KR101017869B1 - Average Water Quality Measuring System of Water Storage Tank - Google Patents

Abstract

The present invention relates to a representative apparatus for measuring water quality in a reservoir, a water tank, and the like of a water and sewage system. In general, the processing of the water supply system supplies the water to the consumer through the raw water intake, flocculation, blending, sedimentation, filtration, water purification, and distribution water stages. In the above water distribution step, the water stored in the purified water is transferred to a water pump by a water pump, and then the water supply of the water reservoir is supplied to the water in a natural manner. It is common that water quality measurement such as turbidity, residual chlorine, alkalinity, electrical conductivity, and water temperature of the drainage water is required in the above-mentioned distribution water stage. Therefore, it is necessary to maintain the representative values of the water quality values measured above. The general drainage basin and the water tank as described above is different in the water quality of the upper and lower layers. The water quality is inevitably different depending on the location of the drainage basin depending on the depth, width or residence time of the basin. Therefore, under these circumstances, representative value measurements are also very important to ensure adequate water quality and to determine drug inputs for water quality control. The present invention relates to an apparatus for measuring the representative water quality in such a critical basin or bath as described above. According to the present invention, there is an effect of installing a measuring device at various points of a drainage basin or a tank, and it is easy to manage, and it is possible to precisely control the water quality by measuring the representative value accurately, and also to facilitate the control of the chemical input control system. In addition, the disinfection by-products caused by the overdose of the drug is also significantly reduced.

Water quality, representative value, turbidity, residual chlorine, reservoir, water tank, alkalinity, electrical conductivity, disinfection by-product, control system

Description

Average Water Quality Measuring System of Water Storage Tank

The present invention provides turbidity, residual chlorine, alkalinity, and electrical conductivity in a basin or bath for water quality management of the basin or bath during each stage of processing such as a tap water system, that is, raw water intake, tapping well, flocculation, sedimentation, filtration, purified water, and distribution water. It is about measuring water quality, such as water temperature. Currently, water quality measurement is measured after sampling by designating a number of measuring points.Average values measured at several points as above are regarded as representative values and used as input values of water quality management or water quality control systems. Are utilized. As described above, the method of measuring the water quality of several points not only requires many measuring devices, but also has a problem that the sampling tube is complicated and difficult to manage. It is also recommended that water meters be installed within 10 feet of the sampling point to ensure accurate water quality measurements.

The present invention relates to the measurement of water quality of such a basin or tank. At present, tap water is taken from rivers or lakes, sent to the water wells, PACs are introduced from the water wells, and sent to the mixed flocculation tanks. Raw water after mixing and flocculation is sent back to the settling basin. Sedimentation of the suspended solids is made in the settling basin, and after the above-mentioned flotation settling process, the filtration is performed on the filter paper to obtain water that meets the legal water quality standards. In addition, the water filtered in the filter paper is collected in the purified water and the water stored in the purified water is a general water supply system to the water supply pump to the destination or drainage. The present invention relates to an apparatus for measuring turbidity, residual chlorine, alkalinity, electrical conductivity, water temperature, etc. for the constant management of a reservoir or a water tank during each step of the processing as described above. The measurement of the water quality management factors of the basin or tank is important for water quality management, drug input, control, etc. The above water quality measurement values should be the average value of the water quality, that is, the representative value to determine the appropriate chemical input amount and each chemical input system. It is also easy to control. On the contrary, if the measured water quality values do not have a representative value, the drug may be excessively input and the disinfection by-products may be generated, which may be harmful to the human body.

Water quality measurements at reservoirs or baths are very important for water quality control and control of chemical input systems. Therefore, representative values of water quality such as turbidity, residual chlorine, alkalinity, electrical conductivity and water temperature in a basin or water bath are very important for the appropriate amount of chemical input. Conventionally, a plurality of measuring points were measured after sampling to measure turbidity or other residual chlorine in a basin or water tank of a water supply system, and a representative value of water quality in a basin or water tank was obtained by averaging each measured value. Such a method requires a plurality of water quality meters by measuring the water quality by collecting water at a plurality of points, and the system is complicated because there are many pipes to collect water and pumped water to the meter. Therefore, in order to solve the above problems, it is necessary to easily and accurately measure the water quality representative value in the reservoir or the water tank.

