the injection body 1100 is accommodated in the water injected through the water injection nozzle 1110, so that the food waste is called water This results in a reduction in the concentration of salinity (NaCl) contained primarily in food waste.

In addition, by spraying high pressure water through the water injection nozzle 1110, it also performs a function of removing the foreign matter on the inner wall of the injection body 1100.

In particular, the installation direction of the water injection nozzle 1110 is installed to be inclined upwardly, thereby spraying toward the bottom of the cover body 1200 for the injection body is provided to be able to wash the cover body 1200.

As shown in the drawing, the water injection nozzle 1110, which performs this function, is inserted and installed through the upper through passage penetrating the injection body 1100, and the water supply hose is connected to the end to supply strong water pressure. To be available.

In addition, although not shown in the drawings, the water injection nozzle 1110 may also be provided as a rotating nozzle that rotates, and may be provided to maximize the cleaning function of the lid 1200 for the input body to be described later.

In addition, the ultraviolet lamp 1210 is installed at a lower portion of the lid 1200 for the input body at appropriate intervals to remove foreign substances or food wastes that are put on the inner wall of the input body 1100 through ultraviolet irradiation. It performs the function of sterilization and deodorization.

At this time, the UV transmission window 1220 is installed in the cover body 1200 for the injection body to prevent the water sprayed by the water injection nozzle 1110 installed to be inclined upward toward the ultraviolet lamp 1210, ultraviolet It is provided below the lamp 1210.

Here, the ultraviolet transmission window 1220 may use quartz or quartz having excellent ultraviolet transmission efficiency.

Although not shown in the drawing, when the ultraviolet lamp 1210 is operated instead of the ultraviolet transmission window 1220 installed in the lid 1200 for the input body, the food waste introduced by opening the inside of the lid 1200 for the input body. When the water injection nozzle 1110 is operated, the ultraviolet ray is directly irradiated to the back, and an opening and closing screen is inserted to close the inside of the injection body cover 1200 to prevent the sprayed water from being sprayed toward the ultraviolet lamp 1210. It may be provided by installing on the body cover 1200.

In addition, the inner wall cleaning member 1120 is provided on the inner wall of the inlet body 1100 so as to clean foreign substances such as food wastes on the inner wall of the inlet body 1100.

As shown in the drawing, the inner wall cleaning member 1120 performs such a function so as to provide uniform washing of the inner wall of the injecting body 1100 even if only about four are installed along the inner wall of the injecting body 1100. The lower penetration passage 1121 is formed in the injection body 1100, and the inner wall cleaning member 1120 has a flexible material, and one side is connected to the lower penetration passage 1121, and is lowered by its own weight. It consists of a washing tube drooping.

At this time, as shown in the figure, by inserting a water supply hose in the lower passage 1121 to provide a strong water pressure can be supplied.

As such, the washing member 1120 for the inner wall, which is a washing tube that is drooped downward by its own weight, is sprayed with water moving up and down and left and right irregularly due to the strong water pressure supplied through the lower through passage 1121. The inner wall of the injection body 1100 can be evenly washed evenly through the inner wall cleaning members 1120 installed only around four along the inner wall, thereby maximally suppressing the occurrence of odor due to the decay of foreign substances.

The crusher 1300 is installed in the lower side of the input body 1100, and finely crushes the input food waste and finely shredded food waste to be mixed well with water, thereby providing a concentration of the salt contained in the food waste Secondary reduction.

Such a detailed configuration of the crusher 1300 performing the function includes a cylindrical crushing body 1310 in which long grooves 1311 are formed at equal intervals so that food can pass therethrough; A shredding cutter 1320 disposed inside the cylindrical shredding body 1310; It is composed of a rotating shaft 1330 fixedly connected to the shredding cutter 1320 to rotate the shredding cutter 1320 by the driving force transmitted from the shredding part side drive unit, by the rotation of the shredding cutter 1320 The food waste placed on the 1320 is moved toward the long grooves 1311 of the cylindrical crushing body 1310, so that the food waste smaller than the long grooves 1311 is dropped toward the reducer 1400 through the long grooves 1311, The food waste having a volume larger than that of the long groove 1311 is crushed to a volume smaller than that of the long groove 1311 by the crushing cutter 1320 that is rotated, and is dropped toward the reducer 1400 through the long groove 1311.

At this time, the long groove of the cylindrical crushed body 1310 so that the crushed food waste passing through the long grooves 1311 of the cylindrical crushed body 1310 can be dropped toward the reducer 1400 communicated with the bottom of the input body 1100. The dropping space 1130 is provided on the lower inner wall of the input body 1100 corresponding to the 1311 is expanded.

