KR102457723B1 - Sewage treatment facility management system - Google Patents

Abstract

By enabling to check in real-time a situation of a sewage treatment facility located in a remote location, the present invention relates to a sewage treatment facility management system that predicts a lifespan of each device and configuration of the sewage treatment facility, and detects a generation of an abnormality in advance, thereby enabling to treat. The sewage treatment facility management system comprises: a sewage treatment facility part; a facility management part; a central management server part; and an administrator terminal.

Description

Sewage treatment facility management system

The present invention relates to a sewage treatment facility management system, and more particularly, by predicting the lifespan of each device and configuration of a sewage treatment facility by enabling real-time confirmation of the situation of a sewage treatment facility located at a remote location to detect abnormal occurrence in advance. It is about a sewage treatment facility management system that can cope with it.

In general, the discharge of sewage through sewage pipes to treat domestic sewage, which is the main cause of pollution in the living environment, greatly contributed to the improvement of the living environment of the residential area. The primary private sewage treatment facility to treat sewage discharge before discharge through sewage conduits is very important for improving the sanitation level of modern industrial society.

In Korea, according to the Sewerage Act, “personal sewage treatment facility” is defined as a facility that treats sewage generated from buildings and facilities by methods such as sedimentation and decomposition, and the amount of sewage generated per day outside the sewage treatment area. If the standard of 2㎥ exceeds this, a 'sewage treatment facility' is installed, and a 'septic tank' (sedimentation decay type independent septic tank) is required to be installed below this, so that individual sewage treatment facilities are classified into sewage treatment facilities and septic tanks. are doing

Since the above-mentioned personal sewage treatment facilities are usually installed over a wide area, abnormalities occurring during sewage treatment, for example, the operation status of the blower in the personal sewage treatment facility, the operation status of the septic tank aeration device, DO, BOD, SS, etc. If it is not accurately detected and selective measures such as troubleshooting, guidance inspection, and maintenance are not taken in a timely manner, secondary pollution accidents such as rivers and groundwater around private sewage treatment facilities may occur.

Republic of Korea Patent No. 10-1501749

An object of the present invention is to enable the situation of a sewage treatment facility located at a remote location to be checked in real time, and to predict the lifespan of each device and configuration of the sewage treatment facility, so that an abnormal occurrence can be detected and dealt with in advance.

The present invention is characterized in that it is a sewage treatment facility management system for checking the situation of a sewage treatment facility located in a remote place in real time.

