KR101392700B1 - Food garbage disposer using microorganism - Google Patents

Abstract

The present invention relates to a device for treating food waste using microorganisms. The device especially comprises: an external housing having a plurality of external feeding holes formed on the rear surface thereof; an internal housing that is installed in the external housing so as to receive food waste to be treated and microorganisms into the internal space thereof and has internal feeding holes formed on both sides thereof and a discharging unit formed on the front surface thereof in order to discharge a mixture of the food waste and microorganisms that are accommodated therein; a top panel that is installed at the top end of the internal housing, is equipped with multiple operation buttons connected with a control unit, and has a lid that is installed in order to be able to rotate; an agitating means for mixing the food waste and microorganisms in the internal space of the internal housing; a deodorizing, absorbing, and discharging means that absorbs external air into the internal housing through the external feeding hole of the external housing and the internal feeding hole of the internal housing, removes smell and moisture therefrom, and discharges the air to the outside of the internal housing; and a storing container that is installed in the front of the internal housing and is slid to be inserted in and separated from the front surface of the external housing so as to receive and store the mixture of the food waste and microorganisms that are discharged through the discharging unit of the internal housing during an agitation procedure by means of the agitating means. Accordingly, the food waste can be easily discharged to the outside, and the discharge of air including bad smells or moisture that is generated during a food waste treating procedure to the outside can be minimized.

Description

{Food Garbage Disposer using Microorganism}

The present invention relates to a food processor using a microorganism, and more particularly, it is capable of easily discharging food processed by a microorganism action to the outside, minimizing the spread of odor, detecting a motor overload caused by the food being loaded, The present invention relates to a food waste disposal apparatus using microorganisms.

Recently, rapid industrial development and increase in waste disposal due to population growth have been pointed out as serious environmental pollution factors.

Among these wastes, food wastes discharged from households, restaurants and food manufacturing factories are not only polluting themselves by producing bad odors, but also polluting the water quality by promoting eutrophication of water when flowing into rivers And the like.

On the other hand, since such food waste contains a large amount of water, it is difficult to collect and transport the waste, and it is difficult to dispose of the waste and it is expensive to dispose of the waste. In the past, There is a limit in that it can not be a method to cause secondary environmental pollution such as food waste and fundamentally dispose of food waste.

To overcome these limitations, many devices for treating food waste have been developed in the past. However, most of these conventional devices have a problem in that, in order to throw away processed food waste to the outside, There is a problem that the air contained in the room spreads into the indoor space and rather causes the surrounding air to deteriorate.

Application No.: 10-2000-0013492, Registration No.: 10-0368042, Title: Disposal apparatus for food waste

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a food waste disposal apparatus, It is also an object of the present invention to provide a food processor using a microorganism capable of minimizing external exhaust of air containing odor or moisture generated during food garbage disposal.

It is another object of the present invention to provide a food waste disposal apparatus using microorganisms capable of quickly solving an overload problem occurring during the treatment of food waste and ensuring stable use of equipment.

In order to solve the above problems, the present invention provides a food processor using microorganisms, comprising: an outer housing having a plurality of external inflow holes formed in its rear surface; An inner housing provided inside the outer housing and having food and microorganisms to be processed to be introduced into the inner space, an inner inflow hole formed on both sides thereof, and a discharge unit for discharging a mixture of food and microorganisms housed therein; An upper panel installed at an upper end of the inner housing and having a plurality of operation buttons connected to the control unit and having a cover rotatably installed; Stirring means for mixing food and microorganisms in the inner space of the inner housing; A deodorizing and sucking and discharging means for sucking the outside air into the inside housing through the outside inflow hole of the outer housing and the inside inflow hole of the inside housing, removing the odor and moisture, and then discharging the outside air to the outside of the inside housing; A reservoir which is installed in front of the inner housing and slides in and out through the front surface of the outer housing and receives and stores a mixture of food and microorganisms discharged through the discharging portion of the inner housing during stirring by the stirring means; .