Here, the food waste not shredded by the shredding cutter 1320 to have a volume smaller than that of the long groove 1311 may be discharged to the outside by opening the lid 1200 for the feed body connected to the feed body 1100.

In addition, the reducer 1400 and the rotating shaft 1330 are provided to be spaced apart from each other, for example, so that the reducer 1400 communicating with the input body 1100 is disposed to have an inclination in an oblique line.

The reducer 1400 is in communication with the lower end of the input body 1100 and performs a function of reducing water contained in the food waste dropped from the input body 1100.

Detailed configuration of the reducer 1400 that performs this function is a tapered side wall is in communication with the lower end of the input body 1100, dehydration holes 1411 are formed, the inner diameter decreases from one side to the other side A dehydrating pipe 1410 having a shape and rotatably embedded in both sides of the dewatering pipe 1410, a spiral screw or a straight stirring blade fixed to the rotating shaft, and a crimping screw ( It is connected to the rear end of the 1420 consists of a driving unit 1430 for transmitting power.

Here, the compression screw 1420 also has a tapered shape in which the inner diameter decreases from one side to the other side like the dewatering pipe 1410, so that the dewatering efficiency can be maximized.

That is, the finely crushed food waste is dropped into the dehydration pipe 1410 through the crusher 1300. At this time, since the compressed screw 1420 is being rotated through the driving unit 1430, the finely crushed food waste is compressed. It is transferred from one side to the other through the 1420.

As such, the finely crushed food waste is squeezed because the inner diameter of the dehydration pipe 1410 is gradually narrowed during transportation, so that the water contained in the food waste is dehydrated.

At this time, since a number of dehydration holes 1411 are formed through the dehydration pipe 1410, the dewatered water flows out of the dehydration pipe 1410 through the dehydration holes 1411.

The water dewatered from the spilled food waste is contaminated water containing salt, so it is provided to be contained in a container for purification. To this end, the drain port 1440 is connected to the lower portion of the dehydration pipe 1410, and is provided in communication through the first connection hose between the connected drain port 1440 and the housing.

The sterilization drying unit 2000 is in communication with the other open side of the dehydration pipe 1410 of each component of the salinity reduction unit 1000, by drying the dehydrated food waste flowing from the salinity reduction unit 1000 However, it is a member that delivers high temperature hot air to the rotating food waste to sterilize and dry.

The detailed configuration of the sterilization drying unit 2000 to perform this function includes a transfer unit 2100, hot air supply means 2200, rotary drum sterilization drying unit 2300 and the drying side driving means 2400.

The transfer unit 2100 is in communication with the other side of the dehydration pipe 1410 of the salinity reduction unit 1000, the conveying flow path 2110 and the conveying flow path 2110, through which the food waste passing through the salt reduction unit 1000 is transported. ) Is in communication with the hot air supply path 2120 is supplied.

In addition, at the tip of the transfer unit 2100 in which the salinity reduction unit 1000 and the transfer unit 2100 are in communication, an inclined surface 2130 is formed to discharge the discharge water generated from the compressed food waste, and thus, the lower portion of the dehydration pipe 1410. It is discharged through the connected drain (1440).

The hot air supply means 2200 may be composed of a heater 2210 and a blowing fan 2220 to supply hot air to the hot air supply path 2120.

That is, the transfer unit 2100 is to sterilize the food waste passing through the transfer flow path 2110 by using the hot hot air supplied from the hot air supply means 2200, and the water contained in the food waste is reduced to moisture. This is transferred to the reduced solid state.

The rotary drum sterilization drying unit 2300, food waste and high temperature hot air flowing through the transfer unit 2100 is introduced, the rotating drum body 2310 is rotated and the food waste introduced into the interior collide with each other and rotate It reaches to the top of the drum body 2310 to fall by its own weight to be sterilized to dry.

In addition, the rotary drum sterilization drying unit 2300, the cover 2320, 2330 is coupled to both sides, respectively, the center of the cover 2320, 2330 through holes (2321, 2331) is formed on one side The cover 2320 is the support flow path 2110 of the transfer unit 2100 is coupled and supported, the other cover 2330 is to be coupled to the outlet 2340 through which the wet steam passes.

In addition, a wet steam passage hole 2341 is formed in the discharge port 2340, and a clogging prevention means 2350 is further formed to prevent the wet steam passage hole 2341 from being blocked.

The blockage preventing means 2350 is formed to protrude to the inner surface of the rotary spring body 2311 and the leaf spring (2351) protruding toward the wet steam passage hole (2341) in the discharge port (2340) rotatable drum body ( It is to include a protruding rod (2352) to be intermittently caught in the leaf spring (2351) in accordance with the rotation of 2310.

