KR20210006678A - System for managing start and end of purification plant filter backwash using real-time transmittance - Google Patents

Abstract

The present invention relates to a system for managing start and end of filter paper backwashing in a water purification plant using real-time light transmittance, comprising: a light source module irradiating light; a light transmittance module for acquiring the light transmittance of outflowing water passing through the filter paper of the water purification plant by the light irradiated from the light source module; a backwash water discharge module discharging backwash water for backwashing the filter paper of the water purification plant; and a control module controlling a start time or an end time for the discharge of the backwash water by the backwash water discharge module based on the light transmittance obtained by the light transmittance module.

Description

System for managing start and end of purification plant filter backwash using real-time transmittance}

The present invention relates to a system for managing the start and end of backwashing of filter paper in a water purification plant using real-time transmittance.

Tap water encountered in daily life is taken from a river or a dam and supplied to each household through a water purification process.

The water treatment process takes in from the river (or dam) and goes through a treatment process that is finally supplied to the consumer through "settling well, coagulation, mixing settling basin, filter paper, water purification basin (drainage basin)", and the purpose of the water treatment facility is the dam (or To produce water suitable for human use as drinking water by removing harmful substances such as floating substances, trace amounts of organic substances and pathogenic microorganisms from raw water of various characteristics such as lakes), rivers, sometimes surface water (river drifting water), and groundwater. have.

The water treatment process consists of an embedding well, a chemical injection facility, a coagulation/settling battery, a filter paper (slow/rapid), a disinfection facility and a discharged water treatment process, and the embedding well receives the supplied raw water and acts as a buffer to stabilize the flow and blends. The coagulation sedimentation facility is a facility that corresponds to the pretreatment process during the treatment of the water treatment plant.It is a process to remove particulate matter (suspended material) and colloidal material contained in raw water.It is a process to remove particulate matter in a short time. Main coagulant and auxiliary coagulant) are injected, mixed, and then removed by sedimentation.

Filter paper is a process of removing fine particles that have not been removed from the sedimentation basin. The main filter layer and gravel layer such as sand or anthracite, the bottom collecting device (pore block) and backwash pump for backwash, air washing and other surfaces if necessary. It consists of washing equipment, etc.

The discharged water treatment facility consists of a dewatering facility and auxiliary facilities that finalize the solid by separating the sedimentation basin drainage water and the filter basin backwash water into solid and liquid.

The chemical injection facility is a facility for injecting powdered activated carbon into raw water to remove flocculants and alkalis such as slaked lime and taste, odors, which are used to remove suspended substances and colloidal substances in raw water in water purification plants, and disinfection facilities (chlorine , UV/AOP, ozone, etc.) is a process to supply hygienically safe water by inactivating pathogenic microorganisms.

Filter paper, which plays the most important role in the water purification process, is divided into slow filtration method and rapid filtration method, and is optimized as a process to finally remove particulate matter (suspend) that has not been removed in the pretreatment process (precipitating). If the filter paper is not washed (hereinafter referred to as backwashing), the target filtration performance in the water treatment process cannot be expected.

Conventional backwashing of filter paper is a method of backwashing water after mechanically stirring a layer of sand, a method of backwashing after disturbing the sand layer with air, a method of backwashing by ejecting air and water at the same time, a method of backwashing with only water, etc. There is this.

In the conventional backwashing of filter paper as described above, since most of the systems that can control the backwashing speed do not exist, the opening and closing of the backwashing valve is a simple on/off method that causes an impact on the structure of the filter paper by sudden operation. Problems are often caused, and turbid leakage is not considered even in the calculation of the backwashing point, so most of them are determined by the development of the loss head or the rising water level of the filter paper.To reduce the power cost of the water purification plant, backwashing is carried out at once. It has a bad effect in terms of water treatment efficiency.

It is an object of the present invention to provide a system for managing the start and end of backwashing of filter papers at a water purification plant using real-time transmittance to prevent excessive use of backwashing water for backwashing of filter papers, and maximize backwashing efficiency.

A system for managing the start and end of backwashing of filter paper in a water purification plant using real-time transmittance according to an embodiment of the present invention includes: a light source module for irradiating light; A transmittance module for obtaining transmittance of the effluent water irradiated from the light source module through the filter paper of the water purification plant; A backwash water discharge module for discharging backwash water for backwashing the filter paper of the water purification plant; And a control module for controlling a start point or end point of discharge of the backwash water by the backwash water discharge module based on the transmittance obtained by the light transmittance module.

The control module of the system for managing the start and end of backwashing of filter paper in a water purification plant using real-time transmittance according to an embodiment of the present invention, the backwash water discharged by the backwash water discharge module through a relationship between turbidity and transmittance. It may be characterized by controlling the start point or end point of the discharge.

The turbidity-to-transmittance correlation of the system for managing the start and end of backwashing of water purification plant filter paper using real-time transmittance according to an embodiment of the present invention is derived through a relationship between transmittance to an arbitrary turbidity value. You can do it.