Here, the discharging unit is fixed to the front surface of the inner housing and has a through hole formed at the center thereof so that a mixture of food and microorganisms can be discharged from the inside of the inner housing; A discharge panel installed in the through hole of the fixed frame and having a plurality of discharge holes; A plurality of lower bolts connecting the fixing frame and the lower portion of the discharge panel; A lower spring installed between the bolt head of the lower bolt and the discharge panel; A plurality of upper bolts connecting the fixing frame and the upper portion of the discharge panel; And an upper spring disposed between the bolt head of the upper bolt and the discharge panel and having a lower rigidity than the lower spring.

The stirring means may include a driving motor installed between the outer housing and the inner housing; A drive pulley installed on a rotary shaft of the drive motor; A driven pulley installed at a predetermined distance from the drive pulley; A belt connected between the drive pulley and the driven pulley to transmit power; A shaft connected to the center of the driven pulley and rotated and inserted into the inner space of the inner housing; And a plurality of stirring vanes provided on an outer surface of the shaft to mix food and microorganisms contained in the inner housing and to push a mixture of food and microorganisms toward the outlet.

In addition, a tension check means for checking the tension of the belt is installed in the inner housing; Wherein the tension checking means comprises: a bracket installed on the inner housing so as to be movable up and down; A tension spring having one end fixed to the outer surface of the inner housing and the other end connected to the upper portion of the bracket; A tension roller rotatably installed at a lower portion of the bracket to provide tension to the belt; And a limit switch installed on an outer surface of the inner housing to detect a movement of the tension roller downward by a predetermined distance and to transmit a signal to the control unit.

The deodorizing and sucking and discharging unit may include a fan motor that operates by receiving a signal from the control unit; A suction fan connected to the motor shaft of the fan motor and sucking air into the inner housing through an outer inlet hole of the outer housing and an inner inlet hole of the inner housing; A communication hole communicating with the inner space of the inner housing is formed on one side of the upper panel and a discharge hole is formed to be spaced apart from the communication hole by a predetermined distance, An ozone sterilizer for sterilizing the ozone sterilizer; A flow pipe through which the air passing through the inner housing and the sterilizer installation unit flows, the upper end of which is connected to the discharge hole of the sterilizer installation unit and the suction fan is installed at the lower end thereof; A heater disposed inside the flow pipe; A perforated plate installed inside the flow pipe at regular intervals; A plurality of deodorizing balls disposed between the perforated plates to remove odors and remaining ozone from the air flowing from the upper side to the lower side of the flow pipe; A connection pipe installed at a lower end of the flow pipe to connect the flow pipe and the suction fan; And a guide passage for receiving the air from which the odor and moisture have been removed from the suction fan and guiding the air between the outer housing and the inner housing.

In addition, a filter is installed in the upper panel, and the air discharged from the inner housing passes through the filter, and then is guided to the communication hole of the sterilizer installation part.

The lower end of the filter is rotatably connected to one side of the upper panel, and the upper end of the filter is connected to a coil spring connected to the other side of the upper panel, and the filter is pulled toward the upper panel.

In addition, an optical sensor connected to the control unit is installed in the reservoir, and the height of the mixture of the food and the microorganism contained therein is measured.

In the food processor using the microorganisms according to the present invention, when the microorganisms are replaced with new microorganisms, the user directly inserts the hand into the inner housing to rotate the stirring wings without pouring the residue, There is an advantage that residues can be easily discharged by pushing the remnants into the storage container and sliding the storage container out of the outer housing.

In addition, since the mixture of food and microorganism can be discharged by using the storage container, it is not necessary for the user to insert his / her hand into the inner space of the inner housing having the stirrer blade in order to extract the mixture of food and microorganism, There is an advantage.

Also, by discharging a small-diameter mixture (mixture of food and microorganisms) through the discharge hole of the discharge portion, and discharging the mixture having a large particle diameter into the gap of the discharge panel spreading from the stationary mold by the weak spring, It is possible to discharge all of the mixture.

Further, since the limit switch of the tension checking means can quickly determine whether an overload has occurred in the stirring means, it is possible to prevent breakage of the apparatus occurring during the stirring process, and to quickly grasp the replacement timing of the stirring means There is an advantage.