In addition, the rotary drum sterilization drying unit 2300, the structure is to be composed of a cylindrical member 2311 wound around the plate and each cover (2320, 2330) coupled to both sides of the cylindrical member (2311). It is simple and easy to manufacture.

Rotating drum body 2310 of the rotary drum sterilization drying unit 2300, at least one wing 2313 is attached to the inside in the axial direction to facilitate food waste transported upwards by the wing 2313. It is to improve the drying efficiency of food waste.

That is, the rotary drum sterilization drying unit 2300 is solidified food waste that has passed through the transfer unit 2100 is rubbed inside the rotary drum sterilization drying unit 2300 and is transferred upward by the wings 2313 to rotate the drum body. By reaching the inner top of 2310 and falling by its own weight, the food waste is changed into a powder form, thereby improving drying efficiency.

Figure 18 is a side cross-sectional view showing another embodiment of the wing installed in the rotating drum body provided in the sterilization drying unit of the food waste treatment apparatus capable of recycling the food waste of the present invention.

This is to attach at least one wing 2313 in the axial direction therein, so that the corner portion of the wing 2313 is rounded so that food waste is not caught in the corner portion.

Figure 19 is a side cross-sectional view showing another embodiment of the wing installed in the rotating drum body provided in the sterilization drying unit of the food waste treatment apparatus capable of recycling the food waste of the present invention.

This is to attach at least one wing (2313) in the axial direction therein, so that the wing (2313) is bent so that food waste falls from the top to improve the drying efficiency.

In addition, the door 2360 is formed in the rotary drum sterilization drying unit 2300, the door 2360 is automatically discharged when the food waste sterilized in the rotary drum sterilization drying unit 2300 to the lower stacker 2500 It includes a door automatic opening and closing means 2370 to be opened and closed, the opening drum 2311a is formed in the rotary drum body 2310 of the rotary drum sterilization drying unit 2300 to discharge the sterilized dry waste to the outside.

In addition, the one side of the cover (2320, 2330) coupled to both sides of the rotating drum body (2310) is the drying side drive means 2400 is interlocked to rotate the rotary drum sterilization drying unit (2300).

Drying side drive means 2400 to perform this function, to rotate the rotary drum sterilization drying unit 2300, the drive motor 2410, the driving body is axially coupled to the drive motor 2410 ( 2420, a driven body 2430 integrally formed on the outside of the rotary drum sterilization drying unit 2300, and a connecting part 2440 connecting the driving body 2420 and the driven body 2430 to each other.

The driving body 2420 and the driven body 2430 may be applied in various forms such as a belt pulley or a sprocket, and thus the connection part 2440 may be configured as a belt or a chain.

The door 2360 opens and closes the opening 2311a. The door 2360 is slid along the outer surface of the rotating drum body 2310, and the locking jaws 2361 and 2362 are bent at both ends thereof. Both side surfaces are supported by the guide pieces 2312 provided on the body 2310.

On the other hand, the present invention will be described by dividing the locking step (2361) 2236 for the convenience of operation description divided into one locking step (2361) and the other locking step (2362).

In addition, the guide piece 2312 is provided with a pressing portion (2312a) to press the both sides of the door 2360 so as not to open the door 2360 without the door automatic opening and closing means 2370.

In addition, an opening window 2363 is formed in the door 2360 to coincide with the opening 2311a of the rotating drum body 2310 when opening the door 2360, and when closing the door 2360. It is to be staggered with the opening 2311a of the rotary drum body 2310.

The door automatic opening and closing means 2370 is to open and close the door 2360, it is preferable to be composed of the solenoid valve (2371), when the rotating drum body 2310 is rotated to be formed on both ends of the door (2360) One side of the jaw 2361 and 2236 is to open the door 2360 so that the operation rod 2372 of the solenoid valve 2371 is advanced and caught.

In addition, the actuating rod 2372 of the solenoid valve 2371 is coupled to an elastic member 2372a in the middle thereof, and the catching jaw 21 when the rotating drum body 2310 is continuously rotated in the opening and closing process of the door 2360. It is to prevent damage even if the operation rod 2372 is caught by the 22.

Through such a configuration, the sterilization drying process of the dehydrated food waste is first, the dewatered food waste introduced from the other side of the opening of the dehydration pipe 1410 of the salinity reduction unit 1000 is the transfer path 2110 of the transfer unit 2100 Is transported along

At this time, the residual discharge water remaining in the food waste passing through the transfer passage 2110 may be discharged by the inclined surface 2130 formed at the tip of the transfer unit 2100.

