KR102664579B1 - Water quality measurement sample water stabilization apparatus - Google Patents

Abstract

The present invention relates to a device for stabilizing water quality measurement sample water. More specifically, for accurate water quality measurement, air bubbles contained in the water quality measurement sample water to be supplied to the water quality measuring instrument are removed and stabilized without using a curved conduit, and then the water quality measuring instrument is used to stabilize the water quality measuring sample water. It relates to a water quality measurement sample water stabilization device supplied to .

Description

Water quality measurement sample water stabilization apparatus}

The present invention relates to a device for stabilizing water quality measurement sample water. More specifically, for accurate water quality measurement, air bubbles contained in the water quality measurement sample water to be supplied to the water quality measuring instrument are removed and stabilized without using a curved conduit, and then the water quality measuring instrument is used to stabilize the water quality measuring sample water. It relates to a water quality measurement sample water stabilization device supplied to .

Recently, with rapid population growth and advanced industrialization in Korea, water quality is becoming extremely polluted due to various sources of pollution, such as air pollution, soil pollution, and industrial waste pollution from industrial facilities. In particular, pollution of water sources and rivers is causing major problems in human life and the normal circulation of the ecosystem.

Accordingly, in order to prevent rivers, streams or water sources from being polluted by wastewater or other pollutants discharged from factories, the purpose is to periodically monitor rivers, streams, lakes, water purification and sewage treatment facilities at the national level. By testing water quality, water sources are protected as well as management and regulation of pollutant-emitting businesses are systematically carried out. In addition, not only have the water quality standards and virus treatment standards for water treated at water treatment plants been strengthened, but real-time monitoring has been systematically introduced to even the quality of water supplied from consumer faucets, and laws and systems have been reorganized and implemented so that citizens can drink tap water with peace of mind. It is becoming.

However, the actual condition of the water supply network cannot be confirmed through related pipes, so if the pipes of the water supply network are damaged or rusted, the tap water discharged from home may contain rust or dirt even if clean tap water is supplied from a water purification plant. These things have been happening frequently recently.

Therefore, it is becoming necessary to test the water quality of tap water supplied to homes through rivers, lakes, lakes, water purification and sewage treatment facilities, as well as water pipes, and a system has been established to monitor the quality of tap water supplied to homes. As a result, the installation of water quality measuring instruments is expected to expand.

In order to accurately test water quality, it is necessary to accurately evaluate water quality by measuring various items depending on site characteristics, and the status of water quality must be judged in real time. The main items that measure the condition of water quality include not only water temperature, but also hydrogen ion concentration, dissolved oxygen amount, turbidity, and other various items. Hydrogen ion concentration represents a numerical value indicating the degree of acidity or alkalinity of a substance, and turbidity is a numerical quantification of the degree of cloudiness of water.

Among the various items that measure water quality, when measuring turbidity using an optical measurement method, turbidity cannot be accurately measured unless air bubbles in the sample water are removed. In other words, if the sample water contains air bubbles, it greatly affects the measurement performance of the water quality meter. This is because when light encounters a bubble, it can be reflected or refracted on the surface of the bubble, generating scattered light, and light passing through the bubble is also refracted through media with different densities.

Accordingly, in Domestic Patent No. 10-0572370 (announced on April 18, 2006) (hereinafter referred to as “Prior Document 1”), etc., the sample water flowing in through the inlet is allowed to exceed the central cylindrical shape, thereby allowing air bubbles contained in the sample water. has been removed. However, this prior art document 1 has a problem in that although it can remove large bubbles, it cannot remove fine bubbles, and when a large flow rate is supplied, the bubbles are not properly removed.

To solve this problem, Domestic Patent No. 10-2618110 (announced on December 28, 2023) (hereinafter referred to as “Prior Document 2”) maintains the hydraulic pressure of the water supplied to the water quality measuring instrument at a constant level and supplies it in an H shape. A technology is disclosed to remove bubbles contained in the tap water through a strainer in the bubble removal pipe of the first pipe and supply it to a water quality meter.

Prior Literature 2 reduced the amount of air bubbles by removing some of them, but there was a limit to the size of the control panel including the water quality meter and the constant flow rate removal device, so bending of the conduit included in the constant flow rate removal device inevitably occurred, and the conduit bending occurred. Fine bubbles stay in the water, causing changes in flow rate, forming an air layer to reduce bubbles, or supply stabilized water quality measurement sample water to the water quality meter.

In other words, Prior Literature 2 also has the problem of reducing the accuracy of turbidity measurement due to air bubbles.

Republic of Korea Patent No. 10-0572370 (announced on April 18, 2006) Republic of Korea Register No. 10-2618110 (announced on December 28, 2023)

Therefore, the object of the present invention is to provide a water quality measurement sample water stabilization device that removes and stabilizes air bubbles contained in the water quality measurement sample water to be supplied to the water quality meter without using a curved conduit for accurate water quality measurement and then supplies it to the water quality meter. It is in

The water quality measurement sample water stabilization device according to the present invention for achieving the above object includes: a main housing in which a constant air pressure is formed and a space is formed on the inside so that the supplied water quality measurement sample water rises from the inner bottom; an inlet that passes through the bottom of the main housing and is connected to the space to receive water quality measurement sample water; The space portion of the main housing is formed elongated from the bottom surface to the top, and the upper part is open, and the pipe of the inlet is formed to extend, so that water quality measurement sample water flowing through the inlet fills up from the bottom and overflows along the outer peripheral surface of the space portion. a sample inflow pipe that flows to allow air bubbles contained in the water quality measurement sample water to spread into the air of the space; It is formed in the direction from the ceiling to the floor of the space of the main housing, and is formed to descend to a position lower than the height of the sample inlet pipe. When immersed in the water quality measurement sample water rising in the space, the water quality measurement sample water is supplied after being immersed. a sample outflow pipe that rises into the inner pipe and flows out of the main housing; And an outlet formed to penetrate the upper surface of the main housing so as to extend from the outside of the main housing to the outlet pipe, and supplies the water quality measurement sample water flowing out from the outlet pipe to the water quality measuring device. .

