KR102381871B1 - Apparatus and method for producing mud and treating waste mud in mud circulation system - Google Patents

Abstract

The present invention relates to an apparatus and a method for manufacturing mud and treating waste mud of a mud circulation system, and specifically to the apparatus and method for manufacturing mud and treating waste mud of a mud circulation system, collecting sensor data from sensors installed in each equipment of a mud circulation system, and based on the same, automatically controlling the equipment for manufacturing mud and treating waste mud, thereby capable of preventing manpower accidents at a drilling site, and performing objectified management to match set characteristics. The apparatus for manufacturing mud and waste mud in a mud circulation system comprises: an operating condition setting unit; a shale shaker vibration detection unit; a flow rate sensing unit inside a pipe; a pressure sensing unit inside a pipe; a barite weight sensing unit; a bentonite weight sensing unit; a fluid level detection unit in a tank; a fluid density sensing unit in the pipe; a PLC control unit; a barite supply motor; a bentonite feeding motor; an in-tank fluid mixing device driving motor; an in-tank fluid mixing device driving motor; and a fluid control valve.

Description

Apparatus and method for producing wastewater and wastewater treatment in a wastewater circulation system

The present invention relates to a wastewater production and waste wastewater treatment apparatus and method for a wastewater circulation system, and more particularly, to collect sensor data from sensors installed in each equipment of the wastewater circulation system, and to provide equipment for wastewater production and wastewater treatment based on this It relates to an apparatus and method for producing wastewater and wastewater treatment of a wastewater circulation system, which can be controlled automatically to prevent human accidents at the drilling site and can be managed objectively according to set characteristics.

A drilling device for digging a hole into the ground to explore underground resources on the seabed or land or to investigate the structure/state of a stratum is a drilling device for rock or sand by drilling fluid such as drilling mud supplied through a drill pipe. Allow the perforation to be performed. Here, in the process of connecting or disconnecting the drill pipe to the drilling device to install or replace the drill pipe, mud is continuously injected to keep the internal and external pressure of the drill string constant. This is to keep the cuttings moving so that they do not accumulate in the well. The mud pump is circulated in the drilling device by inducing the operation of the mud pump throughout the drilling process including the connection/disconnection of the drill pipe.

The water circulation system includes a solid control system and a treatment system. The solids control system includes a bulk system for storing and transporting the diluent material and a mixing system for mixing the diluent material and preventing settling. The foreign material removal system serves to remove the foreign material contained in the waste water.

Such a water circulation system includes a load cell that checks the weight, intake and discharge amount of the hopper, a level sensor to check the height in case of a load cell failure, a pressure sensor to check the filter status, and a pressure to check the fluid pressure in and out of the mixer. pressure sensor for mud tank level check, pressure sensor for jet gun pressure status check, flow meter for water circulation, density sensor to check water density, for fault diagnosis of foreign material removal system and equipment status check Sensors for predicting equipment failure, such as vibration sensors, pressure sensors for checking the condition of a degasser tank, and flow meters for checking the amount of centrifuge input, are used.

However, the conventional waste water circulation system has a function of notifying equipment failure when it exceeds or falls below a set value by analyzing sensor data provided from sensors, and produces waste water or processes waste water in the waste water circulation system. No mention was made of a technology that can automatically perform the process.

Publication of domestic patent registration No. 1959829 (Registration date: March 13, 2019)

Therefore, the present invention has been made in consideration of the above points, and an object of the present invention is to prevent manpower accidents at the drilling site and set characteristics by automating the process of producing mud and treating waste water in the mud water circulation system. It is to provide an apparatus and method for producing wastewater and wastewater treatment of a wastewater circulation system, which can be managed objectively to meet the requirements of the present invention.

