KR20100082887A - A food-rest treatment apparatus - Google Patents

Abstract

PURPOSE: A food waste processor is provided to improve processing efficiency of food waste by improving agitating efficiency of the food waste with an agitating vane rotated upwards and downwards, and to reduce fermentation time of the food waste. CONSTITUTION: A food waste processor comprises the following: a first fermentation chamber(200) with an inlet(210) receiving food waste and microorganism; a second fermentation chamber(300) refermenting the food waste fermented in the first fermentation chamber; a rotary shaft(400) pivotally installed and penetrating the first and the second fermentation chambers; first agitator(500) revolving the food waste; a second agitator(600) agitating the food waste; a lifting rotation part(700) rotating the rotary shaft; and an air supply part installed at the second fermentation chamber.

Description

A food-rest treatment apparatus

The present invention relates to a food waste treatment apparatus, and more particularly, to a food waste treatment apparatus for treating food waste by fermentation and liquefaction.

In general, food waste is discharged daily from homes or restaurants, and the food waste is used as livestock feed or simply filtered through a strainer and then discarded. This food waste treatment method causes odor if the food waste is not disposed of smoothly, contaminating surrounding drinking water sources or air. Food waste treatment apparatus has been developed and used to prevent this.

In general, the food waste treatment apparatus is fermented by heating and stirring the food waste, the fermentation gas and steam generated during the fermentation process is deodorized and discharged, and the waste is collected and discarded or composted.

Korean Unexamined Patent Publication No. 2002-0023386 discloses a food waste treatment apparatus.

The food waste processing apparatus vertically installs a conical screw to which a loading plate with a cutter is attached and a housing accommodating the screw in a chamber into which the food waste and the biochip are inserted, and rotates in a direction opposite to the screw on the outside of the housing. The stirring rod is installed vertically and the screw is rotated to ferment the food waste with stirring.

However, since the food waste treatment apparatus accommodates a large amount of food waste in a single chamber, the food waste takes a long time to ferment, and the stirring rod and screw are fixed to one side and thus, the stirring efficiency is lowered.

The present invention has been made to improve the above problems, an object of the present invention is to provide a food waste treatment apparatus that can shorten the fermentation time of food waste by improving the stirring efficiency and fermentation efficiency of food waste.

Food waste treatment apparatus of the present invention for achieving the above object is a first fermentation chamber having an inlet for food waste and microorganisms, and a second fermentation in the first fermentation chamber to accommodate the liquefied or refined food waste to re-ferment The food waste is mounted on the rotating shaft rotatably installed to move up and down through the fermentation chamber, the first fermentation chamber and the second fermentation chamber, and rotated in the interior of the first fermentation chamber. A first stirring member for stirring a second stirring member mounted on the rotating shaft inside the second fermentation chamber to stir the food waste contained in the second fermentation chamber, and a lifting and lowering rotating unit for rotating while raising and lowering the rotating shaft; And an air supply unit installed in the second fermentation chamber to supply air.

The first stirring member includes a plurality of through holes formed on the outer circumferential surface of the first fermentation chamber so that the food wastes liquefied or finely decomposed by fermentation can be introduced therein, and an inner space in which the food wastes introduced through the through holes are accommodated. The rotating shaft is provided with a conveying passage for transporting the food waste introduced into the inner space of the first stirring member to the lower portion, and discharges the food waste conveyed through the conveying passage to the second fermentation chamber. It is preferred to have an outlet.

The first stirring member is a body having a plurality of through holes, a plurality of upper stirring blades formed concave in the rotational direction of the body to converge the food waste in the rotation center direction on the upper portion of the body, The lower part has a plurality of lower stirring blades formed convexly in the rotational direction of the body to disperse food waste in the direction of the edge of the body.

The air supply unit includes an external suction tube for sucking fresh air from the outside, a fermentation chamber suction tube installed in the first fermentation chamber to suck air in the first fermentation chamber, and a fan connected to the external suction tube and the fermentation chamber suction tube to provide suction power. A mixing tube connected to the member, the external suction tube and the fermentation chamber suction tube to mix the air sucked through the external suction and the fermentation chamber suction tube, and heat the mixing tube to increase the temperature of the air mixed by the mixing tube. A heater, an injection tube connected between the mixing tube and the second fermentation chamber to inject the high temperature mixed air formed by the mixing tube into the second fermentation chamber, and attached to the mixing tube to absorb odor components in the mixed air. It is preferable to have a deodorizing member.

