KR20150021710A - System for treating food waste - Google Patents

Abstract

The present invention relates to a food waste disposal system, and more particularly, to a disposer for disposing food waste discharged through a drain hole of a sink, a separator for separating the drain and the disposer from each other by a predetermined length, And a decomposition tank detachably coupled to the disposer and configured to decompose the food by cultivating the microorganisms in the food waste ground by the disposer. The food waste is crushed by the blade, And the food waste that has been finely ground in the disposer can be discharged in the decomposition tank in a decomposed state using microorganisms, thereby preventing environmental pollution caused by food waste.

Description

[0001] System for treating food waste [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a food garbage disposal system capable of pulverizing and decomposing food garbage and discharging the same.

Food waste contains a large amount of water. If it is handled like general waste, food waste may be decayed and odor may be generated, and food waste may contaminate soil, ground water, and the like. Therefore, in general, garbage is disposed separately from the general garbage by disposing a dedicated receptacle outdoors, which is inconvenient.

In order to solve the inconvenience at the time of collecting such food garbage, a disposer having a crushing member capable of crushing food waste is installed in a drain port of a sink, and the food waste finely crushed by the disposer is discharged through a sewer have.

However, the conventional disposer has a problem that the user may be injured by the pulverizing member of the bar disposer directly coupled to the drain of the sink. In addition, the food waste introduced into the sewer in a state of being broken by the disposer may be corrupted while flowing through the sewer, which may cause serious water pollution.

On the other hand, in order to prevent water contamination by the disposer, it is preferable to use a disposer for crushing food waste and a decomposition tank for decomposing the crushed food waste using microorganisms. In this regard, the current law on disposers obligates the disposer and the disassembly to be used together. Conventionally, there is a disadvantage that it is difficult to use the disposer and the disassembly substantially together because there is no disposer and disassembling unit that are structurally compatible with each other and can be easily separated and combined.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a food garbage disposal system capable of preventing a user from being injured by a disposer capable of grinding food garbage.

Further, it is an object of the present invention to provide a food garbage disposal system having an improved structure to reduce electric power required for grinding food garbage.

It is another object of the present invention to provide a food garbage disposal system capable of discharging food garbage crushed by a disposer in a decomposed state using microorganisms.

Further, it is an object of the present invention to provide a food garbage disposal system having an integral structure capable of being separated and coupled.

A food garbage disposal system according to a preferred exemplary embodiment of the present invention is a disposer for disposing food waste discharged through a drain port of a sink, a separator for separating the drain and the disposer from each other, And a decomposition tank detachably connected to the disposer to decompose the food by cultivating the microorganisms in the food waste ground by the disposer.

Preferably, the connecting pipe includes a bent portion bent so that the drain port of the sink and the disposer are not arranged on the same straight line.

Preferably, the disposer includes a housing, a disposer inlet provided at one side of the housing and connected to the connection pipe to introduce the food waste from the connection tube, a crushing unit for crushing the food garbage introduced into the housing, And a disposer outlet through which the pulverized food waste is discharged.

Preferably, the pulverizing unit includes: a rotating shaft rotatably installed in the housing; a spiral blade formed in a spiral shape along the outer peripheral surface of the rotating shaft to pressurize and transport the food waste; and a blade provided at an end of the spiral blade, And a screw provided therein.

Preferably, the housing includes a crushing plate provided along the inner surface thereof, the crushing plate having a plurality of alternately formed recesses and protrusions and protrusions and protrusions. When the rotation shaft is rotated, the food waste is centrifuged by the centrifugal force of the spiral wings, And is moved between the crushing plates to be crushed by the crushing action between the blade and the crushing plate.

Preferably, the rotary shaft has a conical shape in which the diameter gradually increases from the disposer inlet to the disposer outlet.

Preferably, the helical wing is characterized in that the spacing between adjacent threads from the disposer inlet to the disposer outlet is progressively narrowed.

Preferably, the disposer inlet is installed on the path, and further includes a metal sensing sensor for sensing the metal, and when the metal is sensed by the metal sensing sensor, the disposer stops driving.

Preferably, the blade is formed at a position spaced from the starting point of the helical blade by a predetermined distance.

Preferably, the disassembly tank is provided at one side of the disassembly tank, and is connected to the disposer outlet to store the disassembled tank inlet into which the pulverized food waste flows, the introduced food waste in a state of being pre-stored in water, A decomposition chamber in which the food waste supplied and stored is decomposed, and a decomposition tank discharge port through which the decomposed food waste is discharged.

