KR20200061174A - Food waste disposal system and disposal method - Google Patents

Abstract

The present invention relates to a food waste disposal system and a food waste disposal method. According to the present invention, the food waste disposal system comprises: a crushing unit having an inlet, a crushing plate, and a first outlet; a recirculation unit having a screening net, a second outlet, and a collecting pipe; and a storage unit having a storage space, an ultrasonic generator, and a third outlet. According to the present invention, food waste can be finely crushed to keep a sewer pipe clean.

Description

Food waste disposal system and disposal method

The present invention relates to a food waste treatment system and a treatment method, and more specifically, to a disposer that recycles and crushes food waste to be finely ground.

In modern times, the amount of food waste emitted from each household is increasing. Therefore, in each household, a disposer, a food waste grinder, is being used as a technique for conveniently disposing of food waste while simultaneously reducing the cost of disposing of the food waste.

However, the general disposer is not necessary to finely grind food waste, and thus, there is a problem that the sewage pipe is clogged or backflowed, and thus it is a necessary situation described for fine grinding.

With the conventional disposer-related technology, as shown in Korean Registered Patent 2015 No. 1555946 (announcement of October 06, 2015), the food waste that is installed in the sink drainage and flows through the drainage is rotated by an upper rotating crushing plate. Secondary pulverization, the primary crushed food waste is secondaryly crushed by the lower pulverization unit, and has a relatively high crushing rate compared to single crushing. It is difficult to maintain the durability in the rough rotation of the.

As another disposer-related technology, as described in Korean Patent Registration No. 1004006 in 2010 (announcement of December 31, 2010), a technology has been developed to disassemble and dissolve some crushed food waste through a disposer. , It takes a long time to decompose, and the efficiency of fermentation by microorganisms is low due to food waste and moisture being continuously supplied, and there are problems such as a complicated configuration having a plurality of decomposition tanks.

KR 10-1555946 B1 (2015.10.06.) KR 10-1004005 B1 (2010.12.31.)

In the present invention, as a new technology was devised to solve the above-mentioned problems of the prior art, the present invention is that food waste discharged from an existing disposer cannot be finely crushed and deposited in a sewer pipe, or food waste discharged through a sewer. It is an object of the invention to provide a food waste disposal system that solves problems such as environmental pollution due to inadequate decomposition.

In addition, although not separately described, other objects within a scope that can be inferred in consideration of specific contents and claims for carrying out the following invention are also included in the overall subject matter of the present invention.

As a specific means for solving the problems of the present invention, in the present invention, a food inlet and a water inlet from a sink, a crushing plate for rotating and crushing the food waste, and a primary outlet through which the food waste is crushed are discharged. A crushing section having a crushing section, a filtering net having a sorting hole formed to pass only food wastes having a size smaller than 1 to 3 mm among food wastes discharged from the primary discharge port of the crushing section, and a secondary discharge port through which food waste passing through the filtering net is discharged, The food waste introduced from the recycling pipe and the secondary outlet having a re-entry port in communication with one side of the crushing unit so that the food waste that has not passed through the sorting hole is introduced and the food waste that has passed through the collection pipe is re-entered into the crushing unit. It is characterized in that it includes a storage space, an ultrasonic generator that allows food waste collected in the storage space to be dissolved in water, and a tertiary outlet with a valve to discharge food waste to the outside.

In order to push the food waste stuck in the sorting hole in the reverse direction without passing through the sorting hole of the filtering net, the speed of the backwashing nozzle formed in the secondary outlet and the food waste discharged from the primary outlet is increased to quickly introduce food into the collection pipe. The venturi part formed in the primary outlet so that the re-entry time of food waste does not flow back, and the sensor formed in the secondary outlet so as to measure the amount of food waste passing through the filtering network, and the grinding plate is rotated according to the measured amount of the sensor. It may further include a control unit for controlling the rotation speed of the driving device, the injection amount of the backwash nozzle, the power of the ultrasonic generator.

The filter network may be formed in a conical shape with a wide inlet and a narrow outlet, or may be formed in an arc shape or in a diagonal shape to reduce the resistance from the primary outlet to the recovery pipe.

In constructing the food waste treatment system, the food waste and water input from the sink to the input port, the grinding step in which the input food waste is crushed by a grinding plate, and the crushed food waste is discharged through the primary outlet. The first discharge step, the sorting step in which food waste is sorted into the sorting hole of the filtering network, the recycling step in which food waste larger than the sorting hole is re-entered into the crushing section through the recycling section, and the small food waste that has passed through the sorting hole are secondary. A secondary discharge step discharged through the discharge port, a storage step in which food waste discharged through the secondary discharge port flows into the storage space, and an ultrasonic dissolution step in which food waste stored in the storage space is dissolved in water by an ultrasonic generator, It is characterized in that the food waste is processed through a third discharge step in which the dissolved food waste is discharged through the third discharge port.