In order to achieve the above object, the wastewater production and waste wastewater treatment apparatus of the wastewater circulation system according to an embodiment of the present invention produces wastewater in the wastewater circulation system and reprocesses wastewater obtained after the produced wastewater is used in a drilling process. An apparatus for producing waste water and waste water for a waste water circulation system, comprising: an operating condition setting unit configured to set operating conditions of the waste water circulation system; a shale shaker vibration sensing unit configured to sense vibration of a shale shaker that removes foreign substances contained in waste water; a pipe internal flow rate sensing unit configured to detect a flow velocity inside the pipe of the mixed water circulation system; a pipe internal pressure sensing unit configured to sense a pressure inside the pipe of the mixed water circulation system; a barite weight detection unit configured to measure the weight of barite loaded inside the barite hopper; a bentonite weight sensing unit configured to measure the weight of the bentonite loaded inside the bentonite hopper; a fluid level sensing unit in the tank configured to measure a fluid level in the water tank, the mixing tank, and the waste water reprocessing tank; a fluid density sensor in the pipe configured to detect the density of the fluid in the inlet pipe of the mixing tank; The operating conditions set by the operating condition setting unit, the shale shaker vibration sensing unit, the pipe internal flow rate sensing unit, the pipe internal pressure sensing unit, the barite weight sensing unit, the bentonite weight sensing unit, the fluid level sensing unit in the tank and the pipe PLC control unit configured to output a control signal by sequentially logical processing by a program stored therein based on the sensing signal input from the fluid density sensing unit; a bar light supply motor configured to receive a control signal from the PLC control unit and driven to generate a driving force for transmitting bar light from the bar light hopper to the mixing tank; a bentonite supply motor configured to receive a control signal from the PLC control unit and driven to generate a driving force for transferring the bentonite from the bentonite hopper to the mixing tank; a fluid mixing device driving motor in the waste water reprocessing tank configured to receive a control signal from the PLC controller and driven to provide a driving force to the fluid mixing device in the waste water reprocessing tank; a fluid mixing device driving motor in the mixing tank configured to receive a control signal from the PLC controller and driven to provide a driving force to the fluid mixing device in the mixing tank; a fluid circulation pump driving motor configured to receive a control signal from the PLC control unit and driven to provide a driving force to the fluid circulation pump that circulates the fluid in the water circulation system; a shale shaker driving motor configured to receive a control signal from the PLC controller and driven to provide a driving force to the shale shaker; a degasser driving motor configured to receive a control signal from the PLC control unit and drive it to provide a driving force to a degasser that removes harmful gas generated during drilling; a dust collector fan driving motor configured to receive a control signal from the PLC controller and drive it to provide a driving force to a dust collector that removes airborne particulates generated in the water circulation system; a barite hopper and bentonite hopper air supply valve configured to receive a control signal from the PLC control unit and to control the air supply to the barite hopper and bentonite hopper; and a fluid control valve that is driven by receiving a control signal from the PLC control unit to regulate the flow of fluid in the pipe in the water drainage system.

In the waste water production and waste water treatment apparatus of the waste water circulation system according to the above embodiment, the PLC controller obtains flow rate information by multiplying the flow rate information sensed by the flow rate sensor inside the pipe by the fluid passage and the cross-sectional area of the pipe, It may be further configured to calculate the dilution viscosity using the following [Equation 1] based on the flow rate information.

[Equation 1]

In order to achieve the above object, a method for producing muddy water of a mudwater circulation system according to another embodiment of the present invention includes a density and viscosity setting step in which a target mudwater density and viscosity are set by an operating condition setting unit; a mixing tank selection step in which a mixing tank to be produced is selected by the operation condition setting unit; a target water level fresh water supply step in which a PLC controller controls a fluid circulation pump driving motor and a fluid control valve to supply fresh water of a target water level from a water tank to the selected mixing tank; a work pre-state check step of the PLC control unit checking the work pre-state of the water circulation system equipment to determine whether it is normal; an air supply step in which the PLC control unit opens the barite hopper and bentonite hopper air supply valves to prevent aggregation of barite and bentonite by air when the pre-work state is normal; The PLC control unit drives the barite supply motor and the bentonite supply motor, and controls the fluid circulation pump driving motor and the fluid control valve to set a bulk supply line for supplying the barite and bentonite to the selected mixing tank. feeding step; a fluid mixing step in which the PLC controller drives a fluid mixing device driving motor in the mixing tank to mix the fluid in the selected mixing tank; The PLC control unit detects the flow rate inside the pipe of the dilution circulation system through the pipe internal flow rate sensing unit, obtains the flow rate by multiplying the flow rate by the fluid passage and the cross-sectional area of the pipe, and calculates the dilution viscosity based on the flow rate; a mixing density sensing step in which the PLC control unit detects the mixing density inside the pipe through the pipe internal pressure sensing unit; a target muddy viscosity and density determining step in which the PLC control unit determines whether the muddy viscosity and the muddy density have reached the target muddy density and viscosity; and when the muddy viscosity and the muddy viscosity reach the target muddy density and viscosity in the target muddy viscosity and density determination step, the barite supply motor, bentnite supply motor, fluid mixing device driving motor in the mixing tank, and fluid circulation It is characterized in that it comprises; as well as stopping the pump driving motor, the completion of the water production step of closing the barite hopper and the bentonite hopper air supply valve.

