KR20160039410A - Separate type food waste disposal device - Google Patents

Abstract

The present invention relates to a separation type apparatus for treating food wastes, in which the apparatus includes: a waste material container having a plurality of pores on the surface thereof, a low-level sensor and a high-level sensor for measuring the height of the waste materials contained in the container, and an openable intake valve placed at an waste material inlet, thereby temporarily containing the waste materials discharged from at least one disposer in the container and discharging the waste materials through the lower part thereof; a waste material dehydrating device connected to a lower part of the waste material container for separating and separately discharging the waste materials introduced through the waste material container into sludge and sewage; a sludge container for receiving the sludge separately discharged from the waste material dehydrating device; and a sewage container for receiving the sewage discharged through the pores of the waste material container and the sewage separately discharged from the waste material dehydrating device. The present invention provides that the waste materials discharged through the disposer is separated into sludge and sewage, and the sludge is separately discharged and only the sewage is moved to a sewage treatment plant, thus improving a purifying efficiency for the sewage of the food wastes.

Description

Separate type food waste disposal device [0002]

The present invention relates to a detachable food garbage disposing device capable of separating and processing sludge and sewage from by-products passed through a disposer.

In general, food waste generated in homes and restaurants is collected and discharged with water removed, or disposer is installed on the sink drainage pipe to finely grind food waste and discharge it to the sewage pipe together with sewage Such disposers have already been disclosed in Korean Patent Laid-Open Publication No. 10-2012-0088193 (Published Aug. 8, 2012).

However, when the finely pulverized food waste is discharged through the disposer into the sewer together with the sewage from the kitchen, it causes many problems.

That is, if the by-product treated through the disposer is not completely decomposed and the sludge is discharged into the sewer together with the sewage in the form of pulverized sludge, the sewer pipe is easily clogged by the sludge, and when the sludge is introduced into the river, It can become corrupted and malodorous, and water quality can be contaminated.

On the other hand, the authorities that manage sewage treatment have separate sewage disposal plants to treat the sewage discharged from households and restaurants. These sewage disposal plants do not consider disposal of food waste through the disposer, It is designed for the treatment of sewage effluent. Therefore, authorities are required to regulate disposers installed in homes and restaurants for the smooth and normal treatment of sewage.

However, since households and restaurants where disposers are installed are gradually increasing and management supervision by the authorities is not being performed properly, the number of disposers installed in homes and restaurants may be increased, and food waste disposal Devices are urgently required.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a sludge treatment method and a sludge treatment method which can separate sludge and sewage from dehydrated sludge before reaching a sewage end treatment plant, The present invention also provides a disposable food garbage disposal apparatus.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the precise form disclosed. It can be understood.

According to a preferred embodiment of the present invention, a by-product, which is formed on the surface of a plurality of pores and is discharged from at least one disposer, is temporarily stored therein and then discharged to the lower portion. In order to measure the level of the by- A by-product storage tank provided with a level sensor and a high-level sensor and having an inlet opening / closing valve at the upper side by-product inlet, and a by-product dewatering unit connected to a lower portion of the byproduct storage tank, separately separating the by- A sludge storage tank for collecting the sludge separated and discharged from the byproduct dewatering device, and a sewage storage tank for collecting sewage discharged and discharged from the byproduct dewatering device.

More preferably, a pipeline switching valve is provided in the moving path of the by-product discharged from the at least one disposer, and a plurality of byproduct storage tanks are connected to the pipeline switching valve and selectively opened and closed through the control unit. And the byproduct can be moved to at least one selected one of the plurality of byproduct storage tanks through selective opening and closing.

More preferably, the driving unit is located above the byproduct storage tank, the driving shaft of the driving unit passes through the upper surface of the byproduct storage tank and is located inside the byproduct storage tank, and the driving shaft is connected to the inner surface of the byproduct storage tank through the link member. And a scraper rotated along the side surface is connected.

More preferably, the by-product dewatering apparatus comprises a mesh-type housing having a by-product inlet at an upper portion thereof, a sludge outlet at a lower portion thereof and a plurality of mesh holes at a surface thereof, driving means provided on the outer side of the housing, And a screw conveyor connected to the driving means and rotatably installed in the housing, the screw conveyor having a spiral wing on an outer circumferential surface thereof.