According to a specific means for solving the above-described problem, only food wastes that are not fine until the food wastes are finely crushed can be repeatedly crushed and finely crushed food wastes, dissolved in water through ultrasonic waves and discharged It is possible to maintain a clean sewage pipe to prevent clogging of the sewage pipe due to the complete dissolution of the liquid in which food waste is dissolved in the sewage pipe.

In addition, the particle size of food waste discharged to the river is fine, so the area where microorganisms can stick to food waste is much wider, so the process of fermentation and decomposition proceeds much faster, preventing environmental pollution, etc. It is a great invention.

1 is an exemplary view showing a sink to which the present invention is applied
Figure 2 is a cross-sectional view showing an example of the present invention
Figure 3 is a cross-sectional view showing the venturi portion of the present invention
Figure 4 is a cross-sectional view and a three-dimensional view showing an example of the filter network of the present invention
Figure 5 is a cross-sectional view and a three-dimensional view showing another example of the filter network of the present invention
Figure 6 is a cross-sectional view and a three-dimensional view showing another example of the filter network of the present invention
7 is a flow chart showing a food waste treatment method of the present invention

The present invention is intended to provide a food waste treatment system and a processing method, which will be described in more detail with the drawings below, and the accompanying drawings are exemplary days for easily explaining the content and scope of the technical spirit of the present invention. However, the present invention is not limited thereto, and the terms used are only intended to specifically describe the embodiment and should not be interpreted as being limited to the terms.

The food waste treatment system 1 of the present invention is the crushing part 2 is coupled to the lower portion of the sink A as shown in FIGS. 1 to 2, and the recirculation part ( 3) is coupled, the discharge unit 4 is configured to be coupled to the other side of the recirculation unit (3).

The food waste treatment system 1 will be described in detail through the food waste treatment method as shown in FIG. 7.

1. Input phase (S1)

When food waste and water to be treated with the drain of the sink (A) are flowed together, food waste and water are introduced into the input port (21) of the grinding unit (2) connected to the drain at the bottom of the sink (A).

2. Grinding step (S2)

Food waste and water input through the input port 21 drop downwards.

Crushing cutters and grinding drums respectively formed on the upper surface of the grinding plate 22 and the outer side of the grinding plate 22 while food waste falling on the grinding plate 22 driven by a driving device such as a motor collides with the rotating plate 22 The food waste is crushed to a smaller size, and the crushed food waste falls together with water to the lower portion of the crushing plate 22.

3. Primary discharge step (S3)

The food waste and water pulverized by the rotation of the crushing plate 22 are discharged through the primary outlet 24 communicated with the lower portion and side of the crushing plate 22.

A venturi portion 36 may be formed in the primary outlet 24 as shown in FIG. 3.

Venturi is to form a small diameter of a certain section of the pipe in a streamlined form, when the venturi portion 36 is formed, the hydraulic pressure is lowered, and the Venturi effect occurs when the flow rate is fast.

The effect of the venturi portion 36 will be mentioned again in the following recirculation step (S5-1).

4. Screening step (S4)

At the outlet of the primary outlet 24, the secondary outlet 32 formed to communicate in the longitudinal direction and the recovery pipe 33 formed to communicate upward are connected to be branched, respectively. A filter network 31 is formed at the entrance of the secondary discharge port 32, and a plurality of sorting holes 311 having a predetermined diameter are formed in the filter network, and the diameter of one of the 1 to 3 mm is suitable. .

Among the food wastes introduced through the primary outlet 24, the food waste that has been crushed in a particle size smaller than the sorting hole passes through the sorting hole 311 and flows into the secondary outlet 32, and is crushed larger than the sorting hole. Food waste does not pass through the sorting hole 311 and flows into the collection pipe 33.

Naturally, the water can pass through the sorting hole 311, but since the water passing through the primary outlet 24 cannot pass through the sorting hole 311 at a time, some water is introduced into the recovery pipe 33. , The remaining water will pass through the selection hole 311.

The filtering net 31 may be formed in various forms.

As shown in FIG. 4, a conical shape with a wide entrance and a narrow exit may be formed. When the shape of the filtering net 31 is conical, vortices are generated due to a conical shape in which food waste and water are gradually narrowed. Food waste and water that have not passed through the sorting hole 311 are easily introduced into the recovery pipe 33 by slow flow.