In an embodiment, the sewage treatment facility management system includes: a sewage treatment facility unit configured to aerate the incoming sewage to separate the sludge and the treated water to discharge the treated water; and a facility management unit that receives the facility status of the sewage treatment facility in real time and provides it to the central management server side; and the facility management unit receives and stores real-time status information of the sewage treatment facility unit, compares the stored information with preset information, stores the failure information provided in real time, and detects the lifespan of the sewage treatment facility unit by learning and analyzing the stored information a central management server unit that transmits the control information of the sewage treatment facility unit to the facility management unit so that the sewage treatment facility can be managed according to the input information; and a manager terminal for the manager to check real-time status information from the central management server, wherein the sewage treatment facility includes: a sewage treatment module configured to process and discharge the incoming sewage; and a facility condition detection module formed on one side of the sewage treatment module to detect the flow rate, noise, vibration, load, and water level generated from the sewage treatment module; It consists of a facility driving module formed on one side of the sewage treatment module to receive control information from the facility management unit and provide information to the sewage treatment module and the facility condition detection module, wherein the sewage treatment module includes either sewage or sewage from the outside. A sewage inlet formed on one side of the sewage treatment module to flow into the flow storage tank, and a flow storage tank formed on one side of the treatment module so that either one of sewage or sewage flowing through the sewage inlet is stored, and the flow rate storage tank overflows and moves The sewer consists of an aeration tank formed on one side of the flow storage tank to inject air into any one of the sewage for aeration; It consists of a treated water outlet formed on the other side of the upper side of the sewage treatment module so that the treated water can be discharged to the outside, and a bulkhead formed between the flow storage tank and the aeration tank and between the aeration tank and the sludge settling tank so that the sewage and the treated water overflow according to the water level, The facility state detection module includes an air flow sensor formed on a bulkhead on one side of the aeration tank to detect the flow rate of air supplied to the aeration tank, and a sewage flow rate formed on one side inside the sewage inlet to detect the amount of sewage flowing in through the sewage inlet. A sensor, a noise sensor formed on an upper side of the sewage treatment module to detect noise generated from the sewage treatment module, and a vibration sensor formed on an upper side of the sewage treatment module to detect vibration generated from the sewage treatment module; A load detection sensor formed on one side of the inside of the treated water outlet to detect a load discharged when water is discharged, and a water level sensor formed on a bulkhead of one side of the flow storage tank to detect the water level of either sewage or sewage stored in the flow storage tank The facility driving module is configured to provide real-time status information received from the facility condition detection module to the real-time transmission/reception module side of the facility management unit, or to receive change and input information provided from the central management server unit from the real-time transmission module. Consists of a sensing information transmission/reception module formed on one side of the upper part of the sewage treatment module, The facility management unit includes a real-time transmission/reception module that receives change information and input information of the sewage treatment facility unit from the remote management information transmission/reception module and provides it to the facility control module, and receives information from the real-time transmission/reception module to provide the sensing information transmission/reception module side Consists of a facility control module, wherein the central management server unit includes a remote site management information transmission/reception module for receiving management information transmitted from the facility management unit receiving real-time information from the sewage treatment facility unit, and a remote site management information transmission/reception module. A database for storing management information, a failure detection module that analyzes failure detection information among management information provided through the remote management information transmission/reception module, and stores the analyzed information in the database, and the failure information stored in the database A learning analysis module that learns and analyzes real-time status information and stores the analyzed information in a database, and a lifespan detection module that analyzes and stores the lifespan according to the status information of the sewage treatment facility learned through the learning analysis module and stores it in the database; A facility that transmits the information to the remote management information transmission/reception module side in order to transmit the information to the facility management unit that manages the relevant sewage treatment facility unit in order to change or input the information of the relevant sewage treatment facility unit through the life detection module and the learning analysis module It is characterized in that it consists of an operation module.

In another embodiment, the sewage treatment facility management system further includes a sediment removal unit configured to be discharged to the outside when the sludge falling from the inside of the sludge settling tank to the bottom is settled, and the sediment removal unit is directed toward the bottom inside the sludge settling tank. A settling plate that is seated and formed by a load spring at a certain distance from the bottom surface, and a plate that supports the shaking of the settling plate, one side is fixed to the bottom of the sludge settling tank to support the load spring, and the other side is formed to pass through the settling plate The guide bar and the load spring formed between the settling plate and the bottom surface of the sludge precipitator to support the settling plate by being inserted into the plate guide bar to support the load of the sludge seated on the settling plate and the contact member when the settling plate is descending. A contact sensor formed in the lower center of the settling plate to provide detection information to the vibrator, the air pump and the suction pump, a contact member formed in the center of the bottom surface of the sludge precipitation tank so that the contact sensor can be contacted and sensed, and sensing information from the contact sensor A plurality of vibrators are formed on one side and the other side of the bottom of the settling plate to provide vibration to the settling plate by receiving An air pump formed on one side of the lower part of the sludge precipitation tank to generate air for moving the blocking membrane and the sludge deposited on the settling plate through the air jet nozzle toward the suction member, and to move the air generated from the air pump toward the high pressure jet nozzle An air injection pipe having one side connected to the air pump and the other side formed as one side of the sludge precipitation tank, a high-pressure injection nozzle formed on one side of the air injection pipe to inject air toward the settling plate, and the sludge moving through the high-pressure injection nozzle A suction pump formed on one side of the lower part of the sludge precipitation tank to generate a suction force for suction, and one side is connected to the suction member so that the sludge sucked through the suction member is discharged to the outside by the suction power of the suction pump, and the other side is connected to the suction pump It is specially characterized in that it consists of a sludge transport pipe formed and a suction member formed on one side of the sludge transport pipe to suck the sludge moved by air jet. do it with a jin

