KR101238726B1 - The system of auto monitoring control with sludge density continuous measurement - Google Patents

Abstract

PURPOSE: A long-distance automatic remote-control monitoring controller for waterworks and sewage is provided to maximize the process efficiency of a dehydrator by using a consecutive sludge density measuring device, and to reduce the electrical energy consumption and chemical costs. CONSTITUTION: A long-distance automatic remote-control monitoring controller for waterworks and sewage includes a settling basin(100), a first precipitation pond(200), an aeration basin(300), a second precipitation pond(400), a concentration basin(500), a dehydrator(600), a consecutive sludge density measuring device(700), a monitoring unit(800), and a long-distance automatic remote-control monitoring module(900) for the waterworks and sewage. The insertion time of chemicals into the dehydrator is controlled by a control signal of the long-distance automatic remote-control monitoring module. The dehydrator dehydrates high concentration sludge using the chemicals, and produces and discharges solid sludge. The consecutive sludge density measuring device continuously measures the concentration by depth and the interface of the sludge inside the first precipitation pond, the second precipitation pond, and the concentration basin. [Reference numerals] (100) Settling basin; (300) Aeration basin; (400) Second precipitation pond; (500) Concentration basin; (600) Dehydrator; (600a) Chemical container; (800) Monitoring unit; (900) Water and sewage long-distance automatic remote-control monitoring module; (AA) Hydraulic pressure; (BB) Treated water; (CC) Sludge processing process; (DD) Final treatment

Description

Automatic remote control system for water and sewage using sludge concentration continuous measuring device {THE SYSTEM OF AUTO MONITORING CONTROL WITH SLUDGE DENSITY CONTINUOUS MEASUREMENT}

The present invention can be operated remotely remotely under the control of the water and sewage remote remote automatic monitoring control module can be replaced by unskilled personnel or fully automated the process, intelligent control, the first sedimentation basin, the second By continuously measuring the concentration of sludge in the sedimentation basin and thickening tank, the accurate sludge drawing time and drawing amount can be calculated, and the operation time and operation time of the equipment (pump, valve, etc.) can be set according to the standard value. The present invention relates to an automatic water and sewage remote remote monitoring and control system using a sludge concentration continuous measuring device capable of maximizing the efficiency of dehydrator treatment by maintaining accurate amount of drawing (concentration concentration) and enabling continuous efficient injection of the proper equipment and proper amount of chemicals. .

At present, the sewage treatment system is divided into water treatment process and sludge treatment process.

For the water treatment process, a water treatment facility such as a heavy sedimentation basin, a concentration tank, and a dehydrator is configured.

The sedimentation basin, the concentration tank can not measure the concentration of the sludge in real time in a continuous operation process, there was a problem that the treatment efficiency falls.

In addition, the sludge withdrawal in the thickening tank is set and driven through the timer based on a long process operation experience.

In addition, the sludge drawn from the sedimentation basin and the concentration tank is added to the dehydrator according to the drawing amount and sent to the dehydrator so that the dehydration process or the exact drawing time and drawing amount (draw concentration) are not measured. It operates by setting cycle and time.

Accordingly, there is a problem in that the power ratio increases due to inefficient operation of the sludge drawing valve, the drawing pump, and the chemical input equipment, and the chemical input ratio is increased due to the amount of chemicals introduced.

In addition, the efficient sludge treatment is not made, and automatic operation is difficult, it is made by manual operation, there is a difficulty in the start time, end time and proper concentration maintenance, it was difficult to adjust the equipment operation time and chemical input amount.

Domestic Patent Publication No. 10-0627874 (announced on September 25, 2006)

In order to solve the above problems, the present invention continuously measures the concentration of each sludge depth of the first sedimentation basin, the second sedimentation basin, and the concentration tank, and calculates the exact sludge drawing time and the amount of drawing, and thus the equipment (pump, valve, etc.) Operation time and operation time can be set according to the standard value, and by maintaining the sludge drawing amount (draw concentration), it is possible to maximize the efficiency of dehydrator processing by precisely efficient equipment operation and continuous input of the appropriate chemical quantity, and intelligent control. This can reduce power consumption and chemical costs, and by configuring two-way wireless communication module in the sedimentation basin, the first sedimentation basin, the aeration basin, the second sedimentation basin, the condenser, the valve and the pump of the dehydrator, Automatic operation can be done remotely and remotely under the control of the supervisory control module, so it is possible to substitute unskilled personnel or to automate the entire process. To control the service, sewage far-field automatic remote monitoring control system using a continuous sludge concentration measuring device that can improve the labor costs it is an object.