As shown in FIG. 5, the mesh screen 31 may be formed in a diagonal shape, or the mesh network 31 may be formed in an arc shape as illustrated in FIG. 6. In the case of forming the filtering net 31 in a diagonal or arc shape, a vortex is not formed, and a pipe leading from the primary outlet 24 to the recovery pipe 33 is formed close to the streamline, and the primary outlet 24 By reducing the resistance of the fluid from to the recovery pipe 33, food waste is slid to prevent the problem of being deposited at the inlet of the filtering net 31 to the recovery pipe 33.

5. Recirculation stage (S5-1)

Food waste having a diameter larger than that of the sorting hole 311 does not pass through the filtering net 31 and flows into the collection pipe 33. The inlet of the recovery pipe 33 is connected in communication upward from the outlet of the primary outlet 24, and the recovery pipe 33 is formed to communicate with one side of the crushing section 2, but the height of the communication pipe is 22 ) Is located on the side of the inlet 21 higher than. A re-entry port 34 is formed at an outlet of the recovery pipe 33.

In addition, in order to prevent a problem that food waste or water that is initially input from the input port 21 flows into the re-entry port 34, a blocking wall 37 of a shape that is opened at a predetermined angle at the re-inlet port 34 may be added. have.

Food waste and some water moved upward through the recovery pipe 33 are again introduced into the upper portion of the crushing plate 22 through the re-inlet 34, and are repeated again from the crushing step S2.

Therefore, from the crushing step (S2) to the recirculation step (S5-1), food wastes larger than the diameter of the sorting hole 311 may be repeated until they are smaller than the diameter of the sorting hole 311.

At this time, if the venturi portion 36 is formed in the first discharge step (S3), the speed of the food waste and water reaching the filtering network 31 is faster, so that the screening step (S4) proceeds faster and flows into the recovery pipe (33). The food waste and water to be raised rise more quickly to prevent backflow inside the recovery pipe 33 and shorten the recirculation time, so that a larger amount can be crushed compared to the same time.

6. Secondary discharge stage (S5-2)

Food waste crushed to a diameter smaller than the sorting hole 311 passes through the sieve network 31 and flows into the secondary outlet 32 to be discharged.

If there is no separate discharge unit 4, the crushed food waste may be configured to drain directly from the secondary discharge port 32 to the outside.

Alternatively, it may be combined to be introduced into an existing enzyme fermentation or microbial fermentation device.

In the detailed description, it will be described based on the form in which the discharge portion 4 through which the food waste and water flows is formed is formed in communication with the secondary discharge port 32.

If the sorting step (S4) is continued, in some cases, the food waste may be stuck in the sorting hole 311 of the sieve network 31, and other food waste may not pass, thereby preventing the sorting.

In order to solve the above problem, the backwashing nozzle 35 may be configured to be installed in the secondary outlet 32 to the rear of the filtering net 31.

The high-pressure fluid (air or water) from the backwashing nozzle (35) can be shot forward from the rear of the strainer (31) to extract food waste stuck in the sorting hole (311) in the reverse direction, and the waste food waste can be collected ( 33).

The backwashing nozzle 35 acts in the reverse direction to intentionally interfere with the flow of food waste and water, so that the driving device 23 is repeatedly operated in a constant pattern during operation, or the controller 5 to be described below. ).

7. Storage step (S6)

Food waste and water discharged through the secondary discharge port 32 are stored in the storage space 41 of the discharge unit 4.

If necessary, food waste may be stored in the storage space 41 for a certain period of time, or may be discharged through the tertiary discharge port 43 formed on one side of the discharge unit 4, or the upper side of the discharge unit 4 It may be collected through the discharge cover 45 formed in.

8. Ultrasonic dissolution step (S7)

By the ultrasonic generator 42 installed at the bottom of the discharge portion 4, food waste can be very finely crushed into molecules that are soluble in water by ultrasonic waves.

Therefore, compared to the conventional methods such as enzymes and microbial decomposition, the ultrasonic generator 42 can pulverize food waste in a short time.

Secondary discharge (32) so that the driving device (23) of the crushing unit (2), the backwashing nozzle (35) of the secondary discharge port (32), and the ultrasonic generator (42) of the discharge unit (4) can be controlled to be linked to each ) To install a sensor (B), such as a photo sensor, each driving device 23, a backwash nozzle 35, a control unit 5 for controlling the ultrasonic generator 42 is installed in the food waste disposal system (1) It might be.

According to the amount of food waste measured by the sensor (B) at the secondary outlet, it is to control whether the driving device 23, the backwashing nozzle 35, and the ultrasonic generator 42 are operated through a PCB controller or the like.

9. 3rd discharge step (S8)

The ultrasonic generator 42 is used to discharge the completely dissolved water in the liquid in which food waste is dissolved through the tertiary discharge port 43 formed on one side of the discharge unit 4 to the sewer.