In addition, there is an optical sensor installed in the container for detecting the height of the mixture of the food and the microorganism, so that the emission timing can be clearly understood.

In addition, since the suction force generated by the rotation of the suction fan minimizes the discharge of air to the outside of the outer housing, the air can be circulated only in the inner space of the outer housing. At the same time, the sterilizer, Removal of odor and deodorization, etc., there is an advantage that the spread of air containing odor and moisture can be minimized in the interior space provided with the food processor.

In addition, in the related art, a large number of structures are used in which a filter is taken out, washed outside, and then reinserted. However, according to the present invention, when the filter is pulled, the filter collides with the upper panel due to the elastic force of the coil spring, (Fine powder) is easily removed, thereby securing a passage for circulating fresh air to the inside of the machine, so that microorganisms can smoothly supply oxygen and the microorganism can smoothly treat food waste.

1 is a perspective view of a food processor using microorganisms according to the present invention as seen from one direction.
2 is a perspective view of a food processor using microorganisms according to the present invention as seen from the other direction.
FIG. 3 is a perspective view showing a state in which an outer housing of a food processor using microorganisms according to the present invention is removed, viewed from one direction; FIG.
FIG. 4 is a perspective view of a food processor using a microorganism according to the present invention, with the outer housing removed; FIG.
FIG. 5 is a perspective view of a food processor using a microorganism according to the present invention, with the outer housing removed; FIG.
FIG. 6 is a perspective view showing a filter installation of a food processor using microorganisms according to the present invention. FIG.
7 is a view showing a moving state of a filter of a food processor using microorganisms according to the present invention.
8 is a view showing deodorizing and sucking and discharging means of a food processor using microorganisms according to the present invention.
9 is a view showing a storage container of a food waste disposal apparatus using microorganisms according to the present invention.
10 is a view showing a discharging portion of a food processor using microorganisms according to the present invention.
11 is a view showing the appearance of the discharging portion shown in Fig. 10 in detail;
12A to 12C are views showing a state in which a mixture of food and microorganisms is discharged from a discharging portion of a food processor using microorganisms according to the present invention.
13A is a view showing a state of a tension check means when a normal load acts on stirring means of a food processor using microorganisms according to the present invention.
13b is a view showing a tension check means when an overload is applied to a stirring means of a food processor using microorganisms according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a food processor using microorganisms according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a food processor using microorganisms according to the present invention in one direction, and FIG. 2 is a perspective view of a food processor using microorganisms according to the present invention as seen from the other direction.

FIG. 3 is a perspective view of a food processor using a microorganism according to the present invention, in which the outer housing is removed. FIG. 4 is a side view of a food processor using a microorganism according to the present invention, And FIG. 5 is a perspective view of a food processor using microorganisms according to the present invention, with the outer housing removed. Referring to FIG.

FIG. 6 is a perspective view showing a state in which a filter of a food processor using microorganisms according to the present invention is installed, and FIG. 7 is a view showing a filter of a food processor using microorganisms according to the present invention moving.

FIG. 8 is a view showing deodorizing and sucking and discharging means of a food processor using microorganisms according to the present invention, and FIG. 9 is a view showing a storage container of a food processor using microorganisms according to the present invention.

10 is a view showing the discharging portion of the food processor using microorganisms according to the present invention, FIG. 11 is a view showing the discharging portion shown in FIG. 10 in detail, and FIGS. 12A to 12C are views A mixture of food and microorganisms is discharged from a discharging portion of a food processor using microorganisms.

13A is a view showing the tension check means when a normal load is applied to the stirring means of the food processor using the microorganism according to the present invention, and FIG. 13B is a view showing the stirring means of the food processor using the microorganism according to the present invention FIG. 5 is a view showing a state of the tension check means when an overload is applied to the tension member.