In order to solve the above problems, the present invention has one or two ends of a diagonal sampling tube installed in a drainage basin or a water tank, and a plurality of holes are provided at one side of the diagonal sampling tube. The fluid (water) in the stream is configured to flow into the sampling tube. The fluid (water) flowing into the sampling tube is mixed while rotating by the plate spiral in the sampling tube. By measuring the water quality of the mixed water mixed as described above it is possible to derive the average value of the water quality of the basin or the entire tank.

As in the present invention, it is important to obtain an average value for the entire water quality of the basin or tank. PAC (a type of flocculant) or chlorine can be determined by the chemical dosing system using average water quality values such as turbidity and residual chlorine, so that the most appropriate chemical dosage can be added, thus minimizing disinfection by-products and turbidity. In addition, the system configuration for obtaining the average water quality value, such as residual chlorine, can be easily configured, which also has the advantage of low cost.

A method for obtaining an average water quality (residual chlorine concentration, turbidity, etc.) value in a conventional basin or bath will be described. In general, it is common to measure the water quality after sampling at the inlet side of the basin or water tank or at a plurality of locations in the basin or water tank, and after sampling for a predetermined time, sampling near the discharge side of the basin or water tank. The initial water quality measurement on the inlet side is used to monitor the adequacy of the water quality, to control the water quality measurement in the basin, or to collect water quality data near the discharge side of the basin or tank to determine whether additional chemicals are added. Therefore, in order to determine the appropriate amount of drug input in the above manner, the feedback of the water quality data of various steps should be made. In other words, the amount of chemical input is determined by using the water quality value at the drainage basin or tank inlet side as a feedback element of the control system. The water quality in the basin or bath is then used again as a feedback element in the chemical dosing system. If the above method is not sufficient, proper water quality management can be performed by sampling the water again near the discharge side of the basin or tank to measure the water quality and adding the water quality as a feedback element to control the chemical input system. . In the conventional method as described above, since a multi-stage feedback is made to the chemical input system, the system takes a lot of load, and there is a problem in that a large number of water quality measurement points are required for the proper amount of chemical input.

The present invention relates to a system for finding water quality representative values in a reservoir or a water tank which are essential for water quality management such as turbidity and residual chlorine. When the water quality representative value is obtained from the reservoir or the water tank according to the present invention, the chemical input system can feed back the water quality representative value once to determine the proper dose of the drug, thereby simplifying the system, and preventing the overdose and overdose of the medicine. It can also reduce disinfection by-products from overdose. Hereinafter, a system for obtaining a representative value of water quality in a reservoir or a water tank according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a water collection method in a reservoir or a water tank 1 according to the present invention. 1 is a diagram showing a state in which the sampling pipe 5 is installed with a constant slope in order to obtain a representative water quality value in a reservoir or a water tank. The slope may have a slope in the horizontal direction and the vertical direction. Sampling tube 5 having a constant inclination as described above constitutes a plurality of holes 6 on one side, that is, the side into which the fluid (water) enters, so that the fluid (water) of the upper, middle, and lower portions of the basin or tank is formed. It is configured to be taken into the sampling pipe (5). The collected fluid (water) is mixed again by the plate spiral 13 via the discharge valve 2 and sent to the water quality meter 4 by the motor pump 3 to measure the water quality. Representative water quality value of the tank can be obtained, and the use of the measured water quality as a control element for determining the amount of drug input can easily determine the appropriate amount of drug input. The sampling tube is fixed to one side of the tank by a bracket or the like so as not to shake. 2 is another embodiment of a sampling tube installation and water quality measurement. In another embodiment, the water quality measuring device 4, the submersible motor pump 3, and the discharge valve 18 are placed in a drainage basin or a water tank. In the above, the sampling tube, pump and water quality measuring instrument may be fixedly installed on one side wall in the tank by the bracket, and the sampling tube may be fixed on one side of the water tank, and a fixed height of a certain height may be installed at the bottom of the pump and the measuring instrument and placed on the bottom of the water tank. It can be fixed. In the present invention as described above, when the pump using the submersible pump (3) in the water, the fluid (water) of the reservoir or tank is introduced into the hole of the sampling tube and introduced into the water quality measuring instrument and the water quality of the introduced fluid (water) The meter measures it. The fluid (water) after the water quality measurement is recovered to a drainage basin or a water tank. In the above, the discharge valve 2 is a valve for opening or closing the sampling tube 5 as necessary, such as when the fluid (water) is collected or when the drainage tank or the water tank is cleaned.