Water and sewage remote remote automatic monitoring and control device using the sludge concentration continuous measuring device according to the present invention to achieve the above object

And the sedimentation paper 100 to filter out the sand or bulky waste mixed with water and sewage,

A first sedimentation basin 200 for firstly depositing and removing contaminants in water and sewage that have passed through the settling basin;

Abandonment tank (300) for removing contaminants in water and sewage not removed from the first sedimentation basin through a bioreactor,

A second sedimentation basin 400 for discharging the lumps decomposed by the microorganisms in the aeration tank and then discharging only the clear water to the treated water;

After receiving the sludge generated from the sludge of the first and second sedimentation basin, the sludge of low concentration is precipitated to produce high concentration of sludge, and then drawn out according to the control signal of the water and sewage remote remote monitoring module. Concentrating tank 500 to transfer,

The dehydrator 600, which is supplied while adjusting the amount of chemical input according to the control signal of the automatic remote control of water and sewage remote control, dehydrates the sludge of high concentration through the injected chemical and makes it into solid sludge and discharges it;

It is installed on one side of the first sedimentation basin, the second sedimentation basin and the concentration tank, and continuously measures the concentration of sludge deposited in the first sedimentation basin, the second sedimentation basin, and the concentration tank, and the sludge interface, and delivers them to the remote water and sewage remote remote monitoring control module. Sludge concentration continuous measuring apparatus 700,

A monitoring unit 800 for displaying the operation state of each device, whether the pump and the valve are on / off, the inflow of the water and the sewage, the sludge discharge, and the setting value on the screen;

Concentration by sludge depth measured from the sludge concentration continuous measuring device, connected to the sedimentation basin, the first sedimentation basin, the aeration tank, the second sedimentation basin, the thickening tank, the sludge concentration continuous measuring device, and the monitoring unit by wire / wireless communication. Wake up the sludge level in real time, calculate the sludge drawing time and drawing amount, and set the operating time and operating time of pumps and valves installed in the sedimentation basin, first sedimentation basin, aeration basin, second sedimentation basin, thickening basin It is achieved by being configured as a continuous remote control, the water and sewage remote automatic monitoring control module 900 for controlling to display the operation state of each device to the monitoring unit.

As described above, in the present invention, by continuously measuring the concentration of each sludge depth of the first sedimentation basin, the second sedimentation basin, and the concentration tank, it is possible to maximize the efficiency of dehydrator treatment by continuously inputting accurate and efficient equipment operation and appropriate chemical quantity. And intelligent control, which can reduce power consumption and chemical cost, and by constructing two-way wireless communication module in the sedimentation basin, the first sedimentation basin, the aeration basin, the second sedimentation basin, the concentration tank, the dehydrator valve and the pump, It can be operated remotely remotely under the control of the sewage remote remote automatic monitoring control module, so it is possible to substitute unskilled personnel or to automate the entire process, which can improve the labor cost by 70%.

1 is a block diagram showing the components of the automatic water and sewage remote remote monitoring and control device 1 using the sludge concentration continuous measuring apparatus according to the present invention,
2 is a block diagram showing the components of the sludge concentration continuous measuring apparatus 700 according to the present invention,
3 is a block diagram showing components of a sludge multimeter module 720 according to the present invention;
Figure 4 is a block diagram showing the configuration of a cable terminal unit, a display unit, an operation key configured on the front of the module body of the sludge multimeter module according to the present invention,
5 is an embodiment showing that the sludge multimeter module according to the present invention is installed in the first and second sedimentation basins, concentration tanks to measure the sludge concentration and the sludge interface for each depth,
6 is a block diagram showing the components of the optical sludge detection sensor 713 according to the present invention,
7 is a block diagram showing the components of the cleaning unit 714 according to the present invention,
8 is a block diagram showing components of the heater unit 715 according to the present invention;
9 is a block diagram showing the components of the sludge multimeter control unit 717 according to the present invention;
10 is a circuit diagram showing the components of the transformer of the sludge multimeter control unit according to the present invention,
11 is a block diagram showing the components of the water and sewage remote remote automatic monitoring control module 900 according to the present invention;
12 is to control the first and second sedimentation basin, concentration tank, dehydrator through the water and sewage remote remote automatic monitoring control module 900 according to the present invention, to set the on-off time, chemical injection time, dehydrator operation time of the draw valve A flow chart showing
Figure 13 is an embodiment showing the operation of the optical sludge detection sensor 723 according to the present invention,
14 is a graph illustrating a sensor measuring principle in which light scattering values are linearly measured through the optical sludge detection sensor 723 according to the present invention, and thus the concentration of suspended matter is also proportionally output.
15 is a flow chart illustrating position control of an optical sludge detection sensor through a controller in accordance with the present invention.

Far described in the present invention refers to a method of remote operation in the control station via a transmitter, a communication transmission line, a microwave or the like.

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

1 is a configuration diagram showing the components of the automatic water and sewage remote remote monitoring and control device 1 using the sludge concentration continuous measuring device according to the present invention, which is a settlement 100, the first sedimentation basin 200 , Aeration tank 300, second sedimentation basin 400, concentration tank 500, dehydrator 600, sludge concentration continuous measuring apparatus 700, monitoring unit 800, water and sewage remote remote monitoring and monitoring module 900 It consists of.

First, the sludge concentration continuous measuring apparatus 700 according to the present invention will be described.

The sludge concentration continuous measuring apparatus 700 is installed at one side of the first sedimentation basin, the second sedimentation basin, and the concentration tank, and continuously measures the concentration and the sludge interface according to the sludge depth settled in the first sedimentation basin, the second sedimentation basin, and the concentration tank. It serves to deliver sewage remote remote automatic monitoring control module.

As shown in FIG. 2, a sludge multimeter module 710 is configured.