The food processor using microorganisms according to the present invention includes an outer housing 100, an inner housing 200 installed inside the outer housing 100, an upper panel 400 installed at the upper end of the inner housing 200, A stirrer 600 for mixing food and microorganisms introduced into the inner space of the inner housing 200 and a deodorizer 600 for removing odors and moisture from the air flowing through the outer and inner housings 200 and 200, And a sucking and discharging device 800. The storage case 900 slides through the front surface of the outer housing 100. [

The outer housing 100 constitutes the outer surface of the food processor according to the present invention, and a plurality of external inlet holes 110 are formed on the rear surface thereof. Fresh air from the outside enters the inside of the food processor through the external inflow hole (110).

In the inner housing 200, food and microorganisms to be processed are put into the inner space. Although not shown in the drawing, a heating means such as a surface heating element is provided below the outer surface of the inner housing 200 so that food and microorganisms And provides the following suitable heat. Since the inner housing 200 has the inner inflow hole 210 formed on both sides thereof, the outer air introduced through the outer inflow hole 110 of the outer housing 100 is guided through the inner inflow hole 210 to the inner housing 200 As shown in FIG.

The inner housing 200 has a front side through which the discharge part 300 is installed.

The discharging unit 300 discharges a mixture of food and microorganisms contained in the inner space of the inner housing 200 and includes a fixed frame 310 installed and fixed on the front surface of the inner housing 200, A lower spring 340 surrounding the lower bolt 330 and a lower spring 340 surrounding the lower bolt 330. The lower bolt 330 and the lower bolt 330 are connected to each other by a bolt, A plurality of upper bolts 350 connecting upper portions of the fixing frame 310 and the discharge panel 320 and upper springs 360 surrounding the upper bolts 350.

The fixing frame 310 is bolted to one side of the penetrating front surface of the inner housing 200 and a through hole 311 is formed at the center so that a mixture of food and microorganisms inside the inner housing 200 can be discharged . The hinge 312 is fixed to the outer surface of the inner housing 200 by the hinge 312 so that the fixing frame 310 is moved in the horizontal direction .

The discharge panel 320 is installed in the through hole 311 of the fixing frame 310 and a plurality of discharge holes 321 are formed. The discharge hole 321 communicates with the through hole 311 and communicates with the inner space of the inner housing 200.

The lower bolt 330 passes through a lower portion of the discharge panel 320 and is fastened to the fixing frame 310 around the through hole 311.

The lower spring 340 is installed between the bolt head of the lower bolt 330 and the discharge panel 320. The lower spring 340 applies an elastic force to move the bolt head portion of the lower bolt 330 away from the discharge panel 320.

The upper bolt 350 passes through the upper portion of the discharge panel 320 and is fastened to the fixing frame 310 around the through hole 311.

The upper spring 360 is installed between the bolt head of the upper bolt 350 and the discharge panel 320. The upper spring 360 applies an elastic force to move the bolt head portion of the upper bolt 350 away from the discharge panel 320. Since the upper spring 360 has a lower rigidity than the lower spring 340, the upper spring 360 is compressed more than the lower spring 340, so that the discharge space becomes larger.

Hereinafter, a process of discharging a mixture of food and microorganisms from the inner housing 200 through the discharging unit 300 will be briefly described with reference to FIGS. 12A to 12C.

When the mixture of the food and the microorganism contained in the inner housing 200 is pushed toward the discharge panel 320 by the rotation of the stirring blade 660 of the stirring means 600 to be described later, (321). Since the diameter of the discharge hole 321 is small, the mixture having a large diameter can not be discharged to the outside through the discharge hole 321.

The large-diameter mixture that can not be discharged is discharged to the outside through the gap generated between the discharge panel 320 and the fixed frame 310. More specifically, when the mixture is pushed toward the discharge panel 320 by the rotation of the stirring blade 660 of the stirring means 600, since the rigidity of the upper spring 360 is weak, the pressure of the mixture pushes the discharge panel 320, The upper part of the frame starts to spread slightly. Through this gap, a mixture of food and microorganisms with a large diameter is discharged. In other words, the residues in the inner housing 200, which are drenched, are gathered together and the water is lubricated and passes over the discharge panel 320 without coming out through the discharge hole 321. In addition, a solid powder-like residue having a small particle size and a small particle size is also dropped into the reservoir 900 through the gap formed above the discharge panel 320. Here, if the strength of the upper spring 360 is adjusted by turning the upper bolt 350, the discharged particle size may be adjusted.