In addition, the food waste passing through the transfer passage 2110 is blown high temperature heat generated from the heater 2210 to the blowing fan 2220 to be supplied through the hot air supply passage 2120 to primarily feed the food waste. Sterilized to dry.

The food waste first sterilized and dried in the transfer unit 2100 flows into the rotating drum body 2310 of the sterilized and dried drum unit 2300, which is connected to the transfer passage 2110 of the transfer unit 2100. It is introduced through the through hole 32a of the cover 2320.

The food waste introduced into the rotary drum sterilization drying unit 2300 is rotated by the power of the drying drum driving means 2400, and the food therein collides with each other in the rotating drum body 2310. In addition, the process of falling to its own top and falling by its own weight is changed to a powder form.

In addition, the food waste is more easily transported upward by the wing 2313 in the rotating drum body (2310).

After the food waste is sterilized and dried on the rotating drum body 2310, the operation signal of the microcomputer (not shown) is stopped as shown in FIG. 13B after stopping the rotating drum body 2310 rotated in the forward direction as shown in FIG. 13A. When the operating rod (2372) of the solenoid valve (2371) is advanced, and the rotary drum body (2310) is rotated in the reverse direction, the operating rod (2372) is caught by the other side locking jaw 22 of the door (2360), the door (2360) While sliding along the outer surface of the rotating drum body 2310, the opening 2311a of the rotating drum body 2310 and the opening window 2363 of the door 2360 coincide with each other as shown in FIG. 13C.

When the opening 2311a of the rotating drum body 2310 and the opening window 2363 of the door 2360 coincide with each other, the food waste inside the rotating drum body 2310 is loaded into the stack 2500 as shown in FIG. 13D. Done.

In addition, the rotating drum body 2310 can be rotated continuously by being rotated by the drive means 40, wherein the elastic member (2372a) is coupled to the middle of the operating rod (2372) even if the solenoid valve (2371) is not reversed. By overcoming the locking step (2361) (2362) of the door (2360) by the elasticity of the solenoid valve (2371) to prevent damage.

On the other hand, when the food waste inside the rotating drum body 2310 is discharged to the stacking box 2500 through the opening 2311a, the door 2360 is closed again, which drives the rotating drum body 2310 to drive means 40. By rotating in the forward direction as shown in FIG. 13E and advancing the solenoid valve 2371, the opening window 2363 and the rotating drum body 2310 of the door 2360 are caught by the other engaging jaw 22 of the door 2360. The openings 2311a of) are staggered and the door is closed.

Even when the rotating drum body 2310 is rotated in the forward direction in the state in which the door 2360 is closed as described above, the locking step 2361 of the door is caused by the elasticity of the elastic member 2372a coupled to the middle of the operation rod 2372 ( It is to prevent the damage of the solenoid valve (2371) while passing over 2362.

In addition, when the door 2360 is closed, the solenoid valve 2371 is reversed and the rotary drum body 2310 is rotated again in the forward direction.

On the other hand, the wet steam of the rotating drum body 2310 is transferred to the deodorizing unit 3000 which will be described later through the outlet 2340 of the other side cover (2330).

In addition, a leaf spring 2351 protrudes from the wet steam passage hole 2341 formed in the discharge port 2340, and a protruding rod 2352 is formed in the rotary drum body 2310 to form the rotary drum body 2310. The leaf spring 2351 is intermittently caught by the rotation to prevent the wet steam passage hole 2341 from being blocked.

The deodorizing unit 3000 is in communication with the sterilization drying unit 2000, a member for collecting odor particles generated from the food waste being sterilized in the sterilization drying unit 2000 in the fine humidifying particles, a humidification tank 3100 and water bath 3200.

The humidification tank 3100 includes an inlet port 3110, an atomization unit 3120, and an outlet port 3130.

In addition, the odor particles introduced into the humidification tank (3100) is to be forced to exhaust by the external air forced inlet fan (3160), the present invention provides an external air forced inlet fan (3160) in front of the humidification tank (3100). By installing the odor particles introduced through the inlet port 3110 of the humidification tank 3100 to exhaust the outlet port 3130.

The inlet 3110 is that the odor particles generated in the process of processing food waste is introduced, in the present invention is connected to the sterile drying unit 2000, the odor particles generated in the sterile drying unit 2000 is introduced will be.

The atomization unit 3120 converts the fresh water into fine humidified particles to supply moisture to the odor particles introduced into the inlet 3110, and generates ultrasonic waves by supplying power to atomize the water. Shows an example.

The ultrasonic vibrator is effective to use an ultrasonic vibrator that can reduce the power consumption and to reduce the power particles generated by the ultra-fine holes are formed, typically using a circular vibrator based on the plan view, but is not limited thereto. The shape is not limited as long as it can atomize the introduced external water source.