As described above, it is possible to check the situation of a sewage treatment facility located in a remote place in real time, so that the lifespan of each device and configuration of the sewage treatment facility is predicted, and the occurrence of an abnormality can be detected and dealt with in advance, thereby preventing failure in advance. have

1 is a view showing a sewage treatment facility for the sewage treatment facility management system of the present invention.
2A is a conceptual diagram of a sewage treatment facility management system of the present invention.
Figure 2b is a conceptual diagram of a sewage treatment facility management system of the present invention.
3 is a view of a sediment removal unit that is another embodiment for the sewage treatment facility unit of the present invention.
FIG. 4 is a detailed view of FIG. 3 .
5 is a view of an aeration amplifying unit that is another embodiment of the sewage treatment facility unit of the present invention.
FIG. 6 is a detailed view of FIG. 5 .
7 is a view of a bulkhead elevating unit according to another embodiment of the present invention for a sewage treatment facility unit.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0012] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0014] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0016] Reference is made to the accompanying drawings, which show by way of illustration specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein with respect to one embodiment may be implemented in other embodiments without departing from the spirit and scope of the invention. In addition, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the detailed description set forth below is not intended to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all scope equivalents to those claimed. Like reference numerals in the drawings refer to the same or similar functions throughout the various aspects.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 is a view showing the sewage treatment facility unit 100 for the sewage treatment facility management system 10 of the present invention, and FIGS. 2A and 2B are conceptual views of the sewage treatment facility management system 10 of the present invention.

As shown in the drawing, the sewage treatment facility management system 10 is characterized in that it is possible to check the situation of a sewage treatment facility located at a remote location in real time.

The sewage treatment facility management system 10 includes a sewage treatment facility unit 100 , a facility management unit 140 , a central management server unit 150 , and a manager terminal 160 .

The sewage treatment facility unit 100 is characterized in that it is formed to aerate the incoming sewage to separate the sludge and the treated water to discharge the treated water.

The sewage treatment facility unit 100 includes a sewage treatment module 110 , a facility condition detection module 120 , and a facility driving module 130 .

The sewage treatment module 110 is characterized in that it is formed to treat and discharge the incoming sewage.

The sewage treatment module 110 includes a sewage inlet 111, a flow rate storage tank 112, an aeration tank 113, a sludge settling tank 114, a treated water outlet 115, and a bulkhead 116.

The sewage inlet 111 is formed so that either sewage or sewage from the outside flows into the flow storage tank 112 side, and the sewage inlet 111 is formed in the upper part of one side of the sewage treatment module 110. .

The flow storage tank 112 is formed to store either sewage or sewage flowing in through the sewage inlet 111, and the flow storage tank 112 is characterized in that it is formed on one side of the Haseo treatment module.

The aeration tank 113 is formed to aerate by injecting air into any one of the sewage sewage overflowing and moving from the flow storage tank 112, and the aeration tank 113 is formed on one side of the flow storage tank 112. characterized.

The sludge precipitation tank 114 is aerated and overflows the partition wall 116 so that the sludge is settling toward the bottom, and the sludge precipitation tank 114 is formed on one side of the aeration tank 113 .

The treated water outlet 115 is formed so that the treated water formed at the upper portion of the sludge precipitation tank 114 can be discharged to the outside, and the treated water outlet 115 is formed on the other side of the upper side of the sewage treatment module 110 do it with

The partition wall 116 is formed between the flow storage tank 112 and the aeration tank 113 and between the aeration tank 113 and the sludge precipitation tank 114 so that sewage and treated water overflow according to the water level.

The facility state detection module 120 is characterized in that it is formed on one side of the sewage treatment module 110 to detect the flow rate, noise, vibration, load, and water level generated from the sewage treatment module 110 .

The facility state detection module 120 includes an air flow sensor 121 , a sewage flow sensor 122 , a noise sensor 123 , a vibration sensor 124 , a load detection sensor 125 , and a water level sensor 126 .