In the mud production method of the mud water circulation system according to the other embodiment, the target fresh water supply step includes: a target flow speed and water level setting step in which a target fresh water flow rate and a target fresh water supply water level are set by the operating condition setting unit; Fresh water supply operation pre-state checking step of the PLC control unit to determine whether it is normal by checking the pre-operation status of the fresh water supply-related equipment of the water circulation system; a fresh water supply step of supplying fresh water from the water tank to the selected mixing tank by the PLC controller controlling the fluid control valve and the fluid circulation pump driving motor when the state of the fresh water supply related equipment is normal; a water level sensing step in which the PLC control unit detects a water level in the selected mixing tank through a fluid level sensing unit in the tank; a target fresh water supply level determining step in which the PLC control unit determines whether the water level of the mixing tank is lower than the target fresh water supply level; and when the water level of the mixing tank is lower than the target fresh water supply level, the fresh water supply step proceeds, while when the water level of the mixing tank reaches the target fresh water supply level, the PLC control unit stops the fluid circulation pump driving motor Fresh water supply completion step; may include.

In the mud production method of the mud mud circulation system according to the other embodiment, if the mud mud viscosity and the mud mud density do not reach the target mud mud density and viscosity in the target mud mud viscosity and density determination step, the PLC control unit is a target viscosity determining step of determining whether the viscosity is equal to or less than the target viscosity; and if the mixed viscosity is less than or equal to the target viscosity, the bulk supply step is performed. On the other hand, if the mixed viscosity is greater than the target viscosity, the PLC control unit controls the fluid control valve and the fluid circulation pump driving motor to remove the fluid from the water tank. It may further include; after supplying fresh water to the selected mixing tank, the fresh water additional supply step proceeds to the dilution viscosity calculation step.

In order to achieve the above object, in the waste water treatment method of the waste water circulation system according to another embodiment of the present invention, the PLC control unit checks the pre-work state of the waste water circulation system equipment to determine whether it is normal or not. pre-status check step; a shale shaker driving motor selection step in which a shale shaker driving motor is selected by a driving condition setting unit in a state in which the pre-work state is normal; a return mixing tank selection step of selecting a mixing tank to return the reprocessed waste water by the operation condition setting unit; a fluid supply preparation step in which the PLC controller controls the fluid control valve to supply waste wastewater to the wastewater treatment tank and prepares to return the reprocessed wastewater to the selected mixing tank; a shale shaker driving step in which the PLC control unit senses the vibration of the shale shaker through the shale shaker vibration detection unit and drives the shale shaker driving motor to set vibration; When the PLC control unit detects the fluid level in the waste water reprocessing tank through the in-tank fluid level detection unit, and the fluid level in the waste water reprocessing tank is greater than or equal to a set level, the fluid mixing device driving motor in the waste water reprocessing tank is driven driving the fluid mixing device in the waste water reprocessing tank to a degasser driving step in which the PLC control unit drives the degasser driving motor; and when the PLC control unit detects the fluid level in the waste water reprocessing tank through the in-tank fluid level detection unit and exceeds a set level, the PLC control unit controls the fluid circulation pump driving motor and the fluid control valve to reprocess the mixed water into the selected mixing tank It is characterized in that it comprises a; dilution supply step of supplying

According to an apparatus and method for producing wastewater and waste water treatment of a wastewater circulation system according to an embodiment of the present invention, the operating conditions set by the operating condition setting unit, the shale shaker vibration sensing unit, the pipe internal flow rate sensing unit, and the pipe internal pressure sensing Based on the detection signals input from the part, barite weight detection unit, bentonite weight detection unit, tank fluid level detection unit, and pipe fluid density detection unit, the control signal is sequentially processed by the program stored inside to barite the control signal. Feed motor, bentonite feed motor, fluid mixing device drive motor in the waste water reprocessing tank, fluid mixing device drive motor in the mixing tank. The fluid circulation pump driving motor, the shale shaker driving motor, the degasser driving motor, the dust collector fan driving motor, the barite hopper and bentonite hopper air supply valves, and the fluid control valve are configured to output to control, thereby reducing the water in the mixed water circulation system. Manpower accidents at the drilling site can be prevented by automating the process of manufacturing and waste water treatment, and there is an outstanding effect that it is possible to manage objectively according to the set characteristics.

1 is a block diagram of an apparatus for manufacturing waste water and waste water treatment of a waste water circulation system according to an embodiment of the present invention.
2 is a flowchart for explaining a method for producing mud water of a mud water circulation system according to an embodiment of the present invention.
3 is a detailed flowchart of step S300 of FIG.
4 is a flowchart for explaining a waste water treatment method of a waste water circulation system according to an embodiment of the present invention.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. And, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the content throughout this specification. The terminology used in the detailed description is for the purpose of describing embodiments of the present invention only, and should in no way be construed as limiting. Unless explicitly used otherwise, expressions in the singular include the meaning of the plural. In this description, expressions such as “comprising” or “comprising” are intended to indicate certain features, numbers, steps, acts, elements, some or a combination thereof, one or more other than those described. It should not be construed as excluding the existence or possibility of other features, numbers, steps, acts, elements, or any part or combination thereof.