Meanwhile, the atomization unit 3120 of the present invention exemplifies an ultrasonic method including an ultrasonic vibrator, but is not limited thereto. The present invention is a heating method for heating and atomizing water instead of an ultrasonic method with an atomizer, and heated and atomized. A complex method of spraying water with a vibrator or a centrifugal spray method of granulating the sucked water by centrifugal force may be used.

The discharge port 3130, the humidifying particles generated in the atomization portion 3120 is to collect and discharge the odor particles introduced from the inlet 3110.

In addition, one end of the second connection hose (3131) is connected to the discharge port 3130 is coupled to, the second connection hose (3131) is formed in a coil form humidifying particles passing through the second connection hose (3131) To increase the residence time that can be changed to the liquid phase by collecting the odor particles to be discharged to the outside, such as receiving or draining in the liquid state.

That is, the odor particles of the present invention are not discharged into the atmosphere, but are discharged to the container or the sewer to remove odors.

In addition, the humidification tank 3100 may be provided with at least one humidification tank side detection sensor on the upper side of the atomizing portion 3120, preferably the humidification tank side overflow abnormality sensor 3140 and the humidification tank side no water abnormality detection The sensor 3150 is to be installed.

That is, in the atomization part 3120 of the humidification tank 3100, the water is changed into fine humidifying particles. The ultrasonic vibrator is operated when the atomization part 3120 is operated for a long time without supplying water from the water tank 3200 which will be described later. When the abnormality detection sensor 3150 is detected, the water tank 3200 is supplied with water from the water tank 3200 or the operation of the ultrasonic vibrator should be stopped, and the water supply is excessive in the water tank 3200. In this case, since the water may be continuously supplied due to the degradation of the ultrasonic vibrator and the abnormality of the water supply system, when the humidification tank side overflow abnormality sensor 3140 is detected, the water supply from the water tank 3200 is blocked.

The water tank 3200 is connected to the humidification tank 3100 and the communication path 3300 to supply water. The water tank 3200 has a tubular shape to store water in a predetermined amount and to supply the water to the humidification tank 3100. Will be performed.

In addition, a water supply port 3210 for supplying tap water is connected to the water tank 3200, and a water supply solenoid valve 3211 is installed at the water supply port 3210 to control the water supply port under the control of a microcomputer (not shown). When 3210 is open, water is supplied.

In the present invention, the solenoid valve is installed in the water supply port 3210 to automatically supply water to the water tank 3200, but the user may directly open or close a faucet (not shown) connected to the water supply port 3210. There will be.

In addition, an air flow port 3220 to which air is supplied is connected to the water tank 3200, and an air flow solenoid valve 3221 is installed at the air flow hole 3220 to open the air flow hole 3220 under the control of a microcomputer. When the air is supplied to the tank, the water is introduced from the water supply port, and when the water supply is stopped, it is closed to form a vacuum in the tank.

Here, the air flow port 3220 of the present invention has a water tank 3200 in a sealed state, and since the vacuum pressure may be formed inside the water tank 3200 in a closed state, the air flow hole 3220 is opened when water is supplied. As much as the amount of water flowing in is discharged to the air flow port (3220) to facilitate the inflow of water, and close the air flow solenoid valve (3221) of the air flow port (3220) inside the water tank (3200) The vacuum can be formed.

In addition, at least one tank-side water level sensor is installed in the water tank 3200, and preferably, the water tank-side upper level water level sensor 3230 and the water tank-side lower level water level sensor 3240 are installed. ) When the water inside is lower than the water tank side lower limit level sensor 3240, the microcomputer detects and opens the water supply solenoid valve 3211 to allow tap water to flow into the water tank 3200, and the water is filled. When the water tank side upper limit water level detection sensor 3230 is reached, the microcomputer senses and closes the solenoid valve 3211 for water supply.

In addition, a communication solenoid valve 3310 is installed in the communication path 3300 of the humidification tank 3100 and the water tank 3200, and when the tap water is supplied into the water tank 3200, and the humidification inside the humidification tank 3100. When the side water overflow abnormality detection sensor 3140 is detected, the solenoid valve 3310 is closed, and when the water is supplied from the water tank 3200 to the humidification tank 3100, the solenoid valve 3310 is provided. Will be opened.

In addition, in front of the humidification tank (3100) by installing an external air forced inlet fan (3160) by forcibly introducing air from the outside into the humidification tank (3100) by the odor particles generated in the sterilization drying unit 2000, etc. Furnace to control the flow into the humidifier (3100).