The air flow sensor 121 is formed to sense the flow rate of air supplied to the aeration tank 113, and the air flow sensor 121 is formed on the partition wall 116 on one side of the aeration tank 113. .

The sewage flow sensor 122 is formed to detect the amount of sewage flowing in through the sewage inlet 111, and the sewage flow sensor 122 is formed on one side of the inside of the sewage inlet 111. .

The noise sensor 123 is formed to detect noise generated by the sewage treatment module 110 , and the noise sensor 123 is formed on one side of the upper side of the sewage treatment module 110 .

The vibration sensor 124 is formed to sense vibration generated by the sewage treatment module 110 , and the vibration sensor 124 is formed on one side of the upper side of the sewage treatment module 110 .

The load sensor 125 is formed to detect a load discharged when the treated water is discharged, and the load sensor 125 is formed at one side inside the treated water outlet 115 .

The water level sensor 126 is formed to detect the water level of any one of sewage and sewage stored in the flow storage tank 112, and the water level sensor 126 is formed in the flow storage tank 112, one side bulkhead 116. characterized by being

The facility driving module 130 is formed on one side of the sewage treatment module 110 so as to receive control information from the facility management unit 140 and provide information to the sewage treatment module 110 and the facility condition detection module 120 side. do it with

The facility driving module 130 includes a sensing information transmission/reception module 131 .

The detection information transmission/reception module 131 provides real-time status information received from the facility status detection module 120 to the real-time transmission/reception module 141 side of the facility management unit 140, or a central management server unit 150 from the real-time transmission module. It is formed to receive the change and input information provided by the , and the sensing information transmission/reception module 131 is characterized in that it is formed on one side of the upper part of the sewage treatment module 110 .

The facility management unit 140 receives the facility status of the sewage treatment facility unit 100 in real time and provides it to the central management server unit 150 side.

The facility management unit 140 includes a real-time transmission/reception module 141 and a facility control module 142 .

The real-time transmission module receives change information and input information of the sewage treatment facility unit 100 from the remote location management information transmission/reception module 151 and provides it to the facility control module 142 side.

The facility control module 142 is characterized in that it receives information from the real-time transmission/reception module 141 and provides it to the sensing information transmission/reception module 131 side.

The central management server unit 150 receives and stores real-time status information of the sewage treatment facility unit 100 from the facility management unit 140, compares the stored information with preset information, and stores the failure information provided in real time, , to detect the life of the sewage treatment facility unit 100 by learning and analyzing the stored information, and transmit the control information of the sewage treatment facility unit 100 to the facility management unit 140 side so that the sewage treatment facility can be managed by the input information It is characterized in that

The central management server unit 150 includes a remote management information transmission/reception module 151, a database 152, a failure detection module 153, a learning analysis module 154, a lifespan detection module 155, a facility operation module 156. is made of

The remote location management information transmission/reception module 151 is configured to receive management information transmitted from the facility management unit 140 that has received real-time information from the corresponding sewage treatment facility unit 100 .

The database 152 is characterized in that it stores management information provided through the remote management information transmission/reception module 151 .

The failure detection module 153 analyzes failure detection information among the management information provided through the remote management information transmission/reception module 151 and stores the analyzed information in the database 152 .

The learning analysis module 154 learns and analyzes the failure information and real-time state information stored in the database 152 and stores the analyzed information in the database 152 .

The lifespan detection module 155 analyzes the lifespan according to the state information of the sewage treatment facility unit 100 learned through the learning analysis module 154 and stores it in the database 152 .

The facility operation module 156 manages the corresponding sewage treatment facility unit 100 to change or input information of the corresponding sewage treatment facility unit 100 through the life detection module 155 and the learning analysis module 154 . It is characterized in that the information is transmitted to the remote management information transmission/reception module 151 side in order to be transmitted to the facility management unit 140 side.

The manager terminal 160 is characterized in that the manager checks the real-time status information from the central management server unit 150 .

3 is a view of the sediment removal unit 200 which is another embodiment of the sewage treatment facility unit 100 of the present invention, and FIG. 4 is a detailed view of FIG. 3 .