In each device shown in the figures, elements in some instances may each have the same reference number or different reference numbers to suggest that the represented element may be different or similar. However, elements may have different implementations and work with some or all of the devices shown or described herein. The various elements shown in the drawings may be the same or different. Which one is referred to as the first element and which is referred to as the second element is arbitrary.

In this specification, when any one component 'transmits', 'transfers' or 'provides' data or signal to another component, one component directly transmits data or signal to another component, of course, and transmitting data or signals to the other component via at least one other component.

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

1 is a block diagram of an apparatus for manufacturing waste water and waste water treatment of a waste water circulation system according to an embodiment of the present invention.

As shown in FIG. 1 , the waste water production and waste waste water treatment apparatus of the waste water circulation system according to an embodiment of the present invention includes an operating condition setting unit 170 , a shale shaker vibration sensing unit 100 , and a pipe internal flow rate sensing unit. (110), pipe internal pressure sensing unit 120, barite weight sensing unit 130, bentonite weight sensing unit 140, in-tank fluid height sensing unit 150, in-pipe fluid density sensing unit 160, PLC controller 200 , barite supply motor 300 , bentonite supply motor 310 , fluid mixing device driving motor 320 in the waste water reprocessing tank, and fluid mixing device driving motor 325 in the mixing tank. Fluid circulation pump drive motor 330 , shale shaker drive motor 340 , degasser drive motor 350 , dust collector fan drive motor 360 , barite hopper and bentonite hopper air supply valve 370 , and fluid control valve (380).

The operation condition setting unit 170 sends a key operation signal to the PLC controller 200 to set the operation conditions of the water circulation system. For example, the target mud density, target viscosity, target fresh water flow rate, and target fresh water supply level are set through the operation condition setting unit 170 , and a mixing tank to be produced, a shale shaker driving motor, and a mixing tank to return the reprocessed mud can be selected.

The shale shaker vibration sensing unit 100 detects the vibration (ie, frequency) of the shale shaker that removes foreign substances contained in the waste water and provides a vibration detection signal to the PLC control unit 200 .

The pipe internal flow rate detection unit 110 serves to detect the flow rate inside the pipe of the water circulation system and provide a flow rate detection signal to the PLC control unit 200 .

The pipe internal pressure sensing unit 120 serves to detect the pressure inside the pipe of the water circulation system and provide a pressure sensing signal to the PLC control unit 200 .

The bar light weight sensing unit 130 measures the weight of the bar light loaded inside the bar light hopper and serves to provide a weight sensing signal to the PLC control unit 200 .

The bentonite weight detection unit 140 measures the weight of bentonite loaded inside the bentonite hopper and serves to provide a weight detection signal to the PLC control unit 200 .

The in-tank fluid level detection unit 150 measures the fluid level in the water tank, the mixing tank, and the waste water reprocessing tank, and serves to provide a fluid level detection signal to the PLC controller 200 .

The fluid density detecting unit 160 in the pipe serves to detect the density of the fluid in the inlet pipe of the mixing tank and provide a fluid density sensing signal to the PLC control unit 200 .

The PLC control unit 200 is an electronic device for controlling all components of the present invention, and includes the operating conditions set by the operating condition setting unit 170 , the shale shaker vibration sensing unit 100 , and the pipe internal flow rate sensing unit 110 . , input from the pipe internal pressure sensing unit 120, the barite weight sensing unit 130, the bentonite weight sensing unit 140, the fluid height sensing unit 150 in the tank, and the fluid density sensing unit 160 in the pipe Based on the detection signal, logic is sequentially processed by the program stored inside, and the control signal is processed by the barite supply motor 300, the bentonite supply motor 310, and the fluid mixing device driving motor 320 in the waste water reprocessing tank, mixing In-tank fluid mixing device drive motor (325). Fluid circulation pump drive motor 330 , shale shaker drive motor 340 , degasser drive motor 350 , dust collector fan drive motor 360 , barite hopper and bentonite hopper air supply valve 370 , and fluid control valve By controlling the output to 380, it is possible to produce waste water in the waste water circulation system and reprocess the waste water obtained after the produced waste water is used in the drilling process.

The bar light supply motor 300 receives a control signal from the PLC control unit 200 and is driven (rotated) to generate a driving force so as to transmit the bar light from the bar light hopper to the mixing tank through a pipe.

The bentonite supply motor 310 receives a control signal from the PLC control unit 200 and rotates to generate a driving force to deliver the bentonite from the bentonite hopper to the mixing tank through a pipe.

The fluid mixing device driving motor 320 in the waste water reprocessing tank is driven by receiving a control signal from the PLC control unit 200 to provide a driving force so that the fluid mixing device in the waste water reprocessing tank operates.

The fluid mixing device driving motor 325 in the mixing tank receives a control signal from the PLC controller 200 and is driven to provide a driving force to operate the fluid mixing device in the mixing tank.