The control module of the system for managing the start and end of backwashing of filter paper in a water purification plant using real-time transmittance according to an embodiment of the present invention, the backwash water discharge module based on the transmittance obtained by the transmittance module It can be characterized by controlling the discharge amount of backwash water by.

The backwash water discharge module of the system for managing the start and end of backwashing of a filter paper in a water purification plant using real-time transmittance according to an embodiment of the present invention is linked with the opening and closing rate of the backwash discharge valve and the backwash discharge valve. And a flow rate measurement unit, wherein the control module compares the light transmittance obtained by the transmittance module and an opening/closing rate of the backwash water discharge valve obtained from the flow rate measurement unit to determine the amount of backwash water by the backwash water discharge module. It can be characterized by controlling the discharge amount.

According to the system for managing the start and end of backwashing of filter paper in a water purification plant using real-time transmittance according to the present invention, it is possible to prevent excessive use of backwashing water for backwashing of filter papers and maximize backwashing efficiency.

1 is a block diagram illustrating a system for managing the start and end of backwashing of filter paper in a water purification plant using real-time transmittance according to an embodiment of the present invention.
FIG. 2 is a flowchart illustrating a control method performed by a system for managing the start and end of backwashing of filter paper in a water purification plant using real-time transmittance according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, the spirit of the present invention is not limited to the presented embodiments, and those skilled in the art who understand the spirit of the present invention can add, change, or delete other elements within the scope of the same idea. Other embodiments included within the scope of the inventive concept may be easily proposed, but it will be said that this is also included within the scope of the inventive concept.

In addition, components having the same function within the scope of the same idea shown in the drawings of each embodiment will be described with the same reference numerals.

1 is a block diagram illustrating a system for managing the start and end of backwashing of a water purification plant using a real-time transmittance according to an embodiment of the present invention, and FIG. 2 is a real-time transmittance according to an embodiment of the present invention. It is a flow chart for explaining the control method performed by the system for managing the start and end of backwashing of filter paper in a water purification plant using.

First of all, the water purification process in a water purification plant removes suspended substances, trace amounts of organic substances, and harmful substances such as pathogenic microorganisms from raw water of various characteristics such as dams, rivers or groundwater to produce water suitable for human use as drinking water. It has its purpose.

The filter paper that plays the most important role in the water treatment process is backwashing the most important, so the backwashing depends on the structure of the filter paper, design conditions, the size, shape, specific gravity, and quality of the raw water sediment.

In addition, in terms of the use of backwash water and backwash efficiency, if the start point of backwashing is accelerated, the problem of excessive use of backwashing water occurs.If the start point of backwashing is delayed, there is a problem that the backwashing efficiency that does not improve is inevitably obtained. Occurs.

In addition, if the end time of backwashing is accelerated, there is a problem that backwashing efficiency that is not improved is inevitably obtained, and if the end of backwashing is delayed, there is a problem that the backwashing water is wasted.

As a result, it is necessary to optimize the start and end times of backwashing in terms of waste of backwashing water, loss of filter media, and shortening of lifespan for the above reasons.

Referring to FIG. 1, a system (100, hereinafter referred to as "system") for managing the start and end of backwashing of a water purification plant using real-time light transmittance according to an embodiment of the present invention It may be a system for managing the start and end of backwashing based on the degree of transmission of the light by irradiation.

Specifically, the system 100 may include a light source module 110, a transmittance module 120, a backwash water discharge module 130, and a control module 140.

The light source module 110 may be a module that irradiates light to the effluent water passing through the filter paper, and the transmittance module 120 is a module for obtaining a transmittance of the light irradiated from the light source module 110 to the effluent water. As such, it may be a kind of sensor.

The transmittance module 120 can sense the degree to which the light irradiated from the light source module 110 to the effluent is not scattered and transmitted, and the higher the transmitted degree, the lower the turbidity of the effluent water, so that the water purification efficiency is high. Can mean that.

The backwash water discharge module 130 may be a module for discharging backwash water for backwashing the filter paper of the water purification plant, and the control module 140 is based on the transmittance obtained by the transmittance module 120. The backwash water discharge module 130 may be a kind of controller that controls a start point or end point of discharge of the backwash water.

The control module 140 may control a start point or end point of discharge of the backwash water by the backwash water discharge module 130 through a correlation between turbidity and light transmittance.

Here, the correlation between the turbidity and the transmittance may be derived through the relationship of the transmittance to an arbitrary turbidity value, and a specific derivation process is as follows.

First, the correlation of the turbidity range (0-20 NTU) according to the transmittance (0-100%) is obtained, and then a calibration curve is prepared.

When the calibration curve is created, an equation is derived so that a specific transmittance is matched with a specific turbidity value, so that the turbidity value can be known through the transmittance obtained by the transmittance module 120.