As shown in the drawing, the sediment removal unit 200 is configured to be further included in the sewage treatment facility unit 100, and the sediment removal unit 200 is the seating of the sludge falling from the inside of the sludge precipitation tank 114 to the bottom. It is characterized in that it is formed to be discharged to the outside of the city.

The sediment removal unit 200 includes a settling plate 210 , a plate guide bar 211 , a load spring 212 , a contact sensor 213 , a contact member 214 , a vibrator 215 , and a sludge floating blocking membrane 216 . , an air pump 217 , an air injection pipe 218 , a high-pressure injection nozzle 219 , a suction pump 220 , a sludge conveying pipe 221 , and a suction member 222 .

The settling plate 210 is characterized in that it is seated and formed by a load spring 212 at a predetermined distance from the bottom surface toward the inner bottom of the sludge precipitation tank 114 .

The plate guide bar 211 supports the shaking of the settling plate 210 and is formed to support the load spring 212, and the plate guide bar 211 has one side fixed to the bottom of the sludge sedimentation tank 114, , characterized in that the other side is formed to penetrate the precipitation plate (210).

The load spring 212 is inserted into the plate guide bar 211 to support the load of the sludge seated on the sedimentation plate 210 to support the sedimentation plate 210, and the load spring 212 is formed to support the sedimentation plate 210. It is characterized in that it is formed between the plate 210 and the bottom surface of the sludge precipitation tank 114.

The contact sensor 213 is formed to detect contact with the contact member 214 when the settling plate 210 is lowered and provide the sensing information to the vibrator 215, the air pump 217, and the suction pump 220. , the contact sensor 213 is characterized in that it is formed in the lower center of the settling plate 210 .

The contact member 214 is formed so that the contact sensor 213 can be contacted and sensed, and the contact member 214 is formed in the center of the bottom surface of the sludge precipitation tank 114 .

The vibrator 215 is formed to provide vibration to the settling plate 210 by receiving sensing information from the contact sensor 213. characterized by being

The sludge flotation blocking membrane 216 is formed to block the sludge settling on the settling plate 210 from floating to the upper part of the sludge precipitation tank 114. characterized in that it is formed by

The air pump 217 is formed to generate air for moving the sludge deposited on the settling plate 210 toward the suction member 222 through the air injection nozzle 316 , and the air pump 217 is the sludge The settling tank 114 is characterized in that it is formed in the lower side.

The air injection pipe 218 is formed to move the air generated by the air pump 217 toward the high-pressure injection nozzle 219, and the air injection pipe 218 has one side connected to the air pump 217 and , the other side is characterized in that the sludge precipitation tank 114 is formed on one side.

The high-pressure injection nozzle 219 is formed to inject air toward the settling plate 210 , and the high-pressure injection nozzle 219 is formed on one side of the air injection pipe 218 .

The suction pump 220 is formed to generate a suction force for sucking the sludge moved through the high-pressure injection nozzle 219, and the suction pump 220 is formed on one side of the lower side of the sludge precipitation tank 114. do.

The sludge conveying pipe 221 is formed such that the sludge sucked through the suction member 222 is discharged to the outside by the suction force of the suction pump 220, and the sludge conveying pipe 221 has one side on the suction member 222. connected, and the other side is connected to the suction pump 220 .

The suction member 222 is formed to suck the sludge moved by air injection, and the suction member 222 is formed on one side of the sludge conveying pipe 221 .

5 is a view of an aeration amplifying unit 300 that is another embodiment of the sewage treatment facility unit 100 of the present invention, and FIG. 6 is a detailed view of FIG. 5 .

As shown in the figure, the aeration amplifying unit 300 is further included in the sewage treatment facility unit 100, and the aeration amplifying unit 300 amplifies the aeration reaction of the sewage introduced into the aeration tank 113. is characterized for

The aeration amplifying unit 300 includes a guide plate 310, a flow rate control plate 311, a control motor 312, a vortex impeller 313, an impeller motor 314, an aeration plate 315, and an air injection nozzle 316. is made of

The guide plate 310 is formed to move the inflow direction of sewage toward the center, and the guide plate 310 is formed from one side and the other side of the aeration tank 113 toward the center, respectively.