More preferably, the sludge storage tank is provided with a sludge storage container capable of entering and exiting the inside and outside of the sludge storage tank, and a level sensing sensor is provided in the sludge storage tank to determine and warn the amount of sludge to be filled in the sludge storage vessel do.

More preferably, the sewage storage tank is connected to the sewage end treatment plant, and the receiving member is provided with a receiving member spaced upward from the bottom surface. The receiving member includes a filter net for filtering the sludge from the sewage discharged from the by- And the upper surface of the sewage storage tank is formed with an opening and closing door for storing and withdrawing the filter net container.

The present invention is configured such that the byproduct discharged through the disposer is separated into sludge and sewage through a dehydration process before being introduced into the sewage end treatment plant, and the sludge is separately discharged and moved to the sewage end treatment plant only by the sewage, The processing efficiency can be further improved.

In addition, since the byproduct storage tank can be constituted by a plurality, it is possible to treat the food waste easily by switching to another one even if an abnormality occurs in any one of the byproduct storage tanks, and the efficiency of the treatment can be improved.

In addition, since the effect of the present invention described above is expected to be exerted by the composition of the contents regardless of whether or not the inventor perceives it, the effect described above is only some effects according to the contents described, Should not be recognized.

Further, the effect of the present invention should be grasped further by the entire description of the specification, and even if it is not stated in an explicit sentence, a person having ordinary skill in the art to which the written description belongs, It should be seen as an effect described in this specification.

FIG. 1 is a configuration diagram illustrating an apparatus for separating food garbage disposal according to an embodiment of the present invention.
2 is a front view illustrating a configuration of a separated food waste disposal apparatus according to an embodiment of the present invention.
FIG. 3 is a side view illustrating a configuration of a separable food garbage disposal apparatus according to an embodiment of the present invention.
FIG. 4 is a perspective view illustrating a sewage storage tank of a separable food garbage disposal apparatus according to another embodiment of the present invention.
FIG. 5 is a flowchart illustrating an important operation process of the separated food garbage disposal apparatus according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that the same is by way of illustration and example only and is not to be taken by way of limitation, the scope of the present invention being indicated by the appended claims rather than by the foregoing description.

In addition, the sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation, and the terms defined specifically in consideration of the structure and operation of the contents described may vary depending on the intention or custom of the user or the operator And the definitions of these terms should be based on the contents throughout this specification.

The separation type food garbage disposal apparatus according to the present invention includes a byproduct storage tank in which by-products discharged from the disposer are introduced and temporarily stored, and a by-product dewatering device that dehydrates the byproducts from the byproduct storage tank to separate and discharge the sludge and sewage water. A sludge storage tank for storing the sludge separated and discharged from the byproduct dewatering device, and a sewage storage tank for storing the sewage water separated and discharged from the byproduct dewatering device. In detail, same.

The byproduct storage tank (100)

As shown in FIG. 1, is a device for temporarily storing and discharging by-products containing sewage and sludge discharged from a plurality of disposer 700 installed in a home or a restaurant.

The shape of the byproduct storage tank 100 does not need to be determined to be any one, but preferably, the shape of the byproduct storage tank 100 may be such that the upper side is wider and the lower side is narrower for smooth gravity discharge as shown in FIG.

The disposer 700 and the byproduct storage tank 100 may be connected by a connecting pipe (not shown), and a check valve for preventing backflow is installed in the connection pipe, And is connected to the inlet 130.

The side surface of the byproduct storage tank 100 may be formed of a perforated plate having a plurality of perforations 180 formed therein so that the sludge contained in the by- . Therefore, it is possible to prevent the sewage contained in the by-product from overflowing beyond the set level of the byproduct storage tank 100 through the perforation 180.

On the other hand, the perforations 180 of the byproduct storage vessel 100 may be clogged by the sludge contained in the byproduct. As an example of removing the sludge plugged into the perforation 180, a scraper 170 may be provided to clean the inner surface of the byproduct storage tank 100 having the perforations 180 as shown in FIG. 2 .

The scraper 170 is in contact with at least one portion along the inner surface of the by-product storage tank 100 in which the perforation 180 is formed and the contact portion may be made of a soft rubber or silicone to improve adhesion .