The sludge multimeter module 710 is installed at one side of the first sedimentation basin, the second sedimentation basin, and the concentration tank, and the concentration (thickness) of each sludge depth deposited in the first sedimentation basin, the second sedimentation basin, and the concentration tank, and the sludge interface. It is to measure continuously.

As shown in FIG. 3, the module main body 711, the sensor driving control unit 712, the optical sludge detection sensor 713, the cleaning unit 714, the heater unit 715, the image monitoring unit 716, and sludge A multimeter controller 717 and a data transmitter 718 are provided.

First, the module body 711 according to the present invention will be described.

The module body 711 has a box structure, and serves to protect and support each device from external pressure.

It consists of a cable terminal part 711a, a display part 711b, and an operation key 711c.

The cable terminal part 711a is positioned at the upper front of the first module main body, and a communication cable and an input / output cable connected to the water and sewage remote automatic monitoring control module are connected to each other.

The display unit 711b is located at the bottom of the cable terminal unit, and serves to display the operation state of each device on the screen.

It consists of a TFT-LCD monitor.

The operation key 711c is located at the bottom of the display unit, and serves to input an operation signal of each device through the numeric keys and the character keys.

Second, the sensor drive control unit 712 according to the present invention will be described.

The sensor drive control unit 712 drives the optical sludge detection sensor in the vertical and vertical directions under the control of the sludge multimeter control unit, and transmits the sludge concentration and the sludge interface measurement signal to the optical sludge detection sensor as the optical sludge detection sensor, and the optical sludge. It transmits the data measured by the detection sensor to the sludge multimeter controller.

It consists of a drive motor 712a and a rotating drum 712b.

The drive motor 712a is driven under the control of the sludge multimeter controller, and serves to transmit rotational force toward the rotating drum.

The rotating drum 712b receives the rotational force from the driving motor and winds or unwinds the cable connected to the optical sludge detection sensor.

Third, the optical sludge detection processor 713 according to the present invention will be described.

The optical sludge detection sensor 713 is connected to the sensor drive control unit, and moves in the vertical and vertical directions in the first sedimentation basin, the second sedimentation basin, and the concentration tank, to the transmission signal Tx and the reception signal Rx using the laser light. By measuring MLSS [Mean Float Concentration: Mixed Liquer Suspended Solid] and the concentration of suspended solids (SS), it serves to deliver to the sensor drive control unit.

As shown in FIG. 6, an infrared LED 713b and a photodiode 713c face each other at a lower end side of the cylindrical detection sensor body 713a.

The cylindrical detection sensor body (713a) has a cylindrical shape serves to protect and support each device from external pressure.

The infrared LED 713b serves to emit light to the photodiode.

The photodiode 713c serves to detect a signal of light passing through the sludge.

Here, the infrared LED and the photodiode include a lens unit for preventing diffuse reflection and loss due to light diffusion.

A constant current circuit 713d, an IR converter 713e, an amplifier 713f, and a sensing output unit 713g are formed inside the cylindrical detection sensor body.

The constant current circuit 713d serves to supply a constant current to the infrared LED by receiving power.

The IR converter 713e converts the light received from the photodiode into an electrical signal proportional to the light intensity.

The amplifier 713f serves to amplify the electrical signal converted by the IR converter.

The sensing output unit 713g serves to transfer the electrical signal amplified by the amplifier to the sensor drive controller.

That is, when the optical sludge detection sensor is inserted and moved in the vertical and vertical directions inside the first settling basin, the second settling basin, and the concentration tank, as shown in FIGS. 13 and 14, light according to the turbidity of the sludge between the infrared LED and the photodiode. As the attenuation occurs, the greater the turbidity, the weaker the intensity of the received light and the smaller the electrical output signal.

On the contrary, the scattering value of the light is measured linearly, so that the measured concentration of the suspended matter is also output proportionally.

At this time, the electrical output signal is amplified to detect the boundary of the sudden extraction signal as the sludge layer.

Subsequently, when the sludge layer is detected, the MLSS (Average Flour Concentration: Mixed Liquer Suspended Solid) and the suspended solids (SS) concentration are measured based on the sludge layer.

In addition, the optical sludge detection sensor 713 according to the present invention, the limit switch for detecting the current position of the sensor located in the first sedimentation basin, the second sedimentation basin, the concentration tank on one side of the infrared LED 713b and one side of the photodiode 713c. It is configured to include.

Fourth, a description will be given of the cleaning unit 714 according to the present invention.

The cleaning unit 714 is located on one side of the sensor drive control unit and positioned so that the optical sludge detection sensor is included therein, and the foreign matter introduced into the optical sludge detection sensor is mixed with a spray of water / air. Serves to clean.

As illustrated in FIG. 7, a plurality of cleaning device bodies 714a formed in a cylindrical shape to include an optical sludge detection sensor therein and a plurality of water / air (around the periphery of the bottom surface of the cleaning device body) are formed. Mixing sprayer 714b for high pressure spraying with optical sludge detection sensor, Clean PVC pipe 714c for delivering Water / air to the mixing sprayer, and Water / A water / air pump 714d for supplying air (air) is configured.

Since the cleaning unit according to the present invention has a high concentration of about 10% of the highest concentration of sludge attached to the optical sludge detection sensor, the cleaning unit is configured to clean while adjusting the cleaning pressure and the spray angle through the mixing sprayer.