The fluid circulation pump driving motor 330 receives a control signal from the PLC control unit 200 and is driven to provide a driving force to the fluid circulation pump that circulates the fluid (water, waste water, and waste water) of the mixed water circulation system. .

The shale shaker driving motor 340 receives a control signal from the PLC controller 200 and is driven to provide driving force to the shale shaker.

The degasser driving motor 350 receives a control signal from the PLC controller 200 and is driven to provide a driving force to the degasser that removes harmful gas generated during drilling.

The dust collector fan driving motor 360 receives a control signal from the PLC controller 200 and is driven to provide a driving force to the dust collector that removes particulates in the air generated in the water circulation system.

The barite hopper and bentonite hopper air supply valve 370 is driven (opened or closed) by receiving a control signal from the PLC control unit 200 to lower the barite hopper (a device that lowers the powders attached to the gift hopper) and It is a valve that controls the air supply to the bentonite hopper (a device that lowers the powder attached to the bentonite hopper).

The fluid control valve 380 is a valve that receives a control signal from the PLC control unit 200 and is driven (opened or closed) to control the flow of fluid (water, wastewater, wastewater) in a pipe in the wastewater system.

Hereinafter, a method for producing waste water in a waste water circulation system and a waste waste water treatment method for a waste water circulation system using an apparatus for producing waste water and waste waste water according to an embodiment of the present invention configured as described above will be described.

[How to make this water]

2 is a flowchart for explaining a method of manufacturing mud for a mud circulation system according to an embodiment of the present invention, where S means a step.

First, the target mud density and viscosity are set by the operation condition setting unit 170 (S100), and a mixing tank to produce the mud is selected (S200).

Next, the PLC controller 200 controls the fluid circulation pump driving motor 330 and the fluid control valve 380 to supply fresh water of a target water level from the water tank to the mixing tank selected in step S200 (S300). Step S300 is described in detail below.

Next, the PLC control unit 200 determines whether it is normal by checking the pre-operation state of the water circulation system equipment (S400).

If, in step (S400), the pre-operation state is normal (Y), the PLC control unit 200 opens the barite hopper and bentonite hopper air supply valve 370 (S450) so that the air flows into the barite hopper and bentonite. By injecting into the hopper, the agglomeration of barite and bentonite is prevented.

Next, the PLC control unit 200 drives the barite supply motor 300 and the bentonite supply motor 310 to supply the gift stone and bentonite, and the fluid circulation pump driving motor 330 and the fluid control valve 380 Control to set a bulk supply line for supplying barite and bentonite from the barite hopper and bentonite hopper to the mixing tank selected in step (S200) (S500).

Next, the PLC controller 200 drives the fluid mixing device driving motor 325 in the mixing tank to mix the fluid in the selected mixing tank ( S550 ).

Next, the PLC control unit 200 detects the flow rate inside the pipe of the water circulation system through the pipe internal flow rate sensor 110, multiplies the flow rate by the fluid passage and the cross-sectional area of the pipe to obtain the flow rate, and calculates the water viscosity based on the flow rate Calculate (S600).

That is, the flow rate information sensed from the flow rate sensor 110 inside the pipe is multiplied by the fluid passage cross-sectional area of the pipe to obtain the flow rate (Value), and based on the flow rate, the dilution viscosity is calculated using the following [Equation 1].

[Equation 1]

On the other hand, instead of calculating the dilution viscosity using the above [Equation 1], the flow rate data and the dilution viscosity data from a separately installed server are machine-learned into the artificial neural network as a data set, the pipe internal flow rate sensing unit 110 It is also possible to input the detected flow rate data through to calculate the dilution viscosity data, and then retrieve and use the calculated dilution viscosity data.

Next, the PLC control unit 200 detects the syneresis density inside the pipe through the pipe internal pressure sensing unit 120 (S700), and the synergetic viscosity calculated in step S600 and the synergistic density detected in step S700 are It is determined whether the target syneresis density and viscosity have been reached (S800).

If, in step (S800), the muddy viscosity and the muddy density have reached the target muddy density and viscosity (Y), the PLC control unit 200 controls the barite supply motor 300, the bentnite supply motor 310, and the mixing tank. All operations are terminated by stopping the fluid mixing device driving motor 325 and the fluid circulation pump driving motor 330 and closing the barite hopper and bentonite hopper air supply valves 370 ( S900 ).

On the other hand, in the step (S800), if the muddy viscosity and the muddy density do not reach the target muddy density and viscosity (N), the PLC control unit 200 determines whether the muddy viscosity calculated in the step (S600) is below the target viscosity. It is determined whether or not (S850).