Preferably, the disposer outlet has an engaging projection protruding along the periphery thereof. The disassembling vessel inlet has an engaging groove formed around the periphery of the disposing groove so that the engaging protrusion can be inserted, The coupling protrusion is rotated so that the coupling protrusion and the coupling groove are staggered from each other, and the coupling protrusion is rotated so that the coupling protrusion and the coupling groove are arranged on the same line, and then the coupling protrusion is withdrawn from the coupling groove Thereby separating the disposer and the decomposition tank.

Preferably, the disassembly vessel includes a plurality of diaphragms having a squeeze hole through which the food waste decomposed to a predetermined size can selectively pass, a partition for partitioning the decomposing chamber into a plurality of decomposition spaces, and at least one of the plurality of decomposition spaces And a microorganism supply unit for supplying microorganisms to induce decomposition of the food waste stored in the decomposition chamber.

Preferably, the size of the squeeze hole provided in each of the diaphragms is characterized in that the size gradually decreases from the diaphragm adjacent to the dismount tank to the diaphragm outlet adjacent to the diaphragm outlet.

Preferably, the decomposition tank is further provided with a first pump provided at one side of the decomposition chamber and forming a swirling flow in the water so that the food waste settled in the water is transferred.

Preferably, the first pump is characterized in that the flow of water forming the swirling flow is installed in the lower part of the decomposition chamber so as to face the decomposition tank inflow port at the decomposition tank discharge port and at the decomposition tank inflow port to the decomposition tank discharge port in the upper part of the decomposition chamber .

Preferably, the decomposition tank further comprises a guide pipe for guiding the water stored in the decomposition chamber to the crushing unit to guide the discharge of the food waste remaining in the crushing unit.

Preferably, the guide pipe is provided on the guide path and includes a second pump for introducing water stored in the decomposition chamber into the guide pipe.

The food garbage disposal system according to the present invention has the following effects.

First, it is possible to prevent the user from being injured by the blade for crushing food waste.

Second, since the connector, the disposer, and the disassembly unit are structurally compatible with each other, it is possible to realize a food processing system having an integrated structure by combining a connector, a disposer, and a disassembly unit, The pipes, disposer, and disassembler can be disassembled and replaced or repaired, respectively.

Third, by cutting the food waste using a blade and introducing a crushing structure using a crushing plate, it is possible to reduce the amount of electric power required for crushing food waste, and to reduce the noise and vibration generated when the food waste is crushed .

Fourth, the food waste which has been finely ground in the disposer can be discharged in the decomposition tank by using microorganisms in the decomposition tank, thereby preventing environmental pollution caused by food waste.

Fifth, the decomposition chamber of the decomposition tank is divided into a plurality of decomposition spaces sequentially decomposing through the diaphragm, so that the food waste can be discharged in a fully decomposed state, thereby preventing environmental pollution caused by food waste

1 is a conceptual diagram for schematically explaining a food garbage disposal system according to a preferred exemplary embodiment of the present invention;
Fig. 2 is a view for explaining the connection pipe of Fig. 1; Fig.
Figure 3 is an exploded perspective view of the disposer of Figure 1;
Fig. 4 is a longitudinal sectional view of the disposer of Fig. 3; Fig.
Figure 5 is a partial enlarged view of the grinding unit of Figure 3;
Figure 6 is a cross-sectional view of the housing of Figure 3;
7 is a view for explaining a process of disposing and disassembling the food waste and disassembling the disposer of FIG. 1;
8 and 9 are views for explaining a separation and disassembling method of a disposer and disassemblage.
10 is a view for explaining a guide tube of a food processing system according to another preferred embodiment of the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention. Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

In the drawings, the size of each element or a specific part constituting the element is exaggerated, omitted or schematically shown for convenience and clarity of description. Therefore, the size of each component does not entirely reflect the actual size. In the following description, it is to be understood that the detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a schematic view for explaining a garbage disposal system according to a preferred embodiment of the present invention.

1, a disposer 20 for crushing food waste discharged through a drain hole 12 of a sink 10 according to a preferred exemplary embodiment of the present invention, a drain hole 12 and a disposer 20, A connection pipe 30 detachably coupled between the discharge port 12 and the disposer 20 so as to be spaced apart from the discharge port 12 by a predetermined length, And a decomposition tank (40) for culturing the microorganisms in the food waste pulverized by the food waste (20) to decompose the food.

The disposer 20 is a member for finely crushing the food waste discharged together with the water through the drain hole 12 of the sink 10. In the present specification, the sink 10 means a kitchen utensil which can be used to trim or wash the material to be cooked.