That is, the washing pressure is set at about 2 kgf / cm 2, and the spray angle is set at about 20 ° to 60 °.

Fifth, the heater unit 725 according to the present invention will be described.

The heater unit 725 is located at one side of the sensor drive control unit and serves to thaw the surface of the frozen first settling basin, the second settling basin, and the concentration tank during the winter season.

As shown in FIG. 8, the heater body 715a having a box shape and a heater generator 715b configured inside the heater body to generate heat toward the heater body are provided.

Here, the heater generator is configured by selecting any one of a radiator or a thermoelectric element.

The heater unit according to the present invention is equipped with a temperature sensor on one side so that the heater generator is automatically driven when the air temperature drops below zero.

In addition, a heating controller is configured inside the heater to adjust the heating strength.

Sixth, the image monitoring unit 716 according to the present invention will be described.

The image monitoring unit 716 is located at the inner lower end of the second module main body and moves in the vertical up and down direction inside the first sedimentation basin, the second sedimentation basin, and the concentration tank, similarly to the optical sludge detection sensor, and the driving state of the optical sludge detection sensor. And monitoring the water quality of the first settling basin, the second settling basin, and the concentration tank.

It is located on the surface of the water and configured to monitor the driving state of the optical sludge detection sensor and the water quality of the first sedimentation basin, the second sedimentation basin, and the concentration tank.

The image surveillance unit compresses the captured image data in the JPEG method, and transmits still image data of 1/10/10 seconds to the data transmission unit 718.

Seventh, the sludge multimeter controller 717 according to the present invention will be described.

The sludge multimeter controller 717 is located inside the second module main body, and is connected to a sensor driving controller, an optical sludge detection sensor, a cleaning unit, a heater unit, and an image monitoring unit to control the overall operation of each device, and Sludge concentration and sludge interface measurement signals are transmitted to the drive control unit, and data processing signals are received accordingly, and data on the sludge concentration and sludge interface detected from the optical sludge detection sensor are transmitted to the remote water and sewage remote automatic monitoring control module. And display the operation state of each device on the second display unit.

As shown in FIG. 9, it is comprised of the converter 717a, the controller 717b, and the transformer 717c.

The converter 717a provides a color graphical LCD user interface to the client and serves to process control commands to each controller.

This controls calibration, communication setting and error detection parameter setting, and converts the sludge concentration and sludge interface measurement signals transmitted from the sensor drive controller to be displayed on the display by the GUI.

The transducer calibrates the measured sludge concentration and the sludge interfacial data calibration criteria in a multi-point calibration scheme with up to five points.

That is, it is configured to calibrate to 0.10, 20mg / L when calibrating SS measurement data, 0.5, 2.4% when calibrating sludge concentration measurement data, the total measurement concentration range is 0 ~ 4%, the maximum error within 4%.

The controller 717b serves to control the sensor drive controller for position control of the optical sludge detection sensor.

It has a function of length detection and departure prevention, and serves as a heater control and fan control for temperature control.

The position control of the optical sludge detection sensor through the controller is programmed in the following order.

[Optical Formula Sludge  Position Control of Detection Sensor]

That is, as shown in Fig. 15, in the state of initializing the system, the sludge interfacial measurement mode is driven (S10).

Subsequently, the current position of the optical sludge detection sensor located in the first sedimentation basin, the second sedimentation basin, and the concentration tank is determined (S20). Here, the current position is detected via the limit switch.

Subsequently, when the current position of the optical sludge detection sensor located in the first sedimentation basin, the second sedimentation basin, and the concentration tank is detected, the current position of the optical sludge detection sensor is transmitted to the data transmission unit (S30).

Subsequently, an optical sludge detection sensor is moved vertically and vertically by driving the sensor drive controller (S40).

Finally, after determining the current position of the optical sludge detection sensor located in the first sedimentation basin, the second sedimentation basin, and the concentration tank, if the first sedimentation basin, the second sedimentation basin, the bottom surface of the concentration tank, the sludge interface measurement is completed (S50).

The transformer 717c converts an AC power input into a DC to supply power to each device.

As shown in FIG. 10, the noise filter unit 717c-1 is included on the AC power input side.

Eighth, the data transmission unit 718 according to the present invention will be described.

The data transmission unit 718 is driven under the control of the sludge multimeter module to transmit data on the sludge concentration and the sludge interface calculated by the sludge multimeter module to the water and sewage remote remote automatic monitoring control module through a wired / wireless communication network. Play a role.

It consists of wired and wireless communication modules.

Here, the wire / wireless communication module connects the water and sewage remote remote automatic monitoring control module and the sludge multimeter module to the wired and wireless communication network to receive a control signal from the water and sewage remote remote automatic monitoring control module and transmit a response signal accordingly. Play a role.

It is composed of any one selected from the infrared communication module, RF communication module, ultrasonic communication module, RS232 communication module.

Next, the settlement paper 100 according to the present invention will be described.

The settling paper 100 serves to filter out sand or bulky waste mixed with water and sewage.

It is made of a rectangular sedimentation structure, the inlet pipe is formed in which water and sewage flow into one side, and the discharge pipe is discharged to discharge the water and sewage filtered out sand or bulky waste on the other side.

One side of the discharge pipe is configured to be connected to the first sedimentation basin.