The elevating rotary part is installed on the rotating shaft, the boss having a guide groove formed in a closed track to be curved up and down on the outer circumference to elevate the rotating shaft, and one side so that the boss can move up and down along the guide groove Is inserted into the guide groove, the other side is provided with an interference piece fixed to the frame, a slider coupled to the boss so as to slide along the longitudinal direction of the rotation axis with respect to the boss, and a drive unit for rotating the slider.

In addition, the food waste treatment apparatus according to the present invention is installed in the second fermentation chamber to suck the liquefied food waste inside the second fermentation chamber and the liquid suction pipe installed in the first fermentation chamber and sucked by the liquid suction tube Liquid discharge pipe having a plurality of liquid discharge ports on the outer circumferential surface so as to discharge the food waste, and connected to the liquid suction pipe and the liquid discharge pipe, suck the liquefied food waste through the liquid suction pipe, liquefied through the liquid discharge pipe It further comprises a liquid feeder having a pump for discharging the food waste.

Food waste treatment apparatus according to the present invention has the advantage of reducing the fermentation time of food waste by fermenting the food waste in multiple stages, the stirring member is raised and lowered to increase the stirring efficiency of the food waste to improve the processing capacity of food waste. to provide.

Hereinafter, with reference to the accompanying drawings will be described in more detail food waste treatment apparatus according to a preferred embodiment of the present invention.

1 is a food waste treatment apparatus 100 according to an embodiment of the present invention.

Referring to the drawings, the food waste treatment apparatus 100 includes a first fermentation chamber 200, a second fermentation chamber 300, a rotating shaft 400, a first stirring member 500, a second stirring member 600, and an ascending and descending cycle. It is provided with the whole 700 and the air supply unit 800.

The first fermentation chamber 200 has a receiving space to accommodate food waste and microorganisms to ferment. The accommodation space of the first fermentation chamber 200 has a size such that the first stirring member 400, which will be described later, is rotated while moving up and down inside the first fermentation chamber 200. An upper portion of the first fermentation chamber 200 is provided. Is the inlet 210 for food waste and microorganisms are formed.

The second fermentation chamber 300 has an accommodation space of a predetermined size so as to be fermented in the first fermentation chamber 200 to be re-fermented by liquefied or refined food waste. The second fermentation chamber 300 is formed in a structure in which a part of the first fermentation chamber 200 is embedded to shorten the delivery path of the food waste fermented from the first fermentation chamber 200 to the second fermentation chamber 300. Although not shown in the drawing, unlike the present embodiment, the first fermentation chamber 200 and the second fermentation chamber 300 may be installed to be adjacent to each other.

In addition, the second fermentation chamber 300 is installed on the outer circumferential surface of the sewage discharge valve 310 for discharging sewage, and the second fermentation chamber 300 is installed on the bottom of the food waste treatment apparatus 100 at the time of inspection, the second fermentation chamber 300 is provided with a check discharge valve 430 for discharging all the food waste inside.

The sewage discharge valve 310 is configured by an electronic valve, it is preferable to control the discharge time of the liquefied food waste by setting to open and close every 1 hour or 30 minutes.

The rotary shaft 400 is rotatably installed to move up and down through the first fermentation chamber 200 and the second fermentation chamber 300. The contact portion of the first fermentation chamber 200, the second fermentation chamber 300 and the rotary shaft 400 is provided with a bearing 410 so that the rotary shaft 400 can be easily driven.

In addition, the rotary shaft 400 includes a transfer passage 420 and an outlet 430 to transfer the fermented food waste from the first fermentation chamber 200 to the second fermentation chamber 300.

The conveying passage 420 is formed by penetrating the inside of the rotating shaft 400 in the longitudinal direction and is connected to the inner space 512 of the first stirring member 500 to be described below to convey fermented food waste.

A plurality of discharge ports 430 are formed on the rotating shaft 400 inside the second fermentation chamber 300, and the fermented food waste transferred through the transfer passage 420 in connection with the transfer passage 420 may be a second fermentation chamber ( 300).