The flow control plate 311 is formed to increase or decrease the inflow speed of the sewage moving toward the center, and the flow control plate 311 is formed to be controlled by the control motor 312 on one side of the guide plate 310, respectively. characterized by being

The control motor 312 is formed to rotate the flow rate control plate 311, the control motor 312 is characterized in that formed above the flow rate control plate (311).

The vortex impeller 313 is rotated by the impeller motor 314 to generate air bubbles in the sewage to increase the oxygen concentration, and the vortex impeller 313 is a guide plate 310 and an aeration tank 113. It is characterized in that it is formed between the walls.

The impeller motor 314 is formed to be fixed to the aeration tank 113 by a support with an upper portion of the vortex impeller 313 to rotate the vortex impeller 313 .

The aeration plate 315 is formed so that sewage moving along the flow rate control plate 311 collides, and the air injection nozzle 316 is fixed so that the aeration plate 315 is formed in the aeration tank 113. It is characterized in that it is formed in the center of one side.

The air injection nozzle 316 is formed to inject air to the sewage side to which the speed is controlled and moved by the flow rate control plate 311, and the air injection nozzle 316 is formed in plurality on one side of the aeration plate 315. characterized in that

7 is a view of the bulkhead elevating unit 400, which is another embodiment for the sewage treatment facility unit 100 of the present invention.

As shown in the drawing, the bulkhead elevating unit 400 is further included in the sewage treatment facility unit 100, and the bulkhead elevating unit 400 is configured such that the bulkhead 116 rotates according to the amount of incoming sewage. It is characterized in that it is formed to be able to.

The bulkhead elevating unit 400 includes a first regulating plate 410, a first plate motor 411, a second regulating plate 412, a second plate motor 413, a water level gauge 414, a central support 415, It consists of a rotary hinge (416).

The first throttle plate 410 is formed in a first direction in one direction with respect to the central support 415 formed on the center bottom surface between the flow storage tank 112 and the aeration tank 113 and between the aeration tank 113 and the sludge precipitation tank 114 . It is formed to be rotated by driving the plate motor 411 , and the first regulating plate 410 has one side connected to the motor shaft of the first plate motor 411 , and the other side is formed on the central support 415 . It is characterized in that it is connected to the hinge 416 .

The first plate motor 411 is formed to rotate the first regulating plate 410, and the first plate motor 411 is between the flow storage tank 112 and the aeration tank 113, the aeration tank 113 and the sludge. It is characterized in that it is formed to the outside of one side between the settling tank (114).

The second throttle plate 412 is formed on the center bottom surface between the flow storage tank 112 and the aeration tank 113 and between the aeration tank 113 and the sludge precipitation tank 114 in the second direction from the other side with respect to the central support 415. It is formed to be rotated by the driving of the plate motor 413 , and the second regulating plate 412 has one side connected to the motor shaft of the second plate motor 413 , and the other side is formed on the central support 415 . It is characterized in that it is connected to the hinge 416 .

The second plate motor 413 is formed to rotate the second regulating plate 412, and the second plate motor 413 is between the flow storage tank 112 and the aeration tank 113, the aeration tank 113 and the sludge. It is characterized in that it is formed outside the other side between the settling tank (114).

The water level gauge 414 is formed to sense the water level of the sewage, and the water level gauge 414 includes a first regulating plate 410 and a second regulating plate positioned between the flow storage tank 112 and the aeration tank 113 ( 412), a plurality of first regulating plates 410 and second regulating plates 412 positioned between the aeration tank 113 and the sludge precipitation tank 114 are formed on one side.

The central support 415 is formed to support the rotation of the first regulating plate 410 and the second regulating plate 412 , and the central support 415 is a center bottom surface between the flow storage tank 112 and the aeration tank 113 . And, between the aeration tank 113 and the sludge precipitation tank 114 is characterized in that it is formed on the center bottom surface, respectively.