Through such a configuration, the deodorization process of the food waste being sterilized is first, the odor particles generated in the process of sterilizing the food waste through the sterilization drying unit 2000 through the inlet 3110 of the humidification tank (3100). This is introduced, which is by the external air forced inlet fan 3160 installed in front of the humidification tank (3100) odor particles generated in the sterilization drying unit (2000) or the like is forced into the humidification tank (3100).

Odor particles introduced into the humidification tank 3100 are collected by the atomized fine humidifying particles in the atomization portion 3120 of the humidification tank 3100.

When the odor particles collected in the humidification tank 3100 are discharged to the outlet 3130 by the pressure of the external air forced inlet fan 3160, the odor particles passing through the outlet 3130 are coil-shaped second connections. As the residence time is extended while passing through the hose 3131, it is changed into a liquid phase and finally discharged to the outside.

In addition, when water is insufficient in the humidification tank 3100 of the present invention, water is automatically supplied from the water tank 3200. Hereinafter, a description will be given with reference to FIG. 20. In one state, the state in which the valve is made transparent indicates the state in which the valve is opened.

The first process (FIG. 20A) is a process in which the communication solenoid valve 3310 installed on the communication path 3300 between the water tank 3200 and the humidification tank 3100 is blocked.

In this process, when the water of the water tank 3200 supplied to the humidification tank 3100 is insufficient, the water tank side lower limit water level sensor 3240 detects and replenishes water, which is the humidification tank 3100 and the water tank 3200. Communication solenoid valve 3310 installed in the communication path (3300) between) is to be blocked.

The second process (FIG. 20B) opens the respective solenoid valves formed in the water supply port 3210 and the air flow port 3220 installed in the water tank 3200 to detect the water tank upper limit water level sensor 3230 of the water tank 3200. This is the process of supplying water.

In this process, water is supplied until the water supply solenoid valve 3211 and the air flow solenoid valve 3221 communicated with the water tank 3200 until the water tank upper limit level sensor 3322 is detected.

The third process (FIG. 20C) is a process of closing the respective solenoid valves formed in the water supply port 3210 and the air flow port 3220 when the water tank side upper limit level sensor 3322 is detected.

In this process, when the water tank side upper limit level sensor 3322 is detected, the water supply solenoid valve 3211 and the air flow solenoid valve 3221 of the water tank 3200 are closed, so that the water tank 3200 is formed in a vacuum state. .

The fourth process (FIG. 20D) is a process of opening the communication solenoid valve 3310 so that the water in the water tank 3200 flows into the humidification tank 3100 and is supplied to the upper portion of the communication path 3300.

In this process, the inside of the humidification tank 3100 is at atmospheric pressure if the water is not filled up to the communication path 3300, and the air goes into the water tank 3200 through the communication path 3300, and a predetermined amount of water is in the tank 3200. Is supplied to the side to be supplied to the upper portion of the communication path (3300).

A fifth process (FIG. 20E) is a process in which humidification is performed in the atomization unit 3120 of the humidification tank 3100.

In this process, the water inside the humidification tank 3100 is converted into humidifying particles while the atomization unit 3120 operates.

The sixth process (FIG. 20f) is a process in which the water of the water tank is automatically supplied to the humidification tank through the communication path when the water humidified in the atomization falls below the communication path.

In this process, when the water inside the humidification tank 3100 becomes less than the communication path 3300 due to atomization, the air inside the humidification tank 3100 is moved to the water tank 3200 side, and a predetermined amount of the water tank 3200 side. Water is automatically supplied to the humidification tank 3100 through the communication path (3300).

When water is filled in the communication path 3300, the internal water of the humidification tank 3100 is pressed to atmospheric pressure, and no more water is supplied by the vacuum pressure of the water tank 3200.

In this state, the water in the humidification tank 3100 continues to be consumed by the atomization unit 3120, and the water in the water tank 3200 is automatically replenished into the humidification tank 3100 so as to be less than the communication path 3300. At this time, since the water supply solenoid valve 3211, the air flow solenoid valve 3221, and the communication solenoid valve 3310 formed in the water tank 3200 do not have separate operations, damage due to frequent opening and closing is prevented and durability is achieved. To improve.

On the other hand, if the humidification tank side no water detection sensor 3150 is detected, the drive of the humidifier stops, and informs the user whether there is an error, such as an alarm.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, it will be understood that various modifications and other embodiments are possible to those skilled in the art.