If, in step S850, the mixed viscosity is equal to or less than the target viscosity (Y), the process proceeds to step S500, while if the mixed viscosity is greater than the target viscosity (N), the PLC control unit 200 controls the fluid control valve 380 and After controlling the fluid circulation pump driving motor 330 to supply fresh water from the water tank to the selected mixing tank (S860), the process proceeds to the above step (S600).

Meanwhile, the step S300 will be described in detail with reference to FIG. 3 .

First, a target fresh water flow rate and a target fresh water supply level are set by the driving condition setting unit 170 ( S310 ).

Next, the PLC control unit 200 determines whether it is normal by checking the pre-operation state of the equipment related to the fresh water supply of the water circulation system (S320).

If the state of the fresh water supply related equipment is normal in step S320 (Y), the PLC control unit 200 controls the fluid control valve 380 and the fluid circulation pump driving motor 330 from the water tank in step S200 ) to supply fresh water to the selected mixing tank (S330).

Next, the PLC control unit 200 detects the water level of the selected mixing tank through the in-tank fluid level detection unit 150 (S340), and whether the water level of the mixing tank is lower than the target fresh water supply level set in step S310 is determined (S350).

If, in step S350, the water level of the mixing tank is lower than the target fresh water supply level (Y), the process proceeds to step S330, while when the water level of the mixing tank becomes the target fresh water supply level (N) PLC control unit 200 stops the fluid circulation pump driving motor 330 (S360).

On the other hand, if the state of the equipment related to the fresh water supply in step S320 is abnormal (N), it proceeds to step S360.

[Waste Sewage Treatment Method]

4 is a flowchart for explaining a waste wastewater treatment method of a wastewater circulation system according to an embodiment of the present invention, where S means a step.

First, the PLC control unit 200 determines whether it is normal by checking the pre-operation state of the water circulation system equipment (S1000).

If, in step S1000, in a state where the pre-work state is normal (Y), the shale shaker driving motor 340 is selected by the driving condition setting unit 170 (S1000), and mixing to return the reprocessed waste water When the tank is selected (S1200), the PLC control unit 200 controls the fluid control valve 380 to supply waste water to the waste water treatment tank, and prepare to return the reprocessed water to the mixing tank selected in step S1200. to (S1300).

Next, the PLC control unit 200 drives the shale shaker driving motor 340 to set vibration while sensing the vibration of the shale shaker through the shale shaker vibration sensing unit 100 ( S1400 ).

Next, when the PLC control unit 200 detects the fluid level in the waste water reprocessing tank through the in-tank fluid level detection unit 150 and the fluid level in the waste water reprocessing tank is greater than or equal to the set level, in the waste water reprocessing tank The fluid mixing device driving motor 320 is driven (S1500).

Next, the PLC controller 200 drives the degasser driving motor 350 ( S1600 ), thereby removing harmful gas generated during drilling.

Next, when the PLC control unit 200 detects the fluid level in the waste water reprocessing tank through the tank fluid level detection unit 150 and is above the set level, the fluid circulation pump driving motor 330 and the fluid control valve 380 By controlling and supplying the re-treated water to the selected mixing tank (S170), the waste water treatment process is completed.

According to an apparatus and method for producing waste water and waste water treatment of a waste water circulation system according to an embodiment of the present invention, the operating conditions set by the operating condition setting unit, the shale shaker vibration sensing unit, the pipe internal flow rate sensing unit, and the pipe internal pressure sensing Based on the detection signals input from the part, barite weight detection unit, bentonite weight detection unit, tank fluid level detection unit, and pipe fluid density detection unit, the control signal is sequentially processed by the program stored inside to barite the control signal. Feed motor, bentonite feed motor, fluid mixing device drive motor in the waste water reprocessing tank, fluid mixing device drive motor in the mixing tank. The fluid circulation pump driving motor, the shale shaker driving motor, the degasser driving motor, the dust collector fan driving motor, the barite hopper and bentonite hopper air supply valves, and the fluid control valve are configured to output to control, thereby reducing the water in the mixed water circulation system. By automating the process of manufacturing and waste water treatment, it is possible to prevent manpower accidents at the drilling site and to manage it objectively to meet the set characteristics.

An optimal embodiment is disclosed in the drawings and the specification, and specific terms are used, but these are used only for the purpose of describing the embodiments of the present invention, and are used to limit the meaning or limit the scope of the present invention described in the claims it didn't happen Therefore, it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical protection scope of the present invention should be defined by the technical spirit of the appended claims.