The inflow pipe 110 has a first solenoid valve 111 for opening and closing water and sewage flowing into the sedimentation basin according to a switch control signal of the water and sewage remote remote automatic monitoring control module on one side thereof. It is composed.

The discharge line 120 is a second solenoid valve 121 for opening and closing the water and sewage flowing into the first sedimentation basin in accordance with a switch control signal of the water and sewage remote remote automatic monitoring control module on one side. ) Is configured.

Next, the first settler 200 according to the present invention will be described.

The first sedimentation basin 200 serves to firstly remove and remove contaminants in water and sewage that have passed through the settling basin.

It is made of a rectangular sedimentary structure, the discharge pipe 120 for transporting the water and sewage filtered to the sedimentation basin is formed on one side, the first to transfer the water and sewage from which the pollutant is first removed to the aeration tank to the other side A transfer pipe 220 is formed, and a second transfer pipe 230 for transferring the contaminants deposited on one side of the bottom to the concentration tank is formed.

The first conveying pipe 220 is a third solenoid valve for opening and closing the water and sewage, which is first removed by aeration tank according to the switch control signal of the water and sewage remote remote automatic control module on one side. 221 is configured.

The second conveying pipe 230 is a fourth solenoid valve 231 for opening and closing contaminants precipitated in the concentration tank in accordance with a switch control signal of the water and sewage remote automatic monitoring control module on one side. Is composed.

The second conveying pipe 230 is driven in accordance with the pump driving signal of the water and sewage remote automatic monitoring control module on one side of the floor entrance, the first to suck the precipitated pollutants through the fifth solenoid valve to discharge to the concentration tank. Suction pump 232 is configured.

Next, the aeration tank 300 according to the present invention will be described.

The aeration tank 300 serves to remove contaminants in the water and sewage not removed from the first sedimentation basin through a bioreactor.

It consists of a rectangular aeration structure, is formed by connecting the first conveying pipe 230 for introducing the water and sewage filtered from the first sedimentation basin to the aeration tank on one side, the water and sewage removed through the bioreactor in the aeration tank on the other side The third conveying pipe 310 is formed to transfer the to the second sedimentation basin, the remaining water and sewage of the contaminants sedimented in the second sedimentation basin on the bottom side flows into the aeration again, the fourth to convey the contaminants to the concentration tank. Transfer pipe 320 is formed.

The third conveying pipe 310 opens and closes the water and sewage removed through the bioreactor from the aeration tank to the second sedimentation basin according to a switch control signal of the water and sewage remote automatic monitoring control module on one side. A fifth solenoid valve 311 is configured.

The fourth conveying pipe 320 sends a contaminant that has sunk in the second sedimentation basin to the concentration tank according to a switch control signal of the water and sewage remote automatic monitoring control module on one side, and sends the remaining water and sewage out of the contaminant back to the aeration tank. A sixth solenoid valve 321 is configured to open and close to send.

Next, a second settling basin 400 according to the present invention will be described.

The second sedimentation basin 400 serves to discharge only the clear water to the treated water after the secondary precipitates are removed by sedimentation by the microorganisms in the aeration tank.

It consists of a rectangular sedimentation structure, and is formed by connecting a third transfer pipe 310 for introducing the water and sewage filtered from the aeration tank to one side of the second sedimentation basin on one side, and the sewage and sewage removed by sedimentation in the second sedimentation basin on the other side. The fifth transfer pipe 410 is formed to transfer to the treated water, the remaining water, sewage of the contaminants seized on one side of the bottom flows into the aeration again, and the fourth transfer pipe 320 for transferring the contaminants to the concentration tank. It is connected and formed.

The fifth conveying pipe 410 is the one to open and close the water and sewage removed from the second sedimentation basin with the treated water in accordance with the switch control signal of the water and sewage remote automatic monitoring control module on one side. 7 solenoid valve 411 is configured.

The second sedimentation basin is driven in accordance with the pump driving signal of the water and sewage remote automatic monitoring control module at one side of the floor entrance, and a second suction pump 412 for sucking the precipitated contaminants and discharging them through the sixth solenoid valve to the concentration tank. ) Is configured.

Next, the concentration tank 500 according to the present invention will be described.

The thickening tank 500 receives the sludge generated from the sludge of the first and second sedimentation basin, precipitates the sludge of low concentration to produce a high concentration of sludge, and then to the control signal of the remote water and sewage remote automatic monitoring control module It draws along and transfers it to the dehydrator.

It consists of a rectangular thickening structure, is formed by connecting the second transfer pipe 230 for transferring the contaminant filtered from the first sedimentation basin on one side to the concentration tank, the contaminant filtered from the second sedimentation basin on one side of the third transfer pipe The fourth conveying pipe 320 to be transferred to the thickening tank is connected and formed, the sixth conveying pipe 510 for transferring the high concentration sludge to the dehydrator is formed on one side of the bottom.

The sixth conveying pipe 510 has a drawing valve 511 configured to open and close a high concentration of sludge drawn into the dehydrator according to a switch control signal of a water and sewage remote automatic monitoring control module on one side. do.

The concentrating tank is driven according to the pump driving signal of the water and sewage remote remote automatic monitoring control module at one side of the bottom entrance, and the drawing pump 512 is configured to draw high concentration sludge and discharge it to the dehydrator through a drawing valve.