The connection pipe 30 connects the disposer 20 and the drain port 12 of the sink 10 to connect the water discharged through the drain port 12 of the sink 10 and the food waste contained in the water to the disposer 20 . The connector 30 can separate the discharge port 12 of the sink 10 and the disposer 20 by a predetermined length so that the user's hand can not be brought into contact with the disposer 20. [

The decomposing tank 40 is a member that receives the food pulverized from the disposer 20 and cultivates microorganisms in the pulverized food waste to decompose the food waste. The pulverized food waste is decomposed and discharged using microorganisms, And the like can be protected.

Fig. 2 is a view for explaining the connector 30 of Fig. 1. Fig.

Since a sharp blade or a blade is provided inside the general disposer to crush food waste, there is a fear that the user's hand may come in contact with the blades or blades of the disposer through the drain port 12 of the sink 10, have.

The connection pipe 30 may include a bent portion bent so that the drain port 12 of the sink 10 and the disposer 20 are not arranged on the same straight line.

2, the connection pipe 30 is provided with two bent portions so that the drain port 12 of the sink 10 and the disposer 20 are not disposed in the same straight line. Therefore, the user's hand can not be brought into contact with the disposer 20, and thus the user can be prevented from being injured by the disposer 20. [

The connection relationship between the drain hole 12 of the sink 10 and the disposer 20 and the connection pipe 30 is not particularly limited. For example, the drain hole 12 of the sink 10 is detachably fitted to one end of the connection pipe 30, and the disposer inlet port 53 is detachably fitted to the other end of the connection pipe 30, (30) can be installed between the drain port (12) of the sink (10) and the disposer (20). To this end, a protrusion that can be engaged with the other end of the coupling tube 30 may be provided in the disposer inlet 53.

As such, the connector 30 and the disposer 20 can be structurally compatible with each other so that they can be separated from each other. Therefore, the connection pipe 30 and the disposer 20 are integrally coupled to each other in the sink 10, and the water discharged from the drain 12 of the sink 10 through the connection pipe 30 The food waste can be delivered to the disposer 20. When the connection tube 30 and the disposer 20 are required to be replaced or repaired, the connection tube 30 and the disposer 20 can be separated from each other and easily replaced or repaired.

On the other hand, o-rings (not shown) are provided at both ends of the connection pipe 30 to prevent the food waste and water from flowing out.

Fig. 3 is an exploded perspective view of the disposer of Fig. 1, and Fig. 4 is a longitudinal sectional view of the housing of Fig. 3. Fig.

3 and 4, the disposer 20 is provided at one side of the housing 50 and the housing 50. The disposer 20 is connected to the connection pipe 30 and is connected to the disposer 20 through which the food waste flows from the connection pipe 30. [ And may include an inlet 53, a crushing unit 60 for crushing the introduced food waste, and a disposer outlet 54 provided on the other side of the housing 50 for discharging crushed food waste.

The housing 50 is a member forming the body of the disposer 20, and may have a cylindrical shape with an open top surface. The housing 50 includes a crush plate 51 provided on the inner side surface thereof and a shaft hole 52 through which the lower end of the crush plate 51 is rotatably supported by the crushing unit 60 can do. The details of the crush plate 51 will be described later.

The disposer inlet port 53 is connected to the other end of the connection pipe 30 to provide a passage through which the food waste flows from the connection pipe 30. The formation position of the disposer inlet 53 is not particularly limited, and the open top surface of the disposer 20 can function as the disposer inlet 53, as shown in Fig.

In addition, the disposer inlet port 53 may include a metal sensor for detecting the metal, which is installed on the path thereof, and the driving of the disposer 20 may be stopped when a metal is detected by the metal sensor .

The kind of the metal detection sensor that can be installed in the disposer inlet 53 is not particularly limited, and for example, a metal detection sensor made of a coil for generating a magnetic field may be mounted.

By installing the metal detection sensor, it is possible to prevent a hard metal such as a laced or other hard metal from flowing into the inside of the disposer 20 to prevent the disposer 20 from being damaged. The metal detection sensor may be installed on the path of the connection pipe 30 instead of the disposer inlet 53. [

The crushing unit 60 is a member for crushing the food waste introduced through the disposer inlet 53. The crushing unit 60 includes a rotating shaft 61 rotatably installed in the housing 50 and a helical blade 62 formed in a spiral shape along the outer circumferential surface of the rotating shaft 61 to pressurize and transport the food waste, A screw provided at an end of the blade 62 and having a blade 63 for crushing food waste, and the like.