The shape of the scrapers 170 may be shaped to correspond to the shape of the inner surface of the byproduct storage tank 100 so that the scrapers 170 may be closely contacted with the inner surface of the byproduct storage tank 100, And the drive shaft 150 of the drive unit 150 passes through the upper surface of the byproduct storage tank 100 and is driven by the byproduct storage tank 100 And a scraper 170 is connected to the drive shaft 151 through a link member 160. [

The by-product storage tank 100 is provided with water level sensing means for measuring the level of the byproducts stored therein, and one example of the water level sensing means is a low level sensor 120 and a low level sensor 120, A high level sensor 110 may be installed and the low level sensor 120 and the high level sensor 110 are connected to the control unit 500.

Accordingly, when the by-product introduced into the byproduct storage tank 100 is a low water level sensed by the low level sensor 120, the controller 500 stops driving the by-product dewatering device 200 described below, And when the byproducts flowing into and stored in the byproduct storage tank 100 are a high number of sensed by the high level sensor 110, the controller 500 senses the byproduct and drives the byproduct dewatering device 200, .

When the level of the byproducts stored in the byproduct storage tank 100 reaches the high level sensor 110, the byproduct dewatering device 200, which will be described later, is operated and the byproduct is transferred to the byproduct dewatering device 200, It is necessary to design the discharge amount of the by-product to be transferred to the by-product dewatering device 200 to be equal to or larger than the inflow amount of the by-product to be introduced into the internal combustion engine 100. In case the inflow amount is larger than the discharge amount of the by- Means for preventing the overflow from being overflowed in the storage tank 100 may further be provided.

An inlet opening and closing valve 131 is provided between the byproduct inlet 130 of the byproduct storage tank 100 and the connecting pipe and the inlet opening and closing valve 131 is connected to the control unit 500 Or the like.

Accordingly, when the byproduct entering the byproduct storage tank 100 exceeds the high level sensor 110, the control unit 500 can close the inlet opening / closing valve 131 to stop the byproduct from flowing into the byproduct storage tank 100 If the by-product does not exceed the high level sensor 110 after a predetermined period of time, the controller 500 may open the inlet opening / closing valve 131 again to start the introduction of the by-product into the by-product storage tank 100 .

The control of the inflow opening and closing valve 131 is a means for preventing the overflow of byproducts flowing into the byproduct storage tank 100 as well as preventing the byproduct storage tank 100 or the byproduct dewatering device 200 or the sludge storage tank 300 It is possible to stop the treatment of the byproducts through the control of the inflow opening / closing valve 131 even when a problem such as malfunction or stoppage of components including the sewage storage tank 400 occurs.

As another embodiment of the present invention, the byproduct storage tank may be composed of a plurality of units. FIGS. 1 and 3 show an embodiment in which a byproduct storage tank is composed of a pair, and the number of byproduct storage tanks may be plural have.

In the present invention, two by-product storage tanks are described. For convenience of description, two byproduct storage tanks are defined as a byproduct storage tank 100 and an auxiliary byproduct storage tank 100a.

In the case of the byproduct storage tank 100 and the auxiliary byproduct storage tank 100a, a pipe line switching valve 600 is provided in a connection pipe connected to the disposer 700. The pipe line switching valve 600 is branched and connected to the byproduct storage tank 100 And the auxiliary byproduct storage tank 100a. At this time, the pipeline switching valve 600 switches the pipeline under the control of the control unit 500.

When the byproduct storage tank 100 is used, the conduit switching valve 600 receives a signal from the control unit and connects the connection pipe connected to the disposer 700 and the byproduct storage tank 100, and connects the connection pipe connected to the disposer 700 The auxiliary byproduct storage tank 100a is shut off.

If the operation of the byproduct storage tank 100 is stopped due to an abnormality in the process of using the byproduct storage tank 100, the control unit 500 controls the pipe switching valve 600 to connect the connection pipe 600 connected to the disposer 700 The auxiliary byproduct storage tank 100a can be used until the byproduct storage tank 100 is returned to the original state by interrupting the connecting pipe connected to the disposer 700 and the byproduct storage tank 100 It is.

Meanwhile, a plurality of configurations, such as the byproduct storage tank 100 and the auxiliary byproduct storage tank 100a, may be used as a spare in preparation for any failure, but the present invention is not limited thereto, If the amount of the byproducts flowing into the byproduct storage tank 100 exceeds the acceptable range of the byproduct storage tank 100, the auxiliary byproduct storage tank 100a may be processed in a modified manner.