The upper panel 400 is installed at the upper end of the inner housing 200. The upper panel 400 is provided with a plurality of operation buttons 410 connected to the control unit C and the cover 420 is rotatably installed.

A filter 500 is installed in the upper panel 400 so that when the outside air is introduced into the inner housing 200 and then discharged to the outside, the upper panel 400 is filtered and then discharged outside the inner housing 200. Air is discharged to the outside of the inner housing 200 through the communication hole 832 of the sterilizer installation portion 830 to be described later. The filter 500 is installed just in front of the communication hole 832, Thereby preventing the fine powder from flowing into the ozone sterilizer 831 or the deodorizing ball 870 to deteriorate the function of the apparatus.

The lower end of the filter 500 is rotatably connected to one side of the upper panel 400. The upper end of the filter 500 is connected to one end of the coil spring 510. The other end of the coil spring 510 is connected to the other end of the upper panel 400. [ More specifically, the coil spring 510 has one end connected to the upper end of the filter 500 and the other end connected to the upper panel 400. The upper portion of the filter 500 is pulled toward the upper panel 400 The elastic force is applied.

Accordingly, when the foreign substance is attached to the filter 500 and the foreign substance is to be removed, the upper part of the filter 500 is pulled and rotated by a predetermined angle. Then, when the filter 500 is attached to the elastic force of the coil spring 510, So that the foreign matter adhered to the filter 500 falls into the inner space of the inner housing 200.

The stirring means 600 mixes food and microorganisms in the inner space of the inner housing 200 and includes a driving motor 610, a driving pulley 620 receiving rotational force from the driving motor 610, A driven pulley 630 spaced a predetermined distance from the driving pulley 620 and a belt 640 connecting the driving pulley 620 and the driven pulley 630 to each other; And a plurality of stirring blades 660 mounted on the shaft 650. The shaft 650 is rotatably connected to the shaft 650,

The driving motor 610 is installed between the outer housing 100 and the inner housing 200 and provides rotational force to the stirring means 600.

The driving pulley 620 is disposed between the outer housing 100 and the inner housing 200 and is installed on the rotating shaft of the driving motor 610 and rotates when the rotating shaft rotates.

The driven pulley 630 is positioned between the outer housing 100 and the inner housing 200 and has a larger diameter than the drive pulley.

The belt 640 transfers the power of the drive pulley 620 to the driven pulley 630 so that the driven pulley 630 rotates when the rotation shaft of the drive motor 610 rotates.

The shaft 650 is inserted into the inner space of the inner housing 200 and is connected to the center of the driven pulley 630 and rotates when the driven pulley 630 rotates.

A plurality of stirring vanes 660 are installed along the outer surface of the shaft 650. The stirring vanes 660 mix food and microorganisms contained in the inner housing 200. The stirring blade 660 pushes the mixture of the food and the microorganism toward the discharging part 300 and more specifically toward the discharging panel 320 of the discharging part 300 while rotating.

In order to check the tension of the belt 640 of the agitating means 600, tension checking means 700 is installed in the inner housing 200 according to the present invention. The tension check means 700 includes a bracket 710 installed in the inner housing 200 and a tension spring 720 connected at one end and the other end to the inner housing 200 and the bracket 710, A tension roller 730 mounted on the tension roller 710 and a limit switch 740 contacting the tension roller 730.

The bracket 710 is installed on the outer surface of the inner housing 200 so as to be movable up and down.

One end of the tension spring 720 is fixed to the outer surface of the inner housing 200 and the other end is connected to the upper portion of the bracket 710.

The tension roller 730 is rotatably installed at a lower portion of the bracket 710 to provide tension to the belt 640. That is, the tension roller 730 contacts the outer surface of the belt 640 and raises the belt 640 slightly upward so that the belt 640 is tensioned.