As shown in FIGS. 1 and 2, the inclination and the number of stages of the sampling tube in the basin or the tank are adjustable according to the size and the site of the basin or the basin.

3 shows an embodiment in which the sampling tube 5 is configured in two stages. As shown in FIG. 3, the sampling tube may be installed in two or three stages. In addition, in the case of adding a sampling tube or a new stage, as shown in the example above, a new stage may be additionally installed as required by a coupling hole 16 composed of a thread and a coupling ring, or a sampling tube having a different length. It can also be possible to replace. 4 shows a shape of a sampling tube according to another embodiment. In the above, the sampling tube shows the case where the horizontal slope and the vertical slope are simultaneously. As described above, the sampling tube has an inclination in the horizontal direction and the vertical direction, thereby making it easier to collect the fluid (water) at different positions of the reservoir or the tank.

5 shows an example of installation of a sampling tube, which is another embodiment. Each branch pipe of the main sampling pipe is provided with a solenoid valve to remotely control the solenoid valve, so that the water quality of the fluid (water) flowing in each branch pipe can be measured sequentially. Therefore, if the arithmetic average of the water quality measurement value of the fluid (water) introduced into the branch pipe as described above, it is possible to easily obtain the water quality representative value of the entire basin or tank.

4 and 5 denote the inclination of the sampling main tube 14 in the horizontal direction, and α denotes the vertical inclination of the sampling branch pipe 15, and β denotes the horizontal direction of the sampling branch pipe 15. Indicates the slope.

6 is a perspective view of a circular sampling tube 5, and the numeral 6 shows a hole for collecting water. 7 shows an elliptical sampling tube 7 which is another embodiment, and reference numeral 8 represents a hole for collecting water.

8 shows the hole shape of the circular sampling tube 5. In the above, the hole of the sampling tube may form a hole parallel to the direction in which water flows. However, when the hole is formed as shown in FIG. 8, foreign matters such as moss accumulate in the hole as time passes, so that the hole 11 may be displaced at a predetermined angle with the direction in which water flows, as in the hole 11 of FIG. 9. ), Or the inner surface of the sampling tube is narrow like the hole 12 of FIG. 10 so that the outer surface is wide to prevent foreign substances such as moss from being caught in the hole.

11 also shows another embodiment of the hole 8 of the elliptical sampling tube 7. The shape of the hole constitutes the hole in parallel with the direction of flow of water. 12 shows the shape of a hole according to another embodiment. In the above, the hole constitutes the hole out of a predetermined angle with the direction in which the fluid (water) flows, and in the embodiment of FIG. 13, the outer part of the hole is wider and the inner part is narrower to facilitate the entry of water into the sampling tube 7. An example is shown. By having the shape of the holes (9, 10) as shown in FIGS. 12 and 13, there is an advantage that the moss is not caught in the holes (9, 10).