The rotary hinge 416 is formed such that the first adjusting plate 410 and the second adjusting plate 412 are coupled to rotate, and the rotary hinge 416 is formed above the central support 415. do.

The above-described embodiments are for illustration, and those of ordinary skill in the art to which the above-described embodiments belong can easily transform into other specific forms without changing the technical idea or essential features of the above-described embodiments. You will understand. Therefore, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and likewise components described as distributed may also be implemented in a combined form.

The scope to be protected through this specification is indicated by the claims described below rather than the above detailed description, and should be construed to include all changes or modifications derived from the meaning and scope of the claims and their equivalents. .

10: management system
100: sewage treatment facility unit 110: sewage treatment module
111: sewage inlet 112: flow storage tank
113: aeration tank 114: sludge precipitation tank
115: treated water discharge port 116: bulkhead
120: facility condition detection module 121: air flow sensor
122: sewage flow sensor 123: noise sensor
124: vibration sensor 125: load detection sensor
126: water level sensor 130: facility driving module
131: sensing information transmission/reception module 140: facility management unit
141: real-time transmission/reception module 142: facility control module
150: central management server unit 151: remote management information transmission and reception module
152: database 153: fault detection module
154: learning analysis module 155: life detection module
156: facility operation module 160: manager terminal
200: sediment removal unit 210: sedimentation plate
211: plate guide bar 212: load spring
213: contact sensor 214: contact member
215: vibrator 216: sludge floating barrier membrane
217: air pump 218: air injection pipe
219: high pressure injection nozzle 220: suction pump
221: sludge transfer pipe 222: suction member
300: aeration amplifier 310: guide plate
311: flow control plate 312: control motor
313: vortex impeller 314: impeller motor
315: aeration plate 316: air injection nozzle
400: bulkhead elevating unit 410: first control plate
411: first plate motor 412: second control plate
413: second plate motor 414: water level gauge
415: central support 416: rotary hinge

Claims (3)