The pulverizing unit 60 is a member for pulverizing the food waste introduced into the disposer 20 and is rotatably installed inside the housing 50.

The lower end of the rotary shaft 61 is inserted into the shaft hole 52 of the housing 50 so as to be rotatably supported and includes a bearing 64 for smooth rotation of the rotary shaft 61, And an O-ring 65 for preventing leakage. The lower end of the rotating shaft 61, which is exposed to the outside of the housing 50 through the shaft hole 52, can be coupled with a motor (not shown) that provides driving force.

The type of motor that can be coupled to the rotary shaft 61 is not particularly limited. For example, an induction motor motor that can be driven at a low speed can be coupled to the rotary shaft 61, and a reduction gear 62 is interposed between the motor and the rotary shaft 61 so that the helical blade 62 coupled with the rotary shaft 61 can have a large force. (Not shown) may be installed.

In order to stably rotate the rotary shaft 61, the upper end of the rotary shaft 61 must be rotatably supported in the same manner as the lower end of the rotary shaft 61 rotatably supported by the shaft hole 51. Accordingly, the upper surface of the housing 50, that is, the disposer inlet 53, may be provided with a support lid 55 capable of rotatably supporting the rotary shaft 61. [ The support lid 55 may include a rotation support 56 formed at the center of which a shaft groove 57 capable of rotatably supporting the upper end of the rotation shaft 61 is provided. A bearing 66 for smooth rotation of the rotary shaft 61 can be mounted between the rotary shaft 61 and the shaft groove 57.

The screw is formed along the outer circumferential surface of the rotary shaft 61 and functions to crush the food waste while transporting the food waste. The screw may include a spiral blade 62 and a blade 63.

The spiral blade 62 is formed in a spiral shape along the outer periphery of the rotary shaft 61 and can push the food waste in the axial direction of the rotary shaft 61 for transfer. The blade 63 is provided at the end of the helical blade 62 and can crush the food waste conveyed under pressure by the helical blade 62. The details of the crushing unit 60 will be described later.

The disposer discharge port 54 is connected to a disassembly tank inflow port 41 to be described later to provide a path through which the food waste disintegrated by the crushing unit 60 is discharged. The position where the disposer outlet 54 is formed is not particularly limited and may be formed in the tangential direction of the rotating shaft 61, for example.

Fig. 5 is a perspective view of the crushing unit for explaining the crushing unit of Fig. 3, and Fig. 6 is a cross-sectional view of the disposer for explaining the crushing plate of Fig.

Food waste should be crushed as finely as possible in order to prevent food waste from being contaminated by food waste. Accordingly, the disposer 20 may have the following structure in order to crush food garbage as finely as possible.

For example, the rotary shaft 61 may have a conical shape in which the diameter? Gradually increases from the disposer inlet 53 to the disposer outlet 54.

As shown in FIG. 5, the rotary shaft 61 has a structure in which the diameter? Gradually increases from the upper portion to the lower portion. Accordingly, the food garbage can be conveyed in a compressed state as the pressure increases from the upper portion of the rotary shaft 61 to the lower portion, that is, from the disposer inlet 53 to the disposer outlet 54.

For example, the spiral wing 62 can gradually narrow the spacing? Between adjacent threads from the disposer inlet 53 to the disposer outlet 54.

5, the spacing? Between adjacent threads of the helical wings 62 decreases from the upper portion of the rotary shaft 61 to the lower portion, that is, from the disposer inlet 53 to the disposer outlet 54 And gradually becomes smaller. Accordingly, the food garbage can be conveyed in a compressed state as the pressure increases from the upper portion of the rotary shaft 61 to the lower portion, that is, from the disposer inlet 53 to the disposer outlet 54.

For example, the housing 50 includes a crush plate 51, which is provided along an inner surface of the crush plate 51 and includes a plurality of alternately formed recesses 51a and recesses 51b, The food waste is moved between the blade 63 and the crushing plate 51 by the centrifugal force of the helical blade 62 and can be crushed by the crushing action between the blade 63 and the crushing plate 51 .

6, uneven grooves 51a and uneven protrusions 51b are alternately formed on the inner surface of the housing 50 so that a plurality of uneven grooves 51a and uneven protrusions 51b are formed on the inner side surface of the food garbage A crushing plate 51 for crushing can be formed. The concavo-convex grooves 51a of the crush plate 51 preferably have a semicircular cross-sectional shape, but are not limited thereto, and may have a triangular or quadrangular cross-sectional shape, for example.