1 is a perspective view of a sampling tube installed in a reservoir or a water tank

Figure 2 is a perspective view of the installation of the sampling tube of the drainage basin or water tank according to another embodiment

3 is a sampling pipe coupling configuration diagram when the sampling pipe is configured in two stages;

4 is a configuration diagram of the sampling tube having a slope of the main pipe and the branch pipe

5 is a configuration diagram of a sampling pipe equipped with a solenoid valve in a branch pipe

6 is a perspective view of a circular sampling tube

7 is an elliptical sampling tube perspective view

8 is a sectional view of a circular sampling tube and a hole;

9 is a sectional view of a circular sampling tube and a hole according to another embodiment;

10 is a sectional view of another embodiment of a circular sampling tube and a hole

11 is a sectional view of an elliptical sampling tube and a hole;

12 is a sectional view of an elliptical sampling tube and a hole according to another embodiment;

13 is a sectional view of an elliptical sampling tube and a hole according to another embodiment;

* Description of the symbols for the main parts of the drawings *

                  1: Drainage (water tank) 2: Discharge valve

                  3: motor pump 4. meter

                  5, 7: sampling tubes 6, 8, 9, 10, 11, 12: holes

                  13: plate spiral 14: sampling main tube

                  15: sampling branch pipe 16: coupling sphere

Claims (14)

In the system for measuring the water quality representative value of the basin or tank A sampling tube having a plurality of holes on one side in the reservoir or the water tank 1 and installed with a constant inclination? Representative water quality measurement system of a basin or tank characterized in that consisting of a water quality meter for measuring the water quality of the mixed water introduced into the sampling tube. 2. The system of claim 1, wherein the sampling tube is circular or elliptical. The water quality representative measurement system of claim 1, wherein the water quality representative value measuring system of the reservoir or the tank is configured such that the hole of the sampling tube is deviated by a certain angle from the direction in which the fluid flows. The system of claim 1, wherein the sampling pipe is composed of a main pipe and a branch pipe. The water quality representative value measuring system according to claim 1, wherein the sampling tube hole is configured such that the outer portion of the hole is wide and the inner portion is narrow so that the fluid flows easily into the sampling tube. The water quality representative value measuring system in a reservoir or a water tank according to claim 1, wherein the sampling pipe is composed of two or more stages. The water quality representative measuring system according to claim 1, wherein the water quality representative measuring system of the reservoir or the water tank further includes a plate spiral in a portion of the sampling tube to facilitate mixing of the fluid. The water quality representative value measuring system of a drainage basin or a water tank according to claim 2, wherein the water quality representative value measuring system of the drainage basin or a water tank further comprises a discharge valve. The water quality representative value measuring system of a basin or a water tank according to claim 4, wherein the sampling main pipe has a slope (θ) in a horizontal direction. The water quality representative value measuring system of a basin or tank according to claim 4, wherein the sampling branch pipe has a slope in a horizontal direction β and a vertical direction α. In the system for measuring the water quality representative value of the basin or tank A sampling tube installed in the reservoir or the water tank 1 with a predetermined slope θ, and having a plurality of holes formed at one side thereof; A motor pump for returning the sampled fluid to the measuring instrument; Representative water quality measurement system of a basin or tank, characterized in that consisting of a water quality meter for measuring the water quality of the returned fluid. The water quality representative measurement system of claim 10, wherein the water quality representative value measuring system of the reservoir or the water tank further includes a discharge valve in an outer conduit of the reservoir or the water tank to regulate the flow of the fluid. A sampling tube having a plurality of sampling branch pipes having a plurality of holes and having a solenoid valve in the branch pipes and installed with a predetermined slope;  Representative system for measuring the water quality of the basin or tank, characterized in that for adjusting the solenoid valve to measure the water quality of the fluid flowing into the hole with a time delay. Measuring the water quality of the fluid (water) flowing into each branch pipe by sequentially adjusting the solenoid valves installed in the sampling branch pipes one by one; Method for measuring the representative quality of the water of the basin or tank consisting of averaging the measured water quality measurements introduced into each branch pipe.

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