100: shale shaker vibration detection unit
110: pipe internal flow rate sensing unit
120: pressure sensing unit inside the pipe
130: bar light weight detection unit
140: bentonite weight detection unit
150: fluid level detection unit in the tank
160: fluid density detection unit in the pipe
170: driving condition setting unit
200: PLC control unit
300: bar light supply motor
310: bentonite supply motor
320: fluid mixing device driving motor in the waste water reprocessing tank
325: fluid mixing device drive motor in the mixing tank
330: fluid circulation pump drive motor
340: shale shaker drive motor
350: degasser drive motor
360: dust collector fan drive motor
370: barite hopper and bentonite hopper air supply valve
380: fluid control valve

Claims (7)

As a wastewater production and wastewater treatment device for a wastewater circulation system, the wastewater production and wastewater treatment apparatus for producing wastewater in the wastewater circulation system and reprocessing the wastewater obtained after the produced wastewater is used in a drilling process,
an operating condition setting unit configured to set operating conditions of the water circulation system;
a shale shaker vibration sensing unit configured to sense vibration of a shale shaker that removes foreign substances contained in waste water;
a pipe internal flow velocity sensing unit configured to detect a flow velocity inside the pipe of the mixed water circulation system;
a pipe internal pressure sensing unit configured to sense a pressure inside the pipe of the mixed water circulation system;
a barite weight detection unit configured to measure the weight of the barite loaded inside the barite hopper;
a bentonite weight sensing unit configured to measure the weight of the bentonite loaded inside the bentonite hopper;
a fluid level sensing unit in the tank configured to measure a fluid level in the water tank, the mixing tank, and the waste water reprocessing tank;
a fluid density sensor in the pipe configured to detect the density of the fluid in the inlet pipe of the mixing tank;
The operating conditions set by the operating condition setting unit, the shale shaker vibration sensing unit, the pipe internal flow rate sensing unit, the pipe internal pressure sensing unit, the barite weight sensing unit, the bentonite weight sensing unit, the fluid level sensing unit in the tank and the pipe PLC control unit configured to output a control signal by sequentially logical processing by a program stored therein based on the sensing signal input from the fluid density sensing unit;
a bar light supply motor configured to receive a control signal from the PLC control unit and driven to generate a driving force for transmitting bar light from the bar light hopper to the mixing tank;
a bentonite supply motor configured to receive a control signal from the PLC controller and drive it to generate a driving force for transferring the bentonite from the bentonite hopper to the mixing tank;
a fluid mixing device driving motor in the waste water reprocessing tank configured to receive a control signal from the PLC controller and driven to provide a driving force to the fluid mixing device in the waste water reprocessing tank;
a fluid mixing device driving motor in the mixing tank configured to receive a control signal from the PLC controller and driven to provide a driving force to the fluid mixing device in the mixing tank;
a fluid circulation pump driving motor configured to receive a control signal from the PLC control unit and driven to provide a driving force to the fluid circulation pump that circulates the fluid in the water circulation system;
a shale shaker driving motor configured to receive a control signal from the PLC controller and be driven to provide a driving force to the shale shaker;
a degasser driving motor configured to receive a control signal from the PLC control unit and drive it to provide a driving force to the degasser that removes harmful gas generated during drilling;
a dust collector fan driving motor configured to receive a control signal from the PLC controller and drive it to provide a driving force to a dust collector that removes particulates in the air generated in the water circulation system;
a barite hopper and bentonite hopper air supply valve configured to receive a control signal from the PLC control unit and to control the air supply to the barite hopper and bentonite hopper; and
and a fluid control valve that is driven by receiving a control signal from the PLC control unit and configured to control the flow of a fluid in a pipe in the mixed water circulation system.
According to claim 1,
The PLC control unit
The flow rate information sensed from the flow rate sensor inside the pipe is multiplied by the fluid passage and cross-sectional area of the pipe to obtain the flow rate (Value), and based on the flow rate, the dilution cycle is further configured to calculate the dilution viscosity using the following [Equation 1] Sewage production and waste sewage treatment system in the system.

[Equation 1]