In this case, the pipe line switching valve 600 is in a neutral state to simultaneously supply the byproducts to the byproduct storage tank 100 and the auxiliary byproduct storage tank 100a. The byproduct dewatering device 200, which will be described later, It is clear that the present invention has the capability of receiving and processing all by-products discharged from the storage unit 100a.

The byproduct dewatering device 200,

By-product discharged from the by-product storage tank 100 is separated and separated into sludge and sewage through a dehydrating operation and discharged individually.

As shown in FIG. 2, the by-product dewatering apparatus 200 includes a mesh-shaped housing 210 into which a byproduct flows, a screw conveyor 215 for dehydrating the incoming by-product and separating it into sludge and sewage And a driving means 214 for rotating the screw conveyor 215.

The mesh-shaped housing 210 is provided with a by-product inlet 213 for allowing the by-product discharged from the by-product storage tank 100 to flow into one side of the upper side, and a sludge outlet 211 is provided on one side of the bottom.

Therefore, the by-product introduced into the by-product inlet 213 of the housing 210 is dewatered while being compressed and moved toward the sludge outlet 211 by the rotation of the screw conveyor 215 inside the housing 210, The sludge from which the sewage has been removed from the byproducts is moved to one side by the screw conveyor 215 and then discharged to the sludge discharge port 211 do.

The housing 210 may have a cylindrical shape, and may have an elliptical shape, a polygonal shape, or the like, if desired. The vents 212 formed on the surface of the housing 210 are preferably circular, And the like, and the size, number, and arrangement state thereof can be variously modified without having to be determined by any one of them.

At least one hole (not shown in the figure) may be formed in the wing 215a of the screw conveyor 215 and the water content of the sewage contained in the sludge may be adjusted through the number and size of such holes.

The byproduct dewatering apparatus 200 can separate the sludge and the sewage water by squeezing and dewatering the by-product through the housing 210, the screw conveyor 215, and the driving means 214. However, May be replaced by a centrifugal separator which separates the sludge into sewage and sewage.

The operation of the driving means 214 of the screw conveyor 215 is controlled through the control unit 500 and the determination of the abnormality of the driving means 214 is also performed through the control unit 500. As described above, The driving means 214 may be stopped or driven through the control unit 500 according to the level of the byproduct stored in the control unit 500. [

The sewage storage tank (400)

The apparatus for collecting sewage discharged from the perforation 180 of the byproduct storage tank 100 and the sewage separated from the byproduct through the byproduct dewatering apparatus 200 includes a byproduct storage tank 100 and a byproduct dewatering apparatus 200 And is sized so as to accommodate the falling range of the sewage discharged from the perforation 180 of the byproduct storage tank 100 and the by-product dewatering apparatus 200.

A preferred embodiment of the sewage storage tank 400 has a shape of an enclosure having an opened top surface as illustrated in FIGS. 2, 3 and 4, and a supporting member 430 is provided at an intermediate portion spaced upward from the bottom surface , And a filter net container (410) having an open upper surface is installed in the support member (430).

The sewage storage tank 400 may have a storage space capable of storing a predetermined amount of sewage therein, and a drain valve for cleaning (not shown) may be opened and closed below the sewage storage tank 400.

The filter net container 410 serves to filter sludge discharged from the perforation 180 of the byproduct storage tank 100 and sludge and foreign matter that may be contained in the sewage separated from the byproducts through the byproduct dewatering device 200.

The reason why the opening and closing door 420 is separated from the bottom surface of the sewage storage tank 400 is that the bottom surface of the sewage storage tank 400 is separated from the bottom surface of the sewage storage tank 400, To prevent leakage of sewage filled through the opening / closing door 420.

The filter net container 410 can be easily stored and drawn into the sewage storage tank 400 through the opening and closing door 420 so that the filter net container 410 having the filtered sludge and foreign matter can be easily taken out from the sewage storage tank 400, And the cleaning and maintenance of the filter net container 410 can be effectively performed.

In addition, the sewage collected in the sewage storage tank 400 is transferred to the sewage end treatment plant as shown in FIG.

The sludge storage tank (300)

Is a device for collecting sludge separated from by-products through the above-described by-product dewatering device (200).