Here, the sludge drawing point and the drawing amount of the drawing valve and the drawing pump are made under the control of the water and sewage remote remote automatic monitoring control module.

And, the sewage remote remote automatic monitoring control module receives the sludge concentration and sludge level measured in real time from the sludge concentration continuous measuring device, and calculates the sludge drawing time and drawing amount as shown in FIG. .

Next, the dehydrator 600 according to the present invention will be described.

The dehydrator 600 is supplied while the amount of chemical input is adjusted according to the control signal of the water and sewage remote remote automatic monitoring control module, and serves to discharge the sludge of high concentration through the injected chemical to make solid sludge and discharge it. .

It is formed by connecting the sixth conveying pipe 510 for transferring the high concentration sludge discharged from the concentration tank to the dehydrator on one side, the discharge port 610 for discharging the solid sludge dewatered from the dehydrator to the outside is formed, the upper one side A seventh transfer pipe 620 is formed to transfer the medicine supplied from the chemical storage tank unit to the dehydrator.

The seventh conveying pipe 620 is an eighth to open and close the chemical supply of the chemical supply tank 600a with a dehydrator in accordance with a switch control signal of the water and sewage remote automatic monitoring control module on one side. Solenoid valve 621 is configured.

Here, the chemical supply point and the chemical amount of the eighth solenoid valve are made under the control of the water and sewage remote remote monitoring module.

And, as shown in Fig. 2, the automatic remote control system for water and sewage receiving the sludge depth and sludge level measured in real time from the sludge concentration continuous measuring device, and supplying the chemical supply time point and the chemical quantity to the dehydrator. Calculate

Next, the monitoring unit 800 according to the present invention will be described.

The monitoring unit 800 serves to display the operation state of each device, whether the pump and valve on / off operation, the inflow of the water and sewage, the sludge discharge, the setting value on the screen.

Next, the water and sewage remote remote automatic monitoring control module 900 according to the present invention will be described.

The water and sewage remote remote automatic monitoring control module 900 is connected to the sedimentation basin, the first sedimentation basin, the aeration basin, the second sedimentation basin, the concentration tank, the sludge concentration continuous measuring device, the monitoring unit and the wired / wireless communication to monitor each device remotely and remotely. While receiving the sludge depth and sludge level measured from the sludge concentration continuous measuring device in real time, the sludge drawing time and the amount of drawing is calculated, and according to the sedimentation basin, the first sedimentation basin, the aeration basin, the second sedimentation basin, and the concentration tank. It continuously controls to set and output the operation time and operation time of the installed pump and valve, and it controls to display the operation status of each device in the monitoring unit.

As shown in FIG. 11, the CPU includes a central processing unit (CPU) 910, an input / output unit 920, and a power supply unit 930.

The CPU 910 receives sludge concentration and sludge level measured in real time from the sludge concentration continuous measuring device, and calculates sludge drawing time and drawing amount, as shown in FIG. The continuous control to set and output the operating time and operating time of the pump and valves installed in the sedimentation basin, the first sedimentation basin, the aeration basin, the second sedimentation basin, the concentration tank, and the program control to display the operation status of each device in the monitoring unit. Play a role.

The input / output unit 920 is connected to the first, second, third, fourth, fifth, sixth, seventh solenoid valve, the first and second suction pumps, the drawing valve, the drawing pump, the temperature sensor, and the optical sludge detection sensor at the input side. It receives the sensor value and transmits it to the CPU, and outputs the control command of the CPU to the sedimentation basin, the first sedimentation basin, the aeration basin, the second sedimentation basin, the concentration tank, the dehydrator, the sludge concentration continuous measurement device, and the monitoring unit connected to the output side. Play a role.

The photocoupler is configured such that noise from an external device is not transmitted to the CPU, and the LED module is configured to display each contact state of input and output.

The power supply unit 930 serves to supply power to each device.

Hereinafter, a detailed operation process of the automatic water and sewage remote remote monitoring and control system using the sludge concentration continuous measuring apparatus according to the present invention will be described.

First, filter out the sand or bulky trash mixed with water and sewage from the settlement 100.

Next, in the first sedimentation basin 200, the contaminants in the water and sewage passing through the settling basin are first precipitated and removed.

Next, through the sludge concentration continuous measuring device installed in the first sedimentation basin, the concentration of sludge settled in the first sedimentation basin, the sludge interface is continuously measured and transmitted to the remote water and sewage remote automatic monitoring control module.

Here, the sludge concentration continuous measuring device is composed of a sludge multimeter module.

The sludge multimeter module moves through the optical sludge detection sensor to the first sedimentation basin and vertically in the vertical direction, and transmits the sludge depth and the sludge interface by the transmission signal Tx and the reception signal Rx using laser light. Measure continuously.

Next, the contaminants in the water and sewage that are not removed from the first sedimentation basin in the aeration tank 300 are removed through the bioreactor.

Next, after the second settled basin (400) to remove the lumps decomposed by the microorganisms in the aeration tank secondary, only the clear water is discharged to the treated water.

Next, through the sludge concentration continuous measurement device installed in the second sedimentation basin, the concentration of sludge deposited in the second sedimentation basin, and the sludge interface are continuously measured and transmitted to the remote water and sewage remote automatic monitoring control module.