The limit switch 740 is installed on the outer surface of the inner housing 200 and detects the movement of the tension roller 730 downward by a predetermined distance to send a signal to the controller C. [

Here, the operation of the tension check means 700 will be briefly described with reference to FIGS. 13A to 13B.

When the load applied to the agitating means 600 is normal, the bracket 710 is slightly moved upward to keep the tension spring 720 in a compressed state, and the tension roller 730 is also slightly upward And is in contact with the outer surface of the belt 640.

The belt 640 pushes the tension roller 730 downward and the bracket 710 moves downward and the tension spring 720 is extended and the length of the tension roller 730 is increased It grows longer. Then, the tension roller 730 strongly urges the limit switch 740 located at the lower portion thereof, and the limit switch 740 transmits the signal to the control portion C, thereby recognizing that the overload has occurred. The controller C rotates the driving motor 610 of the stirring means 600 to rotate the stirrer 660 so that the load generating material placed in the stirring blade 660 can be taken out.

The deodorizing and sucking and discharging means 800 sucks the outside air into the inner housing 200 through the outer inflow hole 110 of the outer housing 100 and the inner inflow hole 210 of the inner housing 200 And then discharged to the outside of the inner housing (200). The deodorizing and sucking and discharging means 800 includes a fan motor 810, a suction fan 820 provided with a rotational force by the fan motor 810, a sterilizer installation part 820 provided on one side of the upper panel 400, A fluid pipe 840 installed between the outer housing 100 and the inner housing 200 and a heater 850 installed inside the fluid pipe 840; A deodorizing ball 870 disposed between the perforated plate 860 and a connecting pipe 880 installed at a lower end of the flow pipe 840; And a guide passage 890 connected to the suction fan 820.

The fan motor 810 operates by receiving a signal from the controller C and is installed between the outer housing 100 and the inner housing 200.

The suction fan 820 is connected to the motor shaft of the fan motor 810 and is rotated to suck air. The suction fan 820 is strongly rotated to suck external air through the external inlet hole 110 of the external housing 100 and to discharge the sucked air into the internal inlet hole 210 of the internal housing 200 Thereby allowing the outside air to flow into the inner space of the inner housing 200. It is natural that the force acting on the air flow thereafter is also the suction force of the suction fan 820. [

The sterilizer installation part 830 is provided with an ozone sterilizer 831 for sterilizing ozone. The sterilizer installation part 830 has a communication hole 832 and a discharge hole 833.

The ozone sterilizer 831 is installed inside the sterilizer installation unit 830 provided in the upper panel 400 and is electrically connected to the control unit C and operated by a signal of the control unit C.

The communication hole 832 is formed on one side of the sterilizer installation portion 830 and communicates with the inner space of the inner housing 200. The air introduced into the inner housing 200 through the inner inflow hole 210 flows into the sterilizer installing unit 830 through the communication hole 832 by the suction force of the suction fan 820.

The discharge hole 833 is formed on the lower surface of the sterilizer installation part 830 at a predetermined distance from the communication hole 832. The air introduced through the communication hole 832 is sterilized by the ozone sterilizer 831 with ozone and then discharged to the outside of the sterilizer installation portion 830 through the discharge hole 833.

The upper end of the flow pipe 840 is connected to the discharge hole 833 of the sterilizer installation part 830 and receives air passing through the inner housing 200 and the sterilizer installation part 830. A suction fan 820 is installed at the lower end of the flow pipe 840 to provide power to the flow of air.

The heater 850 functions to remove odor and moisture by heating the air containing odor or moisture inside the flow pipe 840.

The perforated plate 860 is formed with a plurality of perforation holes 861 so that the deodorized ball 870 is stably positioned within the flow pipe 840.

The deodorizing ball 870 is made of spherical ceramics having a large specific surface area of about 4 mm in diameter and has a special coating on the outside of the alumina ball. The deodorizing ball 870 has odor and remaining ozone in the air flowing down from the upper side of the flow pipe 840 Remove. That is, when the deodorizing ball 870 comes into contact with the air introduced through the perforation hole 861 of the upper perforated plate 860, the perforated hole 860 of the lower perforated plate 860 absorbs the odor contained in the air, The air is discharged through the opening 861.