The sludge storage tank 300 is connected to the sludge discharge port 211 of the by-product dewatering apparatus 200 as shown in FIG. 2, and has an internal space of a predetermined size for storing the sludge discharged to the sludge discharge port 211 I have.

The sludge storage tank 300 may store the sludge directly by using the internal space, but it is preferable to form the door 310 on either the front or rear side or the both sides of the sludge storage tank 300, And a sludge storage container 311 capable of entering and exiting the inside and the outside of the sludge storage tank 300.

The sludge storage container 311 can slide in and out of the sludge storage tank 300 through the rail structure and a rolling member is provided on the bottom surface of the sludge storage container 311 to secure the mobility of the sludge storage container 311 You may.

If the amount of the sludge to be filled in the sludge storage vessel 311 of the sludge storage tank 300 exceeds a certain amount, it is necessary to discharge the sludge to the outside and remove the sludge.

Accordingly, the sludge storage tank 300 or the sludge storage container 311 may be provided with a sensing means such as a pressure sensor and a level sensing sensor 312 to measure the amount of sludge to be filled into the sludge storage vessel 311 The discharge time of the sludge to be filled in the sludge storage vessel 311 can be effectively determined and easily removed.

The process of the separated food garbage disposal system according to the present invention will be described with reference to FIG.

First, in an embodiment of the present invention, a plurality of embodiments including a byproduct storage tank and an auxiliary byproduct storage tank will be described.

First, the control unit 500 needs to determine whether the operation of the byproduct storage tank 100 is abnormal (S100).

When it is confirmed that there is no abnormality in the operation of the byproduct storage tank 100, the byproduct flows into the byproduct storage tank 100 (S110)

The level of the byproducts flowing into and stored in the byproduct storage tank 100 is continuously sensed by the low level sensor 120 and the high level sensor 110 connected to the control unit 500. In operation S120,

At this time, when it is determined that the level of the byproduct is low level detected by the low level sensor 120 (S130), the controller 500 stops the operation of the byproduct dewatering device 200 to prevent unnecessary power consumption (S131 )

However, when it is determined that the level of the by-product reaches the high level sensor 110 (S140), the control unit 500 activates the by-product dewatering apparatus 200 (S141)

If the operation of the by-product dewatering apparatus 200 is abnormal during operation, if the operation of the by-product dewatering apparatus 200 occurs (S142), the control unit 500 Off valve 131 is turned off (S143), and the operation of the by-product dewatering apparatus 200 is stopped (S144)

When it is determined that the level of the by-product exceeds the high level sensor 110 (S150), the controller 500 waits for a predetermined time to check whether the by-product exceeds the high level sensor 110. If it is determined that the by- Off valve 131 is turned off to shut off the valve (step S151)

If the control unit 500 determines that the operation of the byproduct storage tank 100 is abnormal when the operation of the byproduct storage tank 100 is determined (S100), the controller 500 controls the pipe switching valve 600 The by-product discharged from the disposer 700 is blocked from being transferred to the by-product storage tank 100 and is moved to the auxiliary by-product storage tank 100a so that the by-product is introduced into the auxiliary by-product storage tank 100a (S210) )

The level of the byproducts flowing into and stored in the auxiliary byproduct storage tank 100a is also sensed by the low level sensor 120 and the high level sensor 110 connected to the control unit 500. In operation S220,

At this time, if it is determined that the level of the byproduct stored in the auxiliary byproduct storage tank 100a is low level detected by the low level sensor 120 (S130), the controller 500 stops the operation of the byproduct dewatering device 200 S131)

When it is determined that the level of the by-product reaches the high level sensor 110 (S140), the controller 500 activates the by-product dewatering device 200 (S141)

Thereafter, the control unit 500 periodically checks the operation of the by-product dewatering unit 200. If an error occurs in the operation of the by-product dewatering unit 200 during operation and there is a problem with the operation (S142) The controller 500 turns off the inlet opening / closing valve 131 (S143) and stops the operation of the by-product dewatering apparatus 200 (S144)

When it is determined that the level of the by-product exceeds the high level sensor 110 (S150), the controller 500 waits for a predetermined time to check whether the by-product exceeds the high level sensor 110. If it is determined that the by- Off valve 131 is turned off (S151).