In the sewage treatment facility management system for checking the situation of a sewage treatment facility located in a remote place in real time,
The sewage treatment facility management system,
a sewage treatment facility unit configured to aerate the incoming sewage to separate the sludge from the treated water to discharge the treated water; and
a facility management unit that receives the facility status of the sewage treatment facility unit in real time and provides it to the central management server unit; and
To receive and store real-time status information of the sewage treatment facility unit from the facility management unit, compare the stored information with preset information, store the failure information provided in real time, and learn and analyze the stored information to detect the lifespan of the sewage treatment facility unit and a central management server unit that transmits control information of the sewage treatment facility unit to the facility management unit so that the sewage treatment facility can be managed according to the input information; and
It consists of a manager terminal for the manager to check real-time status information from the central management server unit,
The sewage treatment facility department,
a sewage treatment module configured to treat and discharge the incoming sewage; and
a facility condition detection module formed on one side of the sewage treatment module to detect the flow rate, noise, vibration, load, and water level generated by the sewage treatment module;
It consists of a facility driving module formed on one side of the sewage treatment module to receive control information from the facility management unit and provide information to the sewage treatment module and the facility condition detection module,
The sewage treatment module,
a sewage inlet formed on one side of the sewage treatment module so that either sewage or sewage from the outside flows into the flow storage tank;
A flow storage tank formed on one side of the sewage treatment module to store either sewage or sewage flowing in through the sewage inlet;
An aeration tank formed on one side of the flow storage tank to aerate by injecting air into either sewage or sewage that overflows from the flow storage tank and moves;
A sludge precipitation tank formed on one side of the aeration tank so that the aeration overflows the bulkhead and the sludge settles toward the bottom;
a treated water discharge port formed on the other side of the upper side of the sewage treatment module so that the treated water formed at the upper part of the sludge settling tank can be discharged to the outside;
It consists of a bulkhead formed between the flow storage tank and the aeration tank and between the aeration tank and the sludge settling tank so that sewage and treated water overflow according to the water level,
The facility state detection module,
an air flow sensor formed on a bulkhead on one side of the aeration tank to detect the flow rate of air supplied to the aeration tank;
A sewage flow sensor formed on one side of the sewage inlet to detect the amount of sewage flowing in through the sewage inlet;
a noise sensor formed on one side of the upper part of the sewage treatment module to detect noise generated from the sewage treatment module;
A vibration sensor formed on one side of the upper part of the sewage treatment module to detect vibrations generated from the sewage treatment module;
A load detection sensor formed on one side of the treated water outlet to detect the load discharged when the treated water is discharged;
It consists of a water level sensor formed on the bulkhead of one side of the flow storage tank to detect the water level of either sewage or sewage stored in the flow storage tank,
The facility driving module is
Sensing information formed on the upper side of the sewage treatment module to provide real-time status information provided from the facility condition detection module to the real-time transmission/reception module side of the facility management unit, or to receive change and input information provided from the real-time transmission module to the central management server unit It consists of a sending/receiving module,
The facility management department,
a real-time transmission/reception module for receiving change information and input information from the sewage treatment facility unit from the remote site management information transmission/reception module and providing it to the facility control module;
It consists of a facility control module for receiving information from the real-time transmission/reception module and providing it to the sensing information transmission/reception module.
The central management server unit,
a remote site management information transmission/reception module for receiving management information transmitted from the facility management unit receiving real-time information from the relevant sewage treatment facility unit;
a database for storing management information provided through the remote management information transmission/reception module;
A failure detection module that analyzes failure detection information among the management information provided through the remote management information transmission/reception module and stores the analyzed information in a database;
A learning analysis module for learning and analyzing the failure information and real-time status information stored in the database and storing the analyzed information in the database;
A lifespan detection module that analyzes the lifespan according to the state information of the sewage treatment facility learned through the learning analysis module and stores it in a database;
A facility that transmits the information to the remote management information transmission/reception module side in order to transmit the information to the facility management unit that manages the relevant sewage treatment facility unit in order to change or input the information of the relevant sewage treatment facility unit through the life detection module and the learning analysis module A sewage treatment facility management system comprising an operation module.
delete The method of claim 1,
The sewage treatment facility management system,
It further comprises a sediment removal unit formed to be discharged to the outside when the sludge falling from the inside of the sludge precipitation tank to the bottom is seated,
The sediment removal unit,
A settling plate that is seated and formed by a load spring at a certain distance from the bottom to the inside of the sludge settling tank;
A plate guide bar that supports the shaking of the settling plate and has one side fixed to the bottom of the sludge settling tank to support the load spring, and the other side is formed to pass through the settling plate;
A load spring formed between the settling plate and the bottom surface of the sludge precipitator is inserted into the plate guide bar to support the load of the sludge seated on the settling plate, and
a contact sensor formed in the lower center of the settling plate to detect contact with the contact member when the settling plate is lowered and provide sensing information to the vibrator, the air pump, and the suction pump;
A contact member formed in the center of the bottom surface of the sludge precipitation tank so that the contact sensor can be contacted and detected;
a vibrator formed in plurality on one side and the other side of the lower surface of the settling plate to provide vibration to the settling plate by receiving sensing information from the contact sensor;
A sludge flotation blocking membrane formed on one side of the settling plate to prevent the sludge settling on the settling plate from floating to the top of the sludge precipitation tank;
An air pump formed on one side of the lower part of the sludge precipitation tank to generate air for moving the sludge deposited on the settling plate through the air jet nozzle toward the suction member;
An air injection pipe having one side connected to the air pump and the other side formed as one side of the sludge precipitation tank in order to move the air generated by the air pump to the high-pressure injection nozzle side;
A high-pressure injection nozzle formed on one side of the air injection pipe to inject air toward the settling plate, and
A suction pump formed on one side of the lower part of the sludge settling tank to generate a suction force for sucking the sludge moving through the high-pressure injection nozzle;
A sludge conveying pipe having one side connected to the suction member and the other side connected to the suction pump so that the sludge sucked through the suction member is discharged to the outside by the suction power of the suction pump;
Sewage treatment facility management system, characterized in that it comprises a suction member formed on one side of the sludge transfer pipe to suck the sludge moved by air jet.

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