The connection pipe 880 is installed between the outer housing 100 and the inner housing 200 and is installed at the lower end of the fluid pipe 840 to connect the fluid pipe 840 to the suction fan 820 do. That is, the air introduced into the flow pipe 840 by the suction force of the suction fan 820 enters the suction fan 820 through the connection pipe 880.

The guide passage 890 is installed between the lower surface of the outer housing 100 and the inner housing 200 and receives the air from which the odor and moisture have been removed from the suction fan 820, And the inner housing (200). That is, the air that has entered the suction fan 820 flows through the interior of the guide passage 890 and is discharged to the space between the outer housing 100 and the inner housing 200. The air discharged into the space between the outer housing 100 and the inner housing 200 after flowing through the guide passage 890 flows into the inner space of the inner housing 200 through the inner inflow hole 210 of the inner housing 200 And the odor and moisture are removed through the same process as described above.

The reservoir 900 is installed in front of the inner housing 200 and more specifically in front of the discharging unit 300 and is pushed by the stirring blade 660 during the stirring process by the stirring unit 600, And a micro-organism mixture discharged through the unit 300 is received and stored. The storage case 900 is configured to slide in and out through the front surface of the outer housing 100.

In the storage bin 900, an optical sensor 910 connected to the control unit C is installed. When the height of the mixture of the food and the microorganism contained in the storage container 900 is measured through the operation of the optical sensor 910 and the mixture needs to be discharged, the storage container 900 is taken out and discharged.

100: outer housing 110: outer inflow hole
200: inner housing 210: inner inflow hole
300: discharging portion 310: fixed frame
311: Through hole 312: Hinge
320: Discharge panel 321: Discharge hole
330: lower bolt 340: lower spring
350: upper bolt 360: upper spring
400: upper panel 410: operation button
420: cover 500: filter
510: coil spring 600: stirring means
610: Driving motor 620: Driving pulley
630: driven pulley 640: belt
650: shaft 660: stirring blade
700: tension check means 710: bracket
720: Tension spring 730: Tension roller
740: Limit switch 800: deodorizing and sucking and discharging means
810: Fan motor 820: Suction fan
830: Sterilizer installation part 831: Ozone sterilizer
832: communication hole 833: exhaust hole
840: Flow piping 850: Heater
860: perforated plate 861: perforated hole
870: deodorization ball 880: connection piping
890: Information channel 900: Storage container
910: optical sensor C: control unit

Claims (9)