Since the crush plate 51 is provided on the inner surface of the housing 50 as described above, the crush plate 51 can be disposed facing the blade 63 provided at the end of the helical blade 62. Therefore, when the rotating shaft 61 is rotated, the food waste is moved between the blade 63 and the crushing plate 51 by the centrifugal force of the helical blades 62, and the crushing action between the blade 63 and the crushing plate 51 To be finely ground.

More specifically, the blade 63 can perform a function of cutting food garbage to a small size, and the crush plate 51 can perform a function of crushing food similar to a millstone. That is, the disposer 20 can crush food waste while crushing it. Accordingly, the food waste can be finely pulverized and the noise and vibration generated when the food waste is pulverized can be reduced, compared to a case where the food waste is simply cut using the blade 63 alone. In addition, it is possible to reduce the electric power cost by reducing the amount of electricity required for grinding food garbage.

Even if the connection pipe 30 is provided between the drain hole 12 of the sink 10 and the disposer 20, There is a risk of being injured in contact with the contact portion 63. Therefore, in order to reliably prevent the user's hand from being injured by the blade 63 of the disposer 20, the blade 63 may be formed at a position spaced from the starting point of the spiral blade by a predetermined distance.

5, the blade 63 may be formed at a starting point of the helical blade 62, that is, a position spaced from the top of the helical blade 62 by a predetermined distance. Therefore, even if the user's hand enters the inside of the disposer 20, the blade 63 is not formed at the uppermost end of the helical blade 62, It is possible to prevent injuries from being caused.

FIG. 7 is a view for explaining the disassembly of FIG. 1; FIG.

The decomposition tank 40 is a device for decomposing the food waste that has been crushed by the disposer 20 and using the microorganisms. The disassembly tank 40 is provided at one side thereof with a disassembly tank inlet 41 connected to the disposer discharge port 54 to receive pulverized food waste, A decomposition chamber 42 where the microorganisms are supplied to the water to decompose the stored food waste, and a decomposition tank discharge port 44 through which the decomposed food waste is discharged.

The decomposition tank inlet 41 is provided on one side of the decomposition tank 40 and connected to the disposer outlet 54 so that the food waste ground by the disposer 20 is introduced into the decomposition tank 40 Provide a pathway. The decomposition tank inlet 41 may be detachably coupled to the disposer discharge port 54, and a detailed description thereof will be given later.

The decomposition chamber 42 is a space in which the food waste introduced into the decomposition tank 40 is decomposed and the food waste introduced into the decomposition chamber 42 is stored in the decomposition chamber 42 in a state of being pre- do.

The decomposition tank 40 may be configured to decompose the food waste stored in the decomposition chamber 42 by supplying microorganisms to the decomposition chamber 42. [ And a microorganism supply unit 43 for introducing microorganisms. The kind of the microorganism supplied by the microorganism feeding part 43 is not particularly limited, and microorganisms generally used for the degradation of food can be used.

The microorganism supply unit 43 may be driven by electricity to supply microorganisms, or may be automatically driven by internal pressure without using electricity, such as a ring gel, to supply microorganisms. In addition, the microorganism supply unit 43 preferably supplies microorganisms in a state of being contained in water, but is not limited thereto.

Thus, microbes are supplied to the decomposition chamber 42 by the microorganism supply unit 43, so that the food waste stored in the decomposition chamber 42 can be decomposed using microorganisms.

The decomposition tank discharge unit 44 is provided on the other side of the decomposition tank and is connected to the decomposition chamber 42 to provide a passage through which the food waste decomposed in the decomposition chamber 42 can be discharged to the outside. That is, the decomposition tank discharge unit 44 is connected to the sewerage, and can discharge the garbage having been crushed and disassembled to the sewerage system.

On the other hand, since the decomposition of food waste using microorganisms takes a long time, the food waste may be discharged to the outside without sufficient decomposition of the food waste.

In order to solve this problem, the decomposition tank 40 is provided with a squeeze hole 46 through which food waste decomposed to a predetermined size can selectively pass therethrough, and a plurality of decomposition spaces 42 Of the diaphragm (45). Preferably, the size of the squeeze hole 46 provided in each of the diaphragms 45 is gradually smaller toward the diverging vat outlet 44 and the adjacent diaphragm 45 by the diverging plate 45 adjacent to the decomposition tank inlet 41 Can be.