The first stirring member 500 of the food waste treatment apparatus 100 according to the present invention is illustrated in FIGS. 2 to 3.

Referring to the drawings, the first stirring member 500 is mounted on the rotary shaft 400 inside the first fermentation chamber 200 to agitate food waste, and moves up and down inside the first fermentation chamber 200. The body 510, the upper stirring blade 520 and the lower stirring blade 530 are provided.

The body 510 is formed in a disk plate structure to be easily rotated in the interior of the first fermentation chamber 200, the food waste is liquefied or finely decomposed by the fermentation in the first fermentation chamber 200 to the outer peripheral surface is introduced A plurality of through holes 511 are formed, and the inside of the body 510 includes an inner space 512 in which food waste introduced through the through holes 511 is accommodated.

The inner space 512 is connected to the conveying passage 420 of the rotating shaft 400 to become a passage through which liquefied or refined food waste is conveyed.

The upper stirring blade 520 is formed to protrude on the upper portion of the body 510, and is formed to be concave in the rotational direction of the body 510 has an interference action to converge the food waste in the direction of the center of rotation of the body 510. The outer circumferential surface of the upper stirring blade 520 is preferably formed with a through hole 511 to allow food waste to flow.

The lower stirring wing 530 is formed to protrude in the lower portion of the body 510 and is convexly formed in the rotational direction of the body 510 to distribute food waste in the direction of the edge of the body 510.

Meanwhile, in the illustrated example, a structure in which four upper stirring blades 520 and four lower stirring blades 530 are formed on the body 510 has been described, but the upper stirring blade 520 and the lower stirring blade 530 are applied. The number is not limited to the illustrated example, a plurality of stirring blades may be installed.

The second stirring member 600 is mounted on the rotary shaft 400 inside the second fermentation chamber 300 to agitate the food waste contained in the second fermentation chamber 300. The second stirring member 600 protrudes from the outer circumferential surface of the rotation shaft 400, and a plurality of through holes are formed on the outer circumferential surface thereof, so that food waste can be efficiently stirred. Although not shown in the drawings, the second stirring member 600 may be formed to be inclined at a predetermined angle to easily stir the food waste.

The lifting lowering rotating unit 700 rotates the rotating shaft 400 up and down, and includes a boss 710, an interference piece 720, a slider 730, and a driving unit 740.

The boss 710 is installed at the lower portion of the rotary shaft 400 and has a wave shaped guide groove 711 along the outer circumferential surface so as to raise and lower the rotary shaft 400.

On the other hand, the boss 710 is formed with a key groove (not shown) corresponding to the key 731 of the slider 730 to be described later on the side of the boss 710 to receive a rotational force from the slider 730. Although not shown in the drawing, unlike the present embodiment, the boss 710 may be formed integrally with the rotation shaft 400.

The interference piece 720 is inserted into the guide groove 711 so that the boss 710 can move up and down along the guide groove 711 and the other side is fixed to the frame 750. One side of the interference piece 720 is provided with a rotating wheel 721 rotatably fixed so that the boss 710 into which the interference piece 720 is inserted can easily rotate. The interference piece 720 is preferably formed of a material having a strength sufficient to support the rotation shaft 400.

The slider 730 is coupled to the boss 710 so as to be slidable along the longitudinal direction of the rotation axis 400 with respect to the boss 710, and the outer circumferential surface of the plurality of keys 731 to transmit rotational force to the boss 710. Is formed.

The driving unit 741 rotates the slider 730, a bracket 741 rotatably supporting the slider 730, a driven sprocket 742 fastened to the slider 730, and a driving motor supplying rotational force ( 743, a driving sprocket 744 fastened to the driving motor 743 to transmit rotational force, and a chain 745 connecting the driven sprocket 742 and the driving sprocket 744.

When rotational force is supplied to the slider 730 by the driving unit 740, the slider 730 rotates the boss 710 by the key 731 formed on the outer circumferential surface. The boss 710 moves up and down along the trajectory of the guide groove 711 formed on the outer circumferential surface by the interference piece 720.