A method for producing waste water of the waste water circulation system according to claim 1 and a waste water circulation system using the waste waste water treatment apparatus, the method comprising:
Density and viscosity setting step in which the target water density and viscosity are set by the operation condition setting unit;
a mixing tank selection step in which a mixing tank to be produced is selected by the operation condition setting unit;
a target level fresh water supply step in which a PLC controller controls a fluid circulation pump driving motor and a fluid control valve to supply fresh water of a target water level from a water tank to the selected mixing tank;
a work pre-state check step of the PLC control unit checking the work pre-state of the water circulation system equipment to determine whether it is normal;
When the pre-operation state is normal, the PLC control unit opens the barite hopper and the bentonite hopper air supply valve to prevent the barite and bentonite by air supplying air supply step;
The PLC control unit drives the barite supply motor and the bentonite supply motor, and controls the fluid circulation pump driving motor and the fluid control valve to set a bulk supply line for supplying the barite and bentonite to the selected mixing tank. feeding step;
a fluid mixing step in which the PLC controller drives a fluid mixing device driving motor in the mixing tank to mix the fluid in the selected mixing tank;
The PLC control unit detects the flow rate inside the pipe of the dilution circulation system through the pipe internal flow rate sensing unit, obtains the flow rate by multiplying the flow rate by the fluid passage and the cross-sectional area of the pipe, and calculates the dilution viscosity based on the flow rate;
a mixing density sensing step in which the PLC control unit detects the mixing density inside the pipe through the pipe internal pressure sensing unit;
a target muddy viscosity and density determining step in which the PLC control unit determines whether the muddy viscosity and the muddy density have reached the target muddy density and viscosity; and
When the muddy viscosity and the muddy density have reached the target muddy density and viscosity in the target muddy viscosity and density determination step, the barite supply motor, bentnite supply motor, a fluid mixing device driving motor in the mixing tank, and a fluid circulation pump In addition to stopping the drive motor, the completion of the production of water to close the barite hopper and the bentonite hopper air supply valve; Containing, the water production method of the water circulation system.
4. The method of claim 3,
The target level of fresh water supply step is
a target flow rate and water level setting step of setting a target fresh water flow rate and a target fresh water supply level by the driving condition setting unit;
Fresh water supply operation pre-state check step of the PLC control unit to determine whether or not the normal operation by checking the pre-operation status of the fresh water supply-related equipment of the water circulation system;
a fresh water supply step of supplying fresh water from the water tank to the selected mixing tank by the PLC controller controlling the fluid control valve and the fluid circulation pump driving motor when the state of the fresh water supply related equipment is normal;
a water level sensing step in which the PLC control unit detects a water level in the selected mixing tank through a fluid level sensing unit in the tank;
a target fresh water supply level determining step in which the PLC control unit determines whether the water level of the mixing tank is lower than the target fresh water supply level; and
When the water level in the mixing tank is lower than the target fresh water supply level, the fresh water supply step proceeds, while when the water level in the mixing tank reaches the target fresh water supply level, the PLC control unit stops the fluid circulation pump driving motor. Completing the supply; Containing, Diwater production method of the Diwater circulation system.
4. The method of claim 3,
If in the step of determining the target synthesizing viscosity and density, the synthesizing viscosity and synthesizing density do not reach the target synthesizing density and viscosity,
a target viscosity determining step of the PLC control unit determining whether the mixed viscosity is equal to or less than the target mixed viscosity; and
If the mixed viscosity is equal to or less than the target mixed viscosity, the bulk supply step is performed, while if the mixed viscosity is greater than the target viscosity, the PLC control unit controls the fluid control valve and the fluid circulation pump driving motor to remove the water from the water tank. After supplying fresh water to the selected mixing tank, additional supply of fresh water proceeding to the step of calculating the viscosity of the mixed water; further comprising, a method for producing water for a water circulation system.
4. The method of claim 3,
The step of calculating the dilution viscosity is
The flow rate information sensed from the flow rate sensor inside the pipe is multiplied by the fluid passage and cross-sectional area of the pipe to obtain a flow rate (Value), and based on the flow rate, the dilution viscosity is calculated using the following [Equation 1], of a dilution circulation system How to make Isu.

[Equation 1]

A waste waste water treatment method of a waste water circulation system using the waste water production and waste waste water treatment apparatus of the waste water circulation system according to claim 1,
A waste waste water work pre-state check step in which the PLC control unit checks the work pre-state of the waste water circulation system equipment to determine whether it is normal;
a shale shaker driving motor selection step in which a shale shaker driving motor is selected by a driving condition setting unit in a state in which the pre-work state is normal;
a return mixing tank selection step of selecting a mixing tank to return the reprocessed waste water by the operation condition setting unit;
a fluid supply preparation step in which the PLC controller controls the fluid control valve to supply waste wastewater to the wastewater treatment tank and prepares to return the reprocessed wastewater to the selected mixing tank;
a shale shaker driving step in which the PLC controller senses the vibration of the shale shaker through the shale shaker vibration detection unit and drives the shale shaker driving motor to set vibration;
The PLC control unit detects the fluid level in the waste water reprocessing tank through the fluid level sensor in the tank and drives the fluid mixing device driving motor in the waste water reprocessing tank when the fluid level in the waste water reprocessing tank is greater than or equal to a set level driving the fluid mixing device in the waste water reprocessing tank to
a degasser driving step in which the PLC control unit drives the degasser driving motor; and
When the PLC control unit detects the fluid level in the waste water reprocessing tank through the in-tank fluid level detection unit and exceeds a set level, the PLC control unit controls the fluid circulation pump driving motor and the fluid control valve to detect the reprocessed water into the selected mixing tank. A waste wastewater treatment method of a wastewater circulation system, including; a wastewater supply step of supplying.

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