The first to third partition plates 45a to 45c for partitioning the decomposition chamber 42 are sequentially disposed along the longitudinal direction of the decomposition chamber 42. As a result, Can be partitioned into the first to fourth decomposition spaces 42a to 42d, respectively. 7, the three partition plates 45 of the decomposition chamber 42 are provided to partition the decomposition chamber 42 into four decomposition spaces in total, but the present invention is not limited thereto.

The first to third diaphragms 45a to 45c are provided with a filter hole 46 through which food waste can selectively pass. The selective passage of food waste means that only food waste that has been slightly degraded by microorganisms can pass through, and food waste that has not yet been degraded can not pass through.

The diameter of the squeeze hole 46 provided in the first to third diaphragms 45a to 45c is largest in the diameter of the squeeze hole 46 provided in the first diaphragm 45a closest to the disassembly tank inflow port 41, The diameter of the squeeze hole 46 provided in the third diaphragm 45c closest to the squeezing outlet 44 is the smallest. Then, the food waste can be sequentially moved from the first decomposition space 42a to the fourth decomposition space 42d through the squeeze holes 46 provided in the respective connection plates depending on the degree of decomposition thereof. Therefore, it is possible to prevent the food waste not sufficiently decomposed from being discharged to the outside through the decomposition tank discharge port 44.

On the other hand, since the food waste is stored in a state of being precipitated in the water stored in the decomposition chamber 42, even if the decomposition is completed by the microorganisms, the food waste may not be discharged to the outside and may accumulate in a continuously precipitated state.

In order to solve this problem, a first pump 47a may be provided at one side of the decomposition chamber 42 and forms a swirling flow A in the water so that the food waste settled in the water is transferred. The first pump 47a is configured such that the flow of water forming the swirling flow A is directed from the decomposition tank discharge port 44 to the decomposition tank inlet port 410 at the lower portion of the decomposition chamber 42, It may be installed at the decomposition tank inlet port 41 to face the decomposition tank discharge port 44. [

7, the bottom surface of the decomposition chamber 42 is provided with a bypass pipe 47 for communicating the fourth decomposition space 42d with the first decomposition space 42a, A first pump 47a capable of pumping the water in the fourth decomposition space 42d into the first decomposition space 42a is provided. Then, in the lower part of the decomposition chamber 42, water flows from the first decomposition space 42a, that is, the decomposition tank discharge port 44 to the decomposition tank inflow port 41 in the fourth decomposition space 42d, The swirling flow A is generated from the first decomposition space 42a to the fourth decomposition space 42d, that is, from the decomposition tank inflow port 41 to the decomposition tank discharge port 44 at the upper portion of the decomposition tank 40.

When the water flows from the first decomposition space 42a to the fourth decomposition space 42d in the upper portion of the decomposition chamber 42, the flow of water is blocked by the first to third partition plates 45a to 45c . Some of the water can not be moved to the other decomposition space through the filter hole 46 of the diaphragm 45 and moves to the bottom surface of the decomposition space. That is, the swirling flow A in the time direction is formed in each decomposition space.

Thus, the first pump 47a forms a clockwise swirling flow A in each of the decomposition spaces. Therefore, the food waste settled on the bottom surface of each decomposition space is moved by the swirling flow A by the swirling flow A in the time direction, and is discharged from the first decomposition space 42a to the fourth decomposition space 42d It can be transferred sequentially.

Figs. 8 and 9 are views for explaining a separation and disassembly method of a disposer and a disassembly tank.

8, the disposer discharge port 54 has an engaging projection 54a protruding from the disposer discharge port 54. The disassembly tank inlet 41 is formed such that the engaging projection 54a can be inserted along the periphery thereof As shown in Fig.

The engaging protrusions 54a may be formed at predetermined intervals along the periphery of the disposer outlet 54. Correspondingly, the engaging recesses 41a are formed at positions corresponding to the positions of the engaging protrusions 54a along the periphery of the disassembling tank inflow opening 41 And may be formed to be insertable. However, the present invention is not limited thereto. The disposer 54 may be provided with a coupling groove 41a, and the disassembly tank inlet 41 may be provided with a coupling projection 54a.

9, after the engaging projection 54a is inserted into the engaging groove 41a, the engaging projection 54a is rotated so that the engaging projection 54a and the engaging groove 41a are staggered, The separator 20 and the decomposition tank 40 can be combined. On the contrary, after the engaging projection 54a is rotated so that the engaging projection 54a is arranged on the same line as the engaging recess 41a, the engaging projection 54a is drawn out from the engaging recess 41a, So that the bath 40 can be separated.