The air supply unit 800 is installed in the second fermentation chamber 300 so as to supply air to activate the activities of aerobic microorganisms, the external suction pipe 810, the fermentation chamber suction pipe 820, the fan member 830, the mixing pipe ( 840, a heater 850, a deodorizing member 860, and an injection tube 870 are provided.

The external suction pipe 810 is installed outside to suck fresh air from the outside, and the fermentation chamber suction pipe 820 is installed above the first fermentation chamber 200 to suck the air inside the first fermentation chamber 200.

The fan member 830 provides a suction force so that the external suction pipe 810 and the fermentation chamber suction pipe 820 may suck air. Although not shown in the drawing, unlike the present embodiment, separate fans may be installed in the external suction pipe 810 and the fermentation chamber suction pipe 820, respectively.

The mixing tube 840 is connected to the external suction tube 810 and the fermentation chamber suction tube 820 to mix the air sucked through the external suction tube 810 and the fermentation chamber suction tube 820.

The heater 850 is installed at a position adjacent to the mixing tube 840, and heats the mixing tube 840 to increase the temperature of the mixing air so that the temperature of the mixing air can increase the fermentation efficiency of the microorganisms. Deodorizing member 860 is mounted to the mixing tube 840 to absorb the odor component in the mixed air. The air mixed by the mixing tube 840 is moved to the injection tube 870 through the heater 850 and the deodorizing member 860.

The injection tube 870 is connected between the mixing tube 840 and the second fermentation chamber 300 to inject the mixed air of the conditions suitable for the fermentation formed by the mixing tube 840 into the second fermentation chamber 300.

On the other hand, the food waste treatment apparatus 100 according to the present invention is a liquid phase for supplying the liquefied food waste to the first fermentation chamber 200 in the second fermentation chamber 300 to increase the fermentation efficiency inside the first fermentation chamber 200 It is further provided with a feeder 900. The liquid supplier 900 includes a liquid suction tube 910, a liquid discharge tube 920, and a pump unit 930.

The liquid suction tube 910 is installed in the second fermentation chamber 300 so that the suction port can be inserted into the food waste so as to suck the liquefied food waste inside the second fermentation chamber 300. Do.

The liquid discharge pipe 920 is inserted into the first fermentation chamber 200 and includes a plurality of liquid discharge ports 921 on the outer circumferential surface to discharge the liquefied food waste sucked by the liquid suction pipe 300. The liquid discharge port 921 is preferably formed to face the direction in which the food waste in the first fermentation chamber 200 is accommodated.

The pump unit 930 is connected to the liquid suction tube 910 and the liquid discharge tube 920 to suck the liquefied food waste of the second fermentation chamber 300 and discharge it to the first fermentation chamber 200. On the other hand, the liquid suction pipe 910 is installed on the upper side of the pump housing 931 which will be described later, the liquid discharge pipe 920 is preferably installed on the outer peripheral surface of the upper side of the pump housing 931. The pump unit 930 includes a pump housing 931, a suction check valve 932, a discharge check valve 933, a piston 934, a piston rod 935, a rotation wheel 936, and an auxiliary rotating plate 937. A spring 938 is provided.

The pump housing 931 is formed in a cylindrical shape having an inner space. The pumping amount of the pump unit 930 is determined once according to the width of the inner space of the pump housing 931.

The suction check valve 932 is installed in the liquid suction pipe 910 adjacent to the pump housing 931, and is configured to open only in the direction in which the food waste is injected into the pump housing 931. To prevent backflow into the two fermentation chamber (300).

The discharge check valve 933 is installed in the discharge suction pipe 920 adjacent to the pump housing 931, and is configured to open only in the direction in which the food waste is discharged from the inside of the pump housing 931.

The piston 934 is installed in the pump housing 931 so as to be able to reciprocate up and down, and the cross section of the piston 934 has an outer diameter corresponding to the inner diameter of the pump housing 931 to maintain airtightness. Although not shown in the drawings, the piston 934 is a compression ring installed to maintain the airtight between the pump housing 931 and the piston 934 and the piston by lubricating the inner wall of the piston 934 and the pump housing 931 The oil ring may be provided to prevent wear of the 934 and the pump housing 931.

The piston rod 935 is formed of an elongated rod installed under the piston 934 and reciprocates the piston 934 up and down.