Here, the sludge concentration continuous measuring device is composed of a sludge multimeter module.

As shown in FIG. 12, the sludge multimeter module moves vertically and vertically in the second sedimentation basin through an optical sludge detection sensor and is transmitted by a transmission signal Tx and a reception signal Rx using laser light. The sludge concentration and sludge interface are measured continuously.

Next, by receiving the sludge generated in the sludge of the first and second sedimentation basin in the concentration tank 500, to precipitate the sludge of low concentration to generate a high concentration of sludge, the control of automatic remote control of water and sewage remote Draw according to the signal and transfer to the dehydrator.

At this time, the sewage remote remote automatic monitoring control module receives sludge concentration and sludge level measured in real time from the sludge concentration continuous measuring device, calculates sludge drawing time and drawing amount, and then calculates sludge drawing time And a drawing valve and a drawing pump of the thickening tank according to the drawing amount.

Here, the sludge concentration continuous measuring device is composed of a sludge multimeter module.

The sludge multimeter module continuously moves the sludge depth and sludge interface by the transmission signal (Tx) and the reception signal (Rx) using laser light while moving vertically in the concentration tank through the optical sludge detection sensor. Measure

Next, the dehydrator 600 is controlled while the chemical quantity input time is adjusted according to the control signal of the water and sewage remote remote automatic monitoring control module, and the sludge of high concentration is dehydrated through the injected chemicals to make solid sludge and discharged.

Finally, the monitoring unit 800 displays the operation state of each device, whether the pump and valve on / off operation, the inflow of the water and sewage, the sludge discharge, the setting value on the screen.

Through this process, in the present invention by continuously measuring the concentration of the sludge depth of the first sedimentation basin, the second sedimentation basin, the concentration tank, the accurate sludge drawing time and the amount of drawing is calculated, and the operation of the equipment (pump, valve, etc.) accordingly The timing and operation time can be set according to the standard value, and by maintaining the sludge drawing amount (draw concentration), it is possible to maximize the efficiency of dehydrator treatment by continually inputting accurate and efficient equipment operation and appropriate chemical quantity, and thus consuming power. And drug costs can be reduced.

1: Water and sewage remote remote automatic monitoring and control device 100: Settlement site
200: first settler 300: aeration tank
400: second sedimentation basin 500: concentration tank
600: Dehydrator
700: sludge concentration continuous measuring device 800: monitoring unit
900: automatic remote control of water and sewage remote control

Claims (8)