On the other hand, when the operation of the by-product dewatering apparatus 200 is normally operated (S142), the by-product dewatering apparatus 200 dehydrates the byproducts (S145) and separates the sludge and sewage, The sludge discharged from the sludge storage vessel 311 through the sludge storage unit 311 is accumulated in the sludge storage vessel 311 located in the sludge storage tank 300. When the sludge is accumulated in the sludge storage vessel 311, The operator opens the door 310 of the sludge storage tank 300 and then takes out the sludge storage container 311 and moves it to the land treatment facility .

The sewage discharged from the perforation 180 of the byproduct storage tank 100 or the auxiliary byproduct storage tank 100a through the vent hole 212 of the dewatering and byproduct dewatering apparatus 200 So that the sludge or foreign matter that may be contained in the sewage water is collected in the filter net container 410. The filter net container 410 is disposed in the upper part of the sewage storage tank 400, So that only sewage is collected in the sewage storage tank 400.

In addition, the filter net container 410 can be received and taken out through the opening / closing door 420 formed on the front surface of the sewage storage tank 400 to easily remove the sludge filtered by the filter net container 410, Can be easily cleaned or exchanged.

And the sewage stored in the sewage storage tank 400 is moved to an externally located sewage end treatment plant and processed.

Although the present invention has been fully described by way of example with reference to the accompanying drawings, it is to be noted that various changes and modifications may be made without departing from the scope of the present invention. Therefore, the scope of the disclosed contents should not be limited to the described embodiments, but should be determined by the appended claims and equivalents thereof.

100: byproduct storage tank 100a: auxiliary byproduct storage tank
110: high level sensor 120: low level sensor
130: byproduct inlet 131: inlet opening / closing valve
140: By-product discharge port 150:
151: drive shaft 160: link member
170: scraper 180: perforation
200: Byproduct dewatering device 210: Housing
211: sludge discharge port 212:
213: Byproduct inlet 214: Driving means
215: screw conveyor 300: sludge storage tank
310: door 311: sludge storage container
312: Level sensing sensor 400: Sewage storage tank
410: filter net container 420: opening / closing door
430: support member 500:
600: conduit switching valve 700: disposer

Claims (6)

A low level sensor and a high level sensor are provided so as to measure the level of the byproducts stored in the inside and the byproducts discharged from the at least one disposer are temporarily stored in the inside and discharged to the bottom A byproduct storage vessel having an inlet opening and closing valve at the upper side by-product inlet;
A byproduct dewatering device connected to a lower portion of the byproduct storage tank and separating the byproducts flowing through the byproduct storage tank into sludge and sewage and discharging the byproduct separately;
A sludge storage tank for collecting the sludge separated and discharged from the by-product dewatering device; And
And a sewage storage tank for collecting the sewage discharged from the by-product storage tank and the sewage discharged separately from the by-product dewatering device.
The method according to claim 1,
A pipe switching valve is provided on a moving path of the by-product discharged from the at least one disposer, and a plurality of byproduct storage tanks are connected to the pipe switching valve and selectively opened and closed through a control unit, Wherein the byproduct can be moved to at least one of the plurality of byproduct storage tanks through the at least one byproduct storage tank.
3. The method according to claim 1 or 2,
The driving shaft of the driving unit passes through the upper surface of the by-product storage tank and is located inside the by-product storage tank. The driving shaft is connected to the inner surface of the by-product storage tank through the link member, And a scraper which is rotated along with the scraper is connected.
The method according to claim 1,
The by-product dewatering device comprises:
A mesh-type housing having a sludge discharge port at one side thereof and a plurality of mesh holes at a surface thereof;
Driving means provided outside the housing; And
And a screw conveyor connected to the driving unit and rotatably installed in the housing, the screw conveyor having a spiral wing on an outer circumferential surface thereof.
The method according to claim 1,
The sludge storage tank is provided with a sludge storage container capable of entering and exiting the inside and outside of the sludge storage tank. A level sensor is provided in the sludge storage tank to determine and warn the amount of sludge to be filled in the sludge storage vessel Wherein the waste water is discharged into the waste water tank.
The method according to claim 1,
The sludge storage tank is connected to a sewage end treatment plant and has a support member spaced upward from the bottom surface. The support member is provided with a filter net container for filtering sludge from sewage discharged from the by- And an opening / closing door for storing and withdrawing the filter net container is provided on the upper side of the front surface of the sewage storage tank.

Images