The control module 140, based on the transmittance obtained by the transmittance module 120, so that the time point at which the acquired transmittance becomes smaller than the first predetermined transmittance becomes the start time of discharge of backwash water. Controls the washing water discharge module 130.

On the other hand, the transmittance module 120 may acquire the transmittance of light to the runoff water in real time, and even while the backwash water is discharged, the transmittance obtained by acquiring the transmittance of light to the runoff water is greater than a second predetermined transmittance. The backwash water discharge module 130 is controlled so that the end time of discharge of the washing water is reached.

On the other hand, the control module 140 may control the discharge amount of backwash water by the backwash water discharge module 130, that is, not only the presence or absence of discharge of backwash water, but also the discharge amount.

To this end, the backwash water discharge module 130 may include a backwash water discharge valve and a flow rate measurement unit interlocking with the opening/closing rate of the backwash water discharge valve.

That is, the control module 140 compares the light transmittance obtained by the light transmittance module 120 and the opening/closing rate of the backwash water discharge valve obtained from the flow rate measurement unit to determine the amount of backwash water by the backwash water discharge module. Emissions can be controlled.

Hereinafter, a method of managing the start and end of backwashing of filter paper in a water purification plant using real-time transmittance performed by the system 100 according to the present invention will be described.

Referring to FIG. 2, a first step (S10) in which light is irradiated to the effluent water passing through the filter paper by the light source module 110 is performed.

When light is irradiated to the outflow water in the first step (S10), a second step (S20) in which transmittance is obtained by the transmittance module 120 is performed.

When the transmittance is obtained by the transmittance module 120, a third step (S30) of determining whether the acquired transmittance is less than a predetermined reference is performed.

If it is determined that the transmittance obtained by the third step (S30) is less than the predetermined standard, the fourth step (S40) of discharging the backwash water by the backwash water discharge module 130 proceeds, and the backwash of the filter paper This will proceed.

Even if the backwash water is discharged in the fourth step (S40) and the backwash of the filter paper proceeds, the second step (S20) in which the transmittance is obtained in real time may be repeatedly performed, and the transmittance obtained in the repetitive process may be performed. If the standard is exceeded, the backwash water is discharged.

On the other hand, when the transmittance obtained by the third step (S30) is greater than or equal to a predetermined criterion, the filter paper does not need backwashing, so the water purification plant is normally operated and the transmittance is obtained in real time (S20). Is repeated.

As described above, the system 100 for managing the start and end of backwashing of filter paper at a water purification plant using real-time transmittance according to the present invention controls the start and end of backwashing of filter papers using the transmittance of light. It is possible to maximize the efficiency of backwashing while preventing excessive use of backwashing water.

In the above, the configuration and features of the present invention have been described based on the embodiments according to the present invention, but the present invention is not limited thereto, and various changes or modifications can be made within the spirit and scope of the present invention. It will be apparent to those skilled in the art, and therefore, such changes or modifications are found to belong to the appended claims.

100: A system for managing the start and end of backwashing of filter paper in a water purification plant using real-time transmittance
110: light source module
120: transmittance module
130: backwash water discharge module
140: control module

Claims (5)

A light source module that irradiates light;
A transmittance module for obtaining transmittance of the light irradiated from the light source module for the effluent water passing through the filter paper of the purification plant;
A backwash water discharge module for discharging backwash water for backwashing the filter paper of the water purification plant; And
A water purification plant using a real-time light transmittance comprising a; a control module for controlling a start point or end point of discharge of the backwash water by the backwash water discharge module based on the light transmittance obtained by the light transmittance module. A system to manage the start and end of filter paper backwash.
The method of claim 1,
The control module,
A system for managing the start and end of backwashing of filter paper in a water purification plant using real-time transmittance, characterized in that the start or end point of discharge of the backwashed water by the backwash water discharge module is controlled through a correlation between turbidity and transmittance .
The method of claim 2,
The light transmittance correlation to the turbidity is,
A system for managing the start and end of backwashing of filter paper in a water purification plant using real-time transmittance, characterized in that it is derived through a relationship between transmittance to an arbitrary turbidity value.
The method of claim 1,
The control module,
A system for managing the start and end of backwashing of filter paper in a water purification plant using real-time transmittance, characterized in that controlling discharge of backwash water by the backwash water discharge module based on the transmittance obtained by the transmittance module.
The method of claim 1,
The backwash water discharge module,
It includes a backwash water discharge valve and a flow rate measurement unit interlocking with the opening and closing rate of the backwash water discharge valve,
The control module,
Using a real-time transmittance, characterized in that the amount of backwash water discharged by the backwash water discharge module is controlled by comparing the transmittance obtained by the transmittance module and the opening/closing rate of the backwash discharge valve obtained from the flow rate measurement unit. A system for managing the start and end of backwashing of filter paper in a water purification plant.

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