The rotary wheel 936 is rotatably installed at the end of the piston rod 935 and in contact with the upper surface of the auxiliary rotating plate 937, and transmits a vertical movement force to the piston rod 935.

The auxiliary rotating plate 937 is installed on the rotating shaft 400, and moves up and down along the rotating shaft 400, the upper surface is formed of a disk having a flat cross section so that the rotating wheel 936 abuts.

Restoring spring 938 is installed on the piston rod 935, when the piston rod 935 is raised by the rise of the auxiliary rotating plate 937, the restoring spring 938 is compressed, when the auxiliary rotating plate 937 is lowered, As the compressed recovery spring 938 is tensioned, the piston rod 935 is lowered to restore the piston 934 to a set position.

When the piston 934 inside the pump housing 931 is lowered by the lowering of the auxiliary rotating plate 937, the food waste of the second fermentation chamber 300 is injected into the pump housing 931. At this time, the food waste of the first fermentation chamber 200 is not injected into the pump housing 931 by the discharge check valve 933. When the piston 934 rises due to the increase of the auxiliary rotating plate 937, the food waste inside the pump housing 931 is discharged to the liquid discharge pipe 920. At this time, food waste is prevented from being injected into the second fermentation chamber 300 by the suction check valve 932.

Referring to the operation of the food waste treatment apparatus 100 according to the embodiment of the present invention configured as described above are as follows.

First, the food waste to be treated is introduced into the first fermentation chamber 200 through the inlet 210 together with the microorganisms. The food waste put into the first fermentation chamber 200 is stirred and fermented by the first stirring member 500 which rotates while moving up and down inside the first fermentation chamber 200.

At this time, the liquid supply unit 900 is fermented in the second fermentation chamber 300 to inject the liquefied food waste into the first fermentation chamber 200. Since the food waste of the injected second fermentation chamber 300 includes activated microorganisms, the fermentation time is reduced by maximizing the fermentation efficiency per unit area of the microorganisms in the first fermentation chamber 200.

The food waste which is fermented and liquefied or refined in the first fermentation chamber 200 is introduced into the through hole 511 of the first stirring member 500, and the introduced food waste is transferred to the feed passage 420 and the outlet of the rotary shaft 400. It is injected into the second fermentation chamber 300 through the (430). At this time, since only the food waste fermented primarily by the through hole 511 is injected into the second fermentation chamber 300, the fermentation efficiency in the second fermentation chamber 300 is increased.

The food waste injected into the second fermentation chamber 300 is re-fermented while being stirred by the second stirring member 600 installed on the rotating shaft 400. The air supply unit 800 mixes the humid air of the first fermentation chamber 200 and the fresh air from the outside to air the second fermentation chamber 300 to activate microorganisms. At this time, the air supply unit 800 passes the mixed air through the heater 850 and the deodorant 860 to remove contaminants, and supplies air of temperature and humidity suitable for the activity of the microorganisms to the second fermentation chamber 300. . In addition, the high temperature mixed air supplied from the air supply unit 800 is provided to the second fermentation chamber 300 to maintain the temperature inside the second fermentation chamber 300 in a condition suitable for fermentation to increase the fermentation efficiency.

The food waste fermented inside the second fermentation chamber 300 is discharged through the sewage discharge valve 310. On the other hand, the sewage discharge valve 310 is composed of an electromagnetic valve, it is possible to open and close the sewage discharge valve 310 periodically. Fermented food waste is discharged when the sewage discharge valve 310 is opened, but air is injected by the air supply unit 800 into the closed second fermentation chamber 300 when the sewage discharge valve 310 is closed. As the pressure of the fermentation chamber 300 rises, the food waste inside the second fermentation chamber 300 flows back to the first fermentation chamber 200 through the transfer passage 420 of the rotary shaft 400. At this time, the refluxed food waste is discharged to the first fermentation chamber 200 through the through hole 511 of the first stirring member 500 to push out the bulky food waste that was blocking the through hole 511 to pass through the through hole ( Blocking of the 511 is prevented.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments thereof are possible.

Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

1 is a circuit diagram of a food waste processing apparatus according to an embodiment of the present invention,

FIG. 2 is a partial cross-sectional view of the first stirring member of the food waste treating apparatus of FIG. 1;

3 is a bottom perspective view of the first stirring member of the food waste treating apparatus of FIG. 1;

4 is an exploded perspective view of the lifting and lowering rotation part of the food waste treating apparatus of FIG. 1.

Claims (7)

A first fermentation chamber having an inlet through which food waste and microorganisms are introduced; A second fermentation chamber fermented in the first fermentation chamber to receive and re-ferment liquefied or refined food waste; A rotating shaft installed to be rotatable and descended through the first and second fermentation chambers; A first stirring member mounted on the rotating shaft inside the first fermentation chamber to rotate up and down inside the first fermentation chamber to stir the food waste; A second stirring member mounted on the rotating shaft inside the second fermentation chamber to stir the food waste contained in the second fermentation chamber; A lifting lowering rotating unit for rotating while lifting the rotating shaft; And an air supply unit installed in the second fermentation chamber to supply air. The method of claim 1, The first stirring member includes a plurality of through holes formed on the outer circumferential surface of the first fermentation chamber so that the food wastes liquefied or finely decomposed by fermentation can be introduced therein, and an inner space in which the food wastes introduced through the through holes are accommodated. Equipped, The rotating shaft is formed with a conveying passage to convey the food waste introduced into the inner space of the first stirring member downward, And a discharge port for discharging the food waste transferred through the transfer passage to the second fermentation chamber. 3. The method of claim 2, The first stirring member is A body having a plurality of through holes formed therein; A plurality of upper stirring blades formed concave in a rotational direction of the body to converge food waste in an upper portion of the body in a rotational center direction; And a plurality of lower stirring blades formed convexly in the rotational direction of the body to disperse the food waste in the direction of the edge of the body in the lower portion of the body. The method of claim 1 The air supply unit An external suction pipe for sucking fresh air outside; A fermentation chamber suction tube installed in the first fermentation chamber to suck air in the first fermentation chamber; A fan member connected to the external suction pipe and the fermentation chamber suction pipe to provide suction power; A mixing pipe connected to the external suction pipe and the fermentation chamber suction pipe to mix air sucked through the external suction and the fermentation chamber suction pipe; A heater that heats the mixing tube to increase the temperature of the air mixed by the mixing tube; An injection tube connected between the mixing tube and the second fermentation chamber to inject the hot mixed air formed by the mixing tube into the second fermentation chamber; And a deodorizing member mounted to the mixing pipe to absorb the malodorous component in the mixed air. The method of claim 1, The lifting and lowering rotation unit A boss installed on the rotating shaft, the boss having a guide groove formed in a closed track to be curved up and down on an outer circumferential surface thereof to raise and lower the rotating shaft; One side is inserted into the guide groove so that the boss can move up and down along the guide groove, the other side and the interference piece fixed to the frame; A slider coupled to the boss slidably with respect to the boss along the longitudinal direction of the rotation axis; And a drive unit for rotating the slider. The method of claim 1, A liquid suction pipe installed in the second fermentation chamber and sucking the liquefied food waste inside the second fermentation chamber; A liquid discharge tube installed in the first fermentation chamber and having a plurality of liquid discharge ports on an outer circumferential surface thereof to discharge the liquefied food waste sucked by the liquid suction tube; A liquid feeder connected to the liquid suction pipe and the liquid discharge pipe, the liquid feeder having a pump unit for sucking the liquefied food waste through the liquid suction pipe and discharging the liquefied food waste through the liquid discharge pipe; Food waste disposal device. The method of claim 6, The pump unit A pump housing provided with an inner space; A suction check valve installed at the liquid suction pipe and opened only in a direction in which food waste is injected into the pump housing; A discharge check valve installed at the liquid discharge pipe and open only in a direction in which food waste is discharged from the pump housing; A piston installed in the pump housing so as to vertically reciprocate and suction or discharge food waste into the pump housing; A piston rod installed under the piston to reciprocate the piston up and down; A rotating wheel rotatably installed at an end of the piston rod; An auxiliary rotating plate in contact with one surface of the rotating wheel and installed on the rotating shaft to move up and down;  And a restoring spring installed on the piston rod to restore the position of the piston to a predetermined position.

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