Thus, the disposer 20 and the disassembly tank 40 can be structurally compatible with each other so that they can be separated from each other. Therefore, the disposer 20 and the disassembly tank 40 are integrally coupled to each other in the inside of the countertop 10, and the food waste disintegrated in the disposer 20 is transferred to the disassembling tank 40, Food waste can be decomposed using microorganisms. Further, when it is necessary to repair the disposer 20 and the disassembling tank 40, the disposer 20 and the disassembling tank 40 can be separated from each other and can easily be replaced or repaired.

Hereinafter, a process of pulverizing and disintegrating food using a food waste disposal system according to a preferred exemplary embodiment of the present invention will be described with reference to the drawings.

First, the drain hole 12 of the sink 10 and the disposer 20 are connected to each other by using the connecting pipe 30 and the disposer 20 and the disposer 20 are connected to each other by using the coupling protrusion 54a and the coupling groove 41a. And the decomposition tank 40 are coupled to each other.

Next, water and food waste are discharged through the drain port (12) of the sink (10).

The food waste is sequentially passed through the connection pipe 30 and the disposer inlet port 53 to the water and the water drained through the drain port 12 of the sink 10 to enter the crushing unit 60 of the disposer 20 do.

Thereafter, the crushing unit 60 is operated to crush the food waste entering the crushing unit 60 finely.

The food garbage that has entered the crushing unit 60 is pressed and conveyed by the screw spiral 62 of the screw and the blade 63 provided at the end of the spiral blade 62 and the crushing plate 51).

Next, the decomposition tank 40 is operated to decompose the food waste introduced into the decomposition chamber 42 by using microorganisms.

Microorganisms are supplied to the decomposition chamber 42 by using the microorganism supply section 43 and the first pump 47a is operated to form a clockwise swirling flow A in the decomposition spaces provided in the decomposition chamber 42 So that the food waste introduced into the decomposition chamber 42 can be decomposed using microorganisms.

Thereafter, the food waste disassembled in the decomposition space is discharged to the sewage pipe through the decomposition tank discharge port 44 provided at one side of the decomposition chamber 42.

Food waste, which has been decomposed by microorganisms, can be decomposed continuously in the process of being transported through sewage pipes. Therefore, food waste may be decomposed only to a proper level.

10 is a view for explaining a guide tube in a food garbage disposal system according to another preferred embodiment of the present invention. The same reference numerals as those in FIGS. 1 to 9 denote the same components, and a detailed description thereof will be omitted.

The food waste treatment system according to another preferred embodiment of the present invention is characterized in that water stored in the decomposition tank 40 is supplied to the disposer 40 as described below in comparison with the food waste disposal system according to the preferred exemplary embodiment of the present invention, (48) that circulates the refrigerant to the refrigerating chamber (20).

10, the decomposing tank 40 includes a guide pipe 48 for guiding the water stored in the decomposition chamber 42 to the crushing unit 60 and guiding the discharge of food waste remaining in the crushing unit 60 . The guide tube 48 is preferably provided on the guide path and may include a second pump 48a for introducing water stored in the decomposition chamber 42 into the guide tube 48. [

The food waste that has flowed into the pulverizing unit 60 of the disposer 20 and finely crushed is disassembled together with the food waste through the disposer outlet 54 by the water introduced into the pulverizing unit 60 of the disposer 20 Can be introduced into the bath 40. However, the fine pulverized food waste may not be smoothly discharged between the structures inside the disposer 20.

Therefore, by providing the guide pipe 48 for communicating the decomposition chamber 42 and the crushing unit 60 with each other and providing the second pump 48a on the path of the guide pipe 48, The water stored in the decomposition chamber 42 of the disposer 20 can be guided to the crushing unit 60 to discharge the food waste remaining in the disposer 20 to the outside.

More specifically, the water in the decomposition tank 40 which has entered the inside of the disposer 20 by the guide pipe 48 discharges the food waste remaining in the disposer 20 due to the flow, The microorganisms contained in the water in the bath 40 can decompose and discharge the food waste remaining in the disposer 20. [

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not to be limited to the details thereof and that various changes and modifications will be apparent to those skilled in the art. And various modifications and variations are possible within the scope of the appended claims.