1: drying container 2: stirring blade
3: heater 1000: salt reduction
1100: injection body 1110: water injection nozzle
1120: cleaning member for the inner wall 1121: lower through passage
1130: dropping space 1200: cover for the input body
1210: UV lamp 1220: UV transmission window
1300: shredder 1310: cylindrical shredding body
1311: long groove 1320: shredding cutter
1330: rotating shaft 1400: reducer
1410: dehydration pipe 1411: dehydration hole
1420: compression screw 1430: drive part
1440 drain 2000: sterile drying unit
2100: transfer unit 2110: transfer path
2120: hot air supply path 2130: slope
2200; Hot air supply means 2210: heater
2220: blowing fan 2300: rotary drum sterilization drying unit
2310: rotating drum body 2311: cylindrical member
2311a: opening 2312: guide
2312a: pressing part 2313: wing
2320, 2330: cover 2340: outlet
2341: wet steam through hole 2350: blocking means
2351: leaf spring 2352: protrusion bar
2360: door 2361,2362: locking jaw
2363: open window 2370: automatic door opening and closing means
2371: solenoid valve 2372: operating rod
2372a: elastic member 2400: driving side driving means
2410: drive motor 2420: prime mover
2430 follower 2440 connection
3000: Deodorizer 3100: Humidification tank
3110: inlet 3120: atomization
3130: outlet 3131: second connection hose
3140: humidification tank water overflow abnormality detection sensor
3150: Humidity tank side water detection abnormality sensor
3160: forced air inlet fan 3200: water tank
3210: water supply port 3211: solenoid valve for water supply
3220: air flow port 3230: water tank upper limit water level sensor
3240: water tank lower limit water level sensor 3300: communication path
3310: Solenoid valve for communication

Claims (33)