An outer housing (100) having a plurality of outer inflow holes (110) formed on a rear surface thereof;
A discharging unit 300 installed in the outer housing 100 for feeding food and microorganisms to be processed into the inner space, forming an inner inflow hole 210 on both sides thereof, and discharging a mixture of food and microorganisms contained in the outer housing 100, An inner housing 200 having a front surface;
An upper panel 400 installed at an upper end of the inner housing 200 and having a plurality of operation buttons 410 connected to the control unit C and having a lid 420 rotatably installed;
An agitating means (600) for mixing food and microorganisms in the inner space of the inner housing (200);
Outer air is sucked into the inner housing 200 through the outer inflow hole 110 of the outer housing 100 and the inner inflow hole 210 of the inner housing 200 and then the odor and moisture are removed, A deodorizing and sucking and discharging means 800 for discharging the deodorant to the outside of the apparatus 200;
And is disposed in front of the inner housing 200 and slid in and out through the front surface of the outer housing 100. During the stirring process by the stirring means 600, And a reservoir 900 for receiving and storing a mixture of food and microorganisms discharged through the reservoir and measuring the height of the mixture of food and microorganisms contained in the reservoir 910 and an optical sensor 910 connected to the controller C A food processor using microorganisms.
The method according to claim 1,
The discharging unit 300 is fixed to the front surface of the inner housing 200 and has a through hole formed at a center thereof so that a mixture of food and microorganisms inside the inner housing 200 can be discharged.
A discharge panel 320 provided in the through hole 311 of the fixing frame 310 and having a plurality of discharge holes 321 formed therein;
A plurality of lower bolts 330 connecting the lower portion of the fixing frame 310 to the lower portion of the discharge panel 320;
A lower spring 340 installed between the bolt head of the lower bolt 330 and the discharge panel 320;
A plurality of upper bolts 350 connecting the upper part of the fixing frame 310 and the upper part of the discharge panel 320;
And an upper spring (360) installed between the bolt head of the upper bolt (350) and the discharge panel (320) and having a lower rigidity than the lower spring (340).
The method according to claim 1,
The stirring means 600 includes a driving motor 610 installed between the outer housing 100 and the inner housing 200;
A driving pulley 620 installed on the rotating shaft of the driving motor 610;
A driven pulley 630 spaced apart from the driving pulley 620 by a predetermined distance;
A belt 640 connecting the drive pulley 620 and the driven pulley 630 to transmit power;
A shaft 650 coupled to the center of the driven pulley 630 and inserted into the inner space of the inner housing 200;
A stirring blade 660 provided on the outer surface of the shaft 650 to mix food and microorganisms contained in the inner housing 200 and to push a mixture of food and microorganisms toward the discharging unit 300; And a microorganism-based food waste treatment apparatus.
The method of claim 3,
A tension check means 700 for checking the tension of the belt 640 is installed in the inner housing 200,
The tension check means 700 includes a bracket 710 mounted on the inner housing 200 so as to be movable up and down;
A tension spring 720 having one end fixed to the outer surface of the inner housing 200 and the other end connected to the upper portion of the bracket 710;
A tension roller 730 rotatably installed at a lower portion of the bracket 710 to apply tension to the belt 640;
And a limit switch (740) installed on an outer surface of the inner housing (200) for sensing the movement of the tension roller (730) downward by a predetermined distance and sending a signal to the controller (C) Food processor using.
The method according to claim 1,
The deodorizing and sucking and discharging means 800 includes a fan motor 810 operated by receiving a signal from the controller C;
The motor shaft of the fan motor 810 is connected to the motor shaft of the fan motor 810 and rotates so that air flows in the inner housing 200 through the outer inlet hole 110 of the outer housing 100 and the inner inlet hole 210 of the inner housing 200, A suction fan 820 for sucking in the refrigerant;
A communication hole 832 is formed at one side of the upper panel 400 and communicated with an inner space of the inner housing 200 and a communication hole 832 is formed at a certain distance from the communication hole 832, A sterilizer installation part 830 in which an ozone sterilizer 831 for sterilizing air introduced through the communication hole 832 with ozone is installed;
An upper end is connected to a discharge hole 833 of the sterilizer installing portion 830 and a suction fan 820 is installed at a lower end of the sterilizing device installation portion 830 to allow air passing through the inner housing 200 and the sterilizer installation portion 830 to flow Flow tubing 840;
A perforated plate 860 installed at predetermined intervals in the flow pipe 840;
A plurality of deodorizing balls 870 disposed between the perforated plates 860 to remove odors and remaining ozone from the air flowing from the upper side to the lower side of the flow pipe 840;
A connection pipe 880 installed at the lower end of the fluid pipe 840 and connecting the fluid pipe 840 to the suction fan 820;
And a guide channel (890) for receiving the air from which the odor and moisture have been removed from the suction fan (820) and guiding it between the outer housing (100) and the inner housing (200).
The method of claim 5,
Wherein the deodorizing and sucking and discharging means (800) further comprises a heater (850) installed in the upper side of the flow pipe (840).
The method of claim 5,
A filter 500 is installed in the upper panel 400 so that the air discharged from the inner housing 200 is guided to the communication hole 832 of the sterilizer installation unit 830 after passing through the filter 500 Wherein the microorganism is a food waste.
The method of claim 7,
A lower end of the filter 500 is rotatably connected to one side of the upper panel 400 and a coil spring 510 connected to the other side of the upper panel 400 is connected to the upper end of the filter 500, Wherein the filter (500) is pulled toward the upper panel (400).
delete

Images