1: food processing system 10: sink
20: Disposer 30: Connector
40: decomposition tank 41: decomposition tank inlet
42: decomposition chamber 43: microorganism supply section
44: disassembly outlet 45: diaphragm
46: Opening hole 50: Housing
51: Crushing plate 53: Disposer inlet
55: Disposer outlet 60: Crushing unit
61: rotating shaft 62: helical wing
63: The blade

Claims (17)

A disposer for crushing food waste discharged through a drain port of a sink;
A connection pipe detachably coupled between the drain hole and the disposer, the connection pipe connecting the drain hole and the disposer so as to be spaced apart from each other by a predetermined length; And
And a decomposition tank detachably coupled to the disposer and configured to decompose the food by cultivating microorganisms in the food waste ground by the disposer. The method according to claim 1,
The connection pipe includes:
And a bent portion bent so that the drain hole of the sink and the disposer are not arranged in the same straight line. The method according to claim 1,
Wherein the disposer comprises:
housing;
A disposer inlet provided at one side of the housing and connected to the connection pipe to allow the food waste to flow from the connection pipe;
A grinding unit for grinding the introduced food wastes; And
And a disposer outlet provided on the other side of the housing for discharging the pulverized food waste. The method of claim 3,
Wherein the crushing unit comprises:
A rotating shaft rotatably installed in the housing; And
A spiral blade formed in a spiral shape along the outer circumferential surface of the rotary shaft for pressing and transporting the food garbage and a screw provided at an end of the spiral blade and for blasting the food garbage, system. 5. The method of claim 4,
The housing includes:
And a crushing plate provided along the inner side surface thereof, the crushing plate having a plurality of alternately formed recesses and protrusions and protrusions and protrusions,
Wherein the food waste is moved between the blades and the crushing plate by the centrifugal force of the helical blades so that the food waste is crushed by the crushing action between the blades and the crushing plate. 5. The method of claim 4,
The rotation shaft
And a conical shape in which the diameter gradually increases from the disposer inlet to the disposer outlet. 5. The method of claim 4,
The spiral blade
Wherein a distance between the adjacent disposer is gradually narrowed from the disposer inlet to the disposer outlet. The method of claim 3,
Wherein the disposer inlet comprises:
And a metal detection sensor installed on the path for sensing the metal,
And the driving of the disposer is stopped when metal is detected by the metal detection sensor. 5. The method of claim 4,
The blade
Wherein the spiral wing is formed at a position spaced from the starting point of the spiral wing by a predetermined distance. The method of claim 3,
Preferably,
A disassembly tank inlet connected to the disposer discharge port and through which the pulverized food waste flows;
A decomposition chamber in which the introduced food waste is stored in a state of being pre-stored in water, and the microorganisms are supplied to the water to decompose the stored food waste; And
And a decomposition tank discharge port through which the food waste decomposed is discharged. 11. The method of claim 10,
The disposer outlet
And an engaging projection protruding along the periphery thereof,
The disassembly tank inlet may include,
And an engaging groove formed in the circumferential direction so that the engaging projection is insertable,
The disassembly and the decomposing jig are engaged by rotating the engaging projection so that the engaging projection and the engaging groove are staggered from each other after the engaging projection is inserted into the engaging groove,
Wherein the detaching means separates the disposer from the disassembly vessel by rotating the engaging projection in such a manner that the engaging projection and the engaging groove are arranged on the same line and then drawing the engaging projection from the engaging groove. 11. The method of claim 10,
Preferably,
A plurality of diaphragms having a filter hole through which the food waste decomposed to a predetermined size can selectively pass, and partitioning the decomposition chamber into a plurality of decomposition spaces; And
And a microorganism supply unit for supplying microorganisms to at least one of the plurality of decomposition spaces to induce decomposition of the food waste stored in the decomposition chamber. 13. The method of claim 12,
The size of the filter hole provided in each of the diaphragms is,
Wherein the decomposition tank is gradually reduced from the partition adjacent to the decomposition tank inlet to the partition adjacent to the decomposition tank outlet. 11. The method of claim 10,
Preferably,
Further comprising a first pump provided at one side of the decomposition chamber to form a swirling flow in the water so that the food waste settled in the water is transferred. 15. The method of claim 14,
The first pump is arranged so that the flow of water forming a swirling flow is directed from the decomposition tank outlet to the decomposition tank inlet from the decomposition tank inlet and from the decomposition tank inlet to the decomposition tank outlet from the upper portion of the decomposition chamber Wherein the food garbage disposal system comprises: 11. The method of claim 10,
Preferably,
Further comprising a guide pipe for guiding the water stored in the decomposition chamber to the crushing unit to guide the discharge of the food waste remaining in the crushing unit. 17. The method of claim 16,
The guide tube
And a second pump provided on the guide path for introducing water stored in the decomposition chamber into the guide pipe.

Images