A salt reduction unit 1000 for supplying water to the input food waste and dehydrating the food waste including water to reduce the concentration of salt (Nacl) contained in the food waste;
In communication with the salinity reduction unit 1000, the dehydrated food waste flowing from the salinity reduction unit 1000 is dried by rotating, sterile drying unit for sterilizing drying by passing the hot air to the rotating food waste ( 2000);
Being in communication with the sterilization drying unit 2000, the deodorizing unit 3000 for collecting the odor particles generated from the food waste sterilized in the sterilization drying unit 2000 in the fine humidifying particles (3000);
The salinity reduction unit 1000, the input body 1100 to which food waste is put; A water injection nozzle 1110 provided on an inner wall of the input body 1100 to inject water; An injection body cover 1200 connected to an upper portion of the injection body 1100; It is provided on the inner wall of the injection body 1100, the inner wall cleaning member 1120 for washing the inner wall of the injection body 1100; having,
The installation direction of the water injection nozzle 1110 is inclined upwardly so as to be injected toward the lid body 1200,
The inlet body 1100 is formed with a lower through passage 1121 for supplying water, the inner wall cleaning member 1120 has a flexible material, one side is connected to the lower through passage 1121, A food processor capable of recycling food wastes, characterized in that the washing pipe hangs downward due to its own weight.
delete delete The method of claim 1,
Food processor capable of recycling food waste, characterized in that the ultraviolet lamp 1210 is installed in the lower portion of the lid 1200 for the input body.
The method of claim 4, wherein
A food processor capable of recycling food waste, characterized in that an ultraviolet transmission window 1220 is installed at the lower portion of the ultraviolet lamp 1210 provided in the lid 1200 for the input body.
The method of claim 1,
A food processor capable of recycling food waste further comprising a shredder (1300) for shredding food waste in the input body (1100).
The method of claim 6,
The reducer 1400 which is in communication with the lower end of the input body 1100, to reduce the water containing salt in the food waste dropped from the input body 1100; Recyclable food handler.
The method of claim 7, wherein
The reducer 1400,
A side wall communicates with a lower end of the input body 1100, dehydration holes 1411 are formed, and a dehydration tube 1410 having an inner diameter smaller from one side to the other side, and opening at both sides;
A compression screw (1420) rotatably embedded in the dehydrating pipe (1410) and having a spiral or linear stirring blade fixed on a rotating shaft;
A driving unit (1430) is connected to the rear end of the pressing screw (1420) for transmitting power;
delete delete The method of claim 1,
The sterilization drying unit 2000 is in communication with the salinity reduction unit 1000, and communicates with the transport passage 2110 and the transport passage 2110 through which food waste passed through the salinity reduction unit 1000 is transferred. A transfer part 2100 having a hot air supply path 2120 through which hot air is supplied;
Hot air supply means (2200) comprising a heater (2210) and a blowing fan (2220) to supply hot air to the hot air supply path (2120);
Food waste and hot air flowing through the transfer unit 2100 flows in, and the rotating drum body rotates to collide with the food waste introduced therein, while reaching the upper portion of the rotating drum body and falling by its own weight to generate hot hot air. Rotating drum sterilization drying unit 2300 to be sterilized for drying;
Food processor capable of recycling the food waste, characterized in that it comprises a drive means for rotating the rotating drum sterilization drying unit (2300).
The method of claim 11,
The rotating drum sterilization drying unit 2300, covers 2320 and 2330 are coupled to both sides of the rotating drum body 2310, respectively, and through holes 2321 and 2331 are formed in the center of the covers 2320 and 2330. The one side cover 2320 is supported by the conveying flow path 2110 of the transfer unit 2100, the other cover 2330 is recycled food waste, characterized in that the outlet 2340 through which the wet steam is coupled is supported. Possible food handler.
The method of claim 12,
The discharge port 2340 is formed with a wet steam passage hole (2341), and the blockage preventing means (2350) for preventing the blockage of the wet steam passage hole (2341) is characterized in that the food waste is recyclable food further Handler.
The method of claim 13,
The blockage preventing means 2350 is a leaf spring (2351) protruding toward the wet steam passage hole (2341) in the discharge port (2340),
It is formed to protrude on the inner surface of the rotating drum body 2310, characterized in that it comprises a protruding rod (2352) to be intermittently caught in the leaf spring (2351) in accordance with the rotation of the rotating drum body (2310) Food handler that can recycle waste.
The method of claim 11,
Food processor capable of recycling the food waste, characterized in that the inclined surface is formed at the tip of the transfer unit 2100 to discharge the residual discharge water generated from the compressed food waste.
The method of claim 11,
The rotary drum sterilization drying unit (2300), the food waste processor is possible recycling of food waste, characterized in that at least one wing (2313) is attached to the inner wall.
The method of claim 11,
The rotating drum sterilization drying unit (2300), at least one wing (2313) is attached to the inner wall, the edge of the wing (2313) is a food waste recycling machine recyclable, characterized in that the rounded.
The method of claim 11,
The rotary drum sterilization drying unit (2300), at least one wing (2313) is attached to the inner wall, the food waste processor recyclable food waste, characterized in that the blade (2313) is made to be bent.
delete The method of claim 11,
The rotary drum sterilization drying unit 2300 has an opening 2311a is formed to discharge the sterilized dry waste to the outside,
A door 2360 that opens and closes the opening 2311a; And
The food waste processor of claim 1, further comprising a door automatic opening and closing means (2370) for automatically opening and closing the door (2360).
The method of claim 20,
The door 2360 is slid along the outer surface of the rotary drum sterilization drying unit 2300, the locking jaw (2361) (2362) is formed bent at both ends, the guide installed in the rotary drum sterilization drying unit 2300 A food processor capable of recycling food waste, characterized in that both sides are supported by a piece (2312).
The method of claim 21,
The guide piece (2312) is a food processor capable of recycling food waste, characterized in that the pressing portion (2312a) is formed.
The method of claim 20,
An opening window 2363 is formed in the door 2360 so that when the door 2360 is opened, the door 2360 is matched with the opening 2311a of the rotating drum body 2310. Handler.
delete The method of claim 1,
The deodorizing unit 3000, the inlet 3110, the odor particles generated in the process of processing the food waste, the fresh water to supply moisture to the odor particles introduced into the inlet (3110) as fine humidified particles. A humidification tank 3100 including an atomization part 3120 for changing and a discharge port 3130 for collecting and discharging the odor particles introduced from the inlet part 3110 by the humidifying particles generated in the atomization part 3120; And
And a water tank (3200) connected to the humidification tank (3100) and a communication path (3300) to supply water.
The method of claim 25,
Odor particles introduced into the humidification tank (3100) is a food processor capable of recycling the food waste, characterized in that forcible exhaust by the forced air inlet fan (3160).
The method of claim 25,
The humidifier (3100) is a food processor capable of recycling food waste, characterized in that at least one of the humidification tank-side water level sensor is installed.
The method of claim 25,
The atomizer (3120) is a food processor capable of recycling food waste, characterized in that it comprises an ultrasonic vibrator.
The method of claim 25,
The discharge port (3130) is coupled to the second connection hose (3131), the second connection hose (3131) is a food waste processor capable of recycling the food waste, characterized in that the coil form.
The method of claim 25,
The water tank (3200) is provided with a water supply port (3210) for supplying tap water, the water supply port (3210) is a food processor capable of recycling food waste, characterized in that the water supply solenoid valve (3211) is installed.
The method of claim 25,
The water tank (3200) is a food processor capable of recycling food waste, characterized in that the air flow port (3220) is supplied with air is formed.
32. The method of claim 31,
The air flow port (3220) is a food processor capable of recycling the food waste, characterized in that the solenoid valve (3221) for air flow is installed.
The method of claim 25,
The communication path (3300) is a food processor capable of recycling food waste, characterized in that the communication solenoid valve (3310) is installed.

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