A flow rate may be adjusted by additionally attaching a valve 44 to the tertiary outlet 43.

In addition, while the food waste or the completely dissolved water in which the food waste is dissolved is stored in the storage space 41, the food waste that has been sludged is hardened by evaporation of moisture, failure of the ultrasonic generator 42, or after age. In this case, the food waste may be separately collected by opening the discharge part cover 45 formed on the upper side of the discharge part 4.

As described above, in the detailed description of the present invention, the most preferred embodiments of the present invention have been described, but various modifications may be made within the scope of the technical scope of the present invention. Therefore, the protection scope of the present invention should not be limited to the above-described embodiments, but the protection scope should be recognized from the technologies of the claims to be described later and the technical means equivalent to these technologies.

1: Food waste disposal system
2: crushing section 21: inlet 22: crushing plate 23: drive unit 24: primary outlet
3: Recycling section 31: Crossing network 311: Selecting hole 32: Secondary outlet 33: Collection pipe
34: re-entry 35: backwashing nozzle 36: venturi part 37: barrier
4: outlet 41: storage space 42: ultrasonic generator 43: tertiary outlet
44: valve 45: outlet cover
5: Control section
A: Sink B: Sensor
S1: Injection stage S2: Grinding stage S3: Primary discharge stage S4: Selection stage
S5-1: Recirculation step S5-2: Secondary discharge step S6: Storage step
S7: Ultrasonic dissolution step S8-1: 3rd discharge step S8-2: Solid discharge step

Claims (7)

A crushing section having an inlet 21 through which food waste and water are input from the sink A, a pulverizing plate 22 rotating to crush the input food waste, and a primary outlet 24 through which crushed food waste is discharged (2);
Of the food waste discharged from the primary outlet 24 of the crushing section 2, the filtering net 31 having a sorting hole 311 formed to pass only food waste smaller than a predetermined size, and the food passing through the filtering net 31 A recirculation section (3) having a secondary discharge port (32) through which waste is discharged, and a recovery pipe (33) that allows food waste that has not passed through the sorting hole (311) to be re-injected into the upper portion of the crushing plate (22). ;
Food waste disposal system characterized in that it contains.
The method according to claim 1;
The storage space 41 where food waste introduced from the secondary discharge port 32 collects, and the ultrasonic generator 42 that molecularly disposes food waste collected in the storage space 41 and dissolves in water, and discharges food waste to the outside A storage unit 4 made of a tertiary discharge port 43 on which a throttle valve 44 is installed;
Food waste disposal system characterized in that it is further included.
The method according to claim 1;
A venturi portion 36 formed with a small diameter of some sections in the primary outlet 24 to increase the speed of food waste discharged from the primary outlet 24 and quickly flow into the recovery pipe 33;
Food waste disposal system characterized in that it is further included.
The method according to claim 1;
A backwashing nozzle 35 formed in the secondary outlet 32 for generating high-pressure fluid to push food waste stuck in the sorting hole 311 of the filtering net 31 in the reverse direction;
Food waste disposal system characterized in that it is further included.
The method according to claim 2 and claim 4;
A sensor B formed in the secondary outlet 32 to measure the amount of food waste that has passed through the filtering net 31;
A control unit 5 configured to be electrically connected to control whether the driving device 23 and the backwashing nozzle 35 and the ultrasonic generator 42 are rotated according to the measurement amount of the sensor B;
Food waste disposal system characterized in that it is further included.
In the food waste disposal method using the food waste disposal system according to any one of claims 1 to 5,
And the food waste and water input from the sink (A) to the inlet (21) input step (S1),
A crushing step (S2) in which the input food waste is crushed by the crushing plate 22;
A primary discharge step (S3) in which the crushed food waste is discharged through the primary discharge port 24,
A sorting step (S4) in which food waste is sorted in the sorting hole 311 of the filtering net 31,
A recycling step (S5-1) in which food waste larger than the sorting hole 311 is re-injected into the crushing section 2 through the recycling section 3;
Food waste treatment method characterized in that the food waste is processed through a second discharge step (S5-2) in which the small food waste that has passed through the sorting hole 311 is discharged through the secondary discharge port 32.
The method according to claim 6,
A storage step (S6) in which food waste discharged through the secondary discharge port 32 flows into the storage space 41;
Ultrasonic dissolving step (S7) in which food waste stored in the storage space 41 is dissolved in water by the ultrasonic generator 42,
The food waste treatment method characterized in that the food waste is further processed through a third discharge step (S8) in which the complete dissolved water in the liquid in which the food waste is dissolved is discharged through the third discharge port 43.

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