And the sedimentation paper 100 to filter out the sand or bulky waste mixed with water and sewage,
A first sedimentation basin 200 for firstly depositing and removing contaminants in water and sewage that have passed through the settling basin;
Abandonment tank (300) for removing contaminants in water and sewage not removed from the first sedimentation basin through a bioreactor,
A second sedimentation basin 400 for discharging the lumps decomposed by the microorganisms in the aeration tank and then discharging only the clear water to the treated water;
The sludge generated from the sludges of the first and second sedimentation basins is applied, and the sludges of low concentrations are precipitated to produce high concentrations of sludges, which are drawn according to the control signals of the remote water and sewage remote remote monitoring and control module to the dehydrator. Thickening tank 500,
The dehydrator 600, which is supplied while adjusting the amount of chemical input according to the control signal of the automatic remote control of water and sewage remote control, dehydrates the sludge of high concentration through the injected chemical and makes it into solid sludge and discharges it;
It is installed on one side of the first sedimentation basin, the second sedimentation basin and the concentration tank, and continuously measures the concentration of sludge deposited in the first sedimentation basin, the second sedimentation basin, and the concentration tank, and the sludge interface, and delivers them to the remote water and sewage remote remote monitoring control module. Sludge concentration continuous measuring apparatus 700,
A monitoring unit 800 for displaying the operation state of each device, whether the pump and the valve are on / off, the inflow of the water and the sewage, the sludge discharge, and the setting value on the screen;
Concentration by sludge depth measured from the sludge concentration continuous measuring device, connected to the sedimentation basin, the first sedimentation basin, the aeration tank, the second sedimentation basin, the thickening tank, the sludge concentration continuous measuring device, and the monitoring unit by wire / wireless communication. And, receives the sludge interface in real time, calculates the sludge drawing time and the amount of drawing, and set the operating time and operating time of the pump and valve installed in the settling basin, first settling basin, aeration tank, second settling basin, thickening tank according to the output Continuous sewage and remote sewage and sewage remote using a sludge concentration continuous measuring device, characterized in that it consists of a water and sewage remote remote automatic monitoring control module 900 for controlling to display the operation status of each device to the monitoring unit. Automatic Surveillance Control System.
According to claim 1, The sludge concentration continuous measuring apparatus 700
Sludge Multimeter Module installed on one side of the first sedimentation basin, the second sedimentation basin, and the concentration of the sludge depth (thickness) and sludge interface deposited in the first sedimentation basin, the second sedimentation basin, and the concentration basin. Water and sewage remote remote monitoring system using a sludge concentration continuous measuring device, characterized in that consisting of (710).
The sludge multimeter module 710 of claim 2, wherein
A second module body 711 formed of a box structure to protect and support each device from external pressure;
Under the control of the sludge multimeter controller, the optical sludge detection sensor is driven vertically and vertically, the sludge concentration and sludge interface measurement signals are transmitted to the optical sludge detection sensor by the optical sludge detection sensor, and the data measured by the optical sludge detection sensor is transferred. A sensor drive controller 712 for transmitting to the multi-meta controller,
Connected to the sensor drive control unit, while moving vertically up and down inside the first sedimentation basin, the second sedimentation basin, the concentration tank, MLSS [Average Float Concentration: Mixed Liquer] by the transmission signal (Tx) and the reception signal (Rx) using laser light. Suspended Solid], and an optical sludge detection sensor 713 measuring the suspended solids (SS) concentration and then transmitting the suspended solids (SS) to the sensor drive controller.
The cleaning unit 714, which is located on one side of the sensor drive control unit and cleans the foreign substances introduced into the optical sludge detection sensor by mixing spraying of water / air, with the optical sludge detection sensor positioned therein. Wow,
Located on one side of the sensor drive control unit, the heater unit 715 for thawing the surface of the frozen first sedimentation basin, the second sedimentation basin, the concentration tank during the winter season,
Located in the inner lower end of the second module body and moving in the vertical up and down direction in the first sedimentation basin, the second sedimentation basin, the concentration tank in the same manner as the optical sludge detection sensor, the driving state of the optical sludge detection sensor and the first sedimentation basin, the second sedimentation basin And a video surveillance unit 716 for monitoring the quality of the water in the concentration tank,
Located inside the second module body, connected to the sensor drive control unit, optical sludge detection sensor, cleaning unit, heater unit, image monitoring unit, to control the overall operation of each device, the sensor drive control unit to measure the sludge concentration and sludge interface It transmits the signal, receives the data processing signal accordingly, and transmits the sludge concentration and the sludge interface detected by the optical sludge detection sensor to the water and sewage remote remote automatic monitoring control module. 2, a sludge multimeter controller 717 for controlling the display to be displayed on the display unit;
A second data transmission unit 718 driven under the control of the sludge multimeter module to transmit data on the sludge concentration and the sludge interface calculated by the sludge multimeter module to the water and sewage remote automatic monitoring control module through a wired or wireless communication network. Water and sewage remote remote monitoring system using a sludge concentration continuous measuring device, characterized in that consisting of.
The method of claim 3, wherein the optical sludge detection sensor 713 is
An infrared LED 713b and a photodiode 713c face each other at a lower side of the cylindrical detection sensor body 713a, and a constant current circuit 713d for supplying a constant current to the infrared LED by applying power to the inside of the cylindrical detection sensor body. ), An IR converter 713e for converting the light received from the photodiode into an electrical signal proportional to the light intensity, an amplifier 713f for amplifying the electrical signal converted by the IR converter, and amplification in the amplifier. Water and sewage remote automatic monitoring and control device using the sludge concentration continuous measuring device, characterized in that it consists of a sensing output unit (713g) for transmitting the electrical signal to the sensor drive control unit.
The method of claim 3, wherein the cleaning unit 714 is
A washing machine body 714a having a cylindrical shape to include an optical sludge detection sensor therein;
A mixing sprayer 714b formed in plural along the bottom surface of the washing machine body and spraying with a high pressure sludge detection sensor with water / air;
Clean PVC pipe 714c for delivering Water / air to the mixing sprayer,
Water and sewage remote remote monitoring system using a sludge concentration continuous measuring device, characterized in that consisting of a water / air pump (714d) for supplying water (air) / air (air) to the clean PVC pipe.
The sludge multimeter controller 717 of claim 3, wherein
A converter 717a which provides the client with a color graphical LCD user interface and processes control commands to each controller;
A controller 717b for controlling a sensor drive controller for position control of an optical sludge detection sensor;
Water and sewage remote automatic monitoring and control device using a sludge concentration continuous measuring device, characterized by comprising a transformer (717c) for switching the AC power input to DC to supply power to each device.
7. The transducer of claim 6, wherein the transducer 717a
Sludge concentration continuous using the sludge concentration continuous measurement device, characterized in that configured to calibrate the measured sludge concentration and the sludge interface data calibration standard using a multi-point calibration method that uses up to 5 points. Remote automatic surveillance control device.
The method of claim 1, wherein the water and sewage remote remote automatic monitoring control module 900 is
Sludge Concentration The sludge depth and sludge level are received in real time, and the sludge drawing time and drawing amount are calculated, and the pumps are installed in the settling basin, the first settling basin, the second settling basin, and the second settling basin. And a central processing unit (CPU) 910 for continuously controlling to set and output the operation time and the operating time of the valve, and for controlling the program to display the operation state of each device in the monitoring unit.
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 solenoid valve, 1, 2 suction pump, drawing valve, drawing pump, temperature sensor, optical sludge detection sensor It receives the measured sensor value and transfers it to the CPU, and outputs CPU control command to the sedimentation basin, first sedimentation basin, aeration basin, second sedimentation basin, thickening tank, dehydrator, sludge concentration continuous measuring device connected to the output side, and monitoring unit. I / O unit 920 to make,
Water and sewage remote automatic monitoring and control device using the sludge concentration continuous measuring device, characterized in that the power supply unit 930 for supplying power to each device.

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