The main housing is formed in a cylindrical shape, and the sample outflow pipe is formed in the center of the cylindrical shape.

The device is characterized in that it further includes a pressure control unit formed to penetrate into the space from the outer upper part of the main body housing to adjust the air pressure of the space.

The pressure regulator includes a pressure regulator that is formed to penetrate into the space from the outer upper part of the main body housing and forms an air supply path that receives air and supplies air to the space to form the air pressure of the space. and a pressure control valve configured in the pressure control pipe to control the amount of air supplied to the space.

The pressure control valve includes an air pressure sensor that measures the air pressure of the space, and the pressure control unit further includes a pressure control unit that adjusts the pressure control valve so that the air pressure measured by the air pressure sensor is maintained at a preset air pressure. It is characterized by including.

The pipe diameter of the sample inlet pipe is characterized in that it is formed larger than the pipe diameter of the sample outflow pipe.

The diameter of the sample inlet pipe is less than 1/2 of the pipe diameter of the main housing, but is configured to be maximum in a range that does not overlap with the sample outflow pipe.

The height of the sample inlet pipe is formed at a first height (H1), and the sample outflow pipe is configured to descend to a second height (H2), which is at least 1/2 lower than the first height.

The present invention has the effect of maximizing bubble removal efficiency by removing air bubbles from the sample water to be supplied to the water quality meter (hereinafter referred to as “water quality measurement sample water”) by applying only a non-curved conduit.

In addition, the present invention is configured on the inside of a main housing forming a sealed space therein to receive water quality measurement sample water, and the bubbles contained in the water quality measurement sample water overflowing the inlet pipe diffuse into the space. Remove the water quality measurement sample water that overflows and fills up from the bottom of the space of the main body to the top according to the constant pressure of the space and the difference between the pipe diameters of the inlet pipe and the outlet pipe contained in the water quality measurement sample water that fills the space. Since it is discharged naturally, it has the effect of stabilizing and supplying water quality measurement sample water with air bubbles removed at a constant pressure without using a separate static pressure maintenance device.

Figure 1 is a diagram showing the configuration of a water quality measurement device to which the water quality measurement sample water stabilization device according to the present invention is applied.
Figure 2 is a perspective view showing the configuration of a water quality measurement sample water stabilization device according to the present invention.
Figure 3 is a side cross-sectional view of the water quality measurement sample water stabilization device according to the present invention.
Figure 4 is a plan cross-sectional view of the water quality measurement sample water stabilization device according to the present invention.
Figure 5 is a diagram illustrating the effect of applying the water quality measurement sample water stabilization device according to the present invention.

Hereinafter, the configuration and operation of the water quality measurement sample water stabilization device according to the present invention will be described in detail with reference to the attached drawings.

Figure 1 is a diagram showing the configuration of a water quality measurement device to which the water quality measurement sample water stabilization device according to the present invention is applied.

Referring to Figure 1, the water quality measurement sample water stabilization device 20 of the present invention receives tap water, river water, river water, etc. as water quality measurement sample water through a water pipe, pump, etc., and removes air bubbles contained in the water quality measurement sample water. After removal, the flow rate is stabilized at a preset static pressure and supplied to the water quality meter (30).

As shown in FIG. 1, the water quality measurement sample water stabilization device 20 of the present invention is internally configured so that air bubbles contained in the supplied water quality measurement sample water do not stay in the bends of the conduit, causing a change in flow rate or forming an air layer. The conduits used are constructed using straight conduits without any bends.

As shown in FIG. 1, a positive pressure valve 10 may be installed in front of the water quality measurement sample water stabilization device 20 of the present invention to supply water quality measurement sample water at positive pressure to the water quality measurement sample water stabilization device 20. will be.

Figure 2 is a perspective view showing the configuration of a water quality measurement sample water stabilization device according to the present invention, Figure 3 is a side cross-sectional view of the water quality measurement sample water stabilization device according to the present invention, and Figure 4 is a water quality measurement according to the present invention. It is a plan cross-sectional view of the sample water stabilization device, and Figure 5 is a view to explain the effect of applying the water quality measurement sample water stabilization device according to the present invention. Hereinafter, description will be made with reference to FIGS. 2 to 5.

The water quality measurement sample water stabilization device 20 of the present invention includes a main housing 110, an inlet 120, a sample outlet 130, a sample inlet pipe 140, a sample outlet pipe 150, and an outlet 160. and, depending on the embodiment, may further include a pressure regulator 170.

The main housing 110 may be formed in various shapes such as a cube, rectangular parallelepiped, or cylindrical having an upper surface and a lower surface, and is formed to have a space 111 therein. The space 111 may also be formed in a shape corresponding to the shape of the main body housing 110, but it is preferable that it be formed in a cylindrical shape. The external shape of the main body 110 may also be preferably cylindrical.

Depending on the embodiment, the space 111 may initially be configured to maintain a constant air pressure through the inlet 120, the sample inlet pipe 140, the sample outlet pipe 150, and the outlet 160, and in other embodiments Depending on the example, it may be configured to maintain a constant air pressure through the pressure regulator 170.

The inlet 120 is formed at the bottom of the main body 110 so that the pipe of the inlet 120 penetrates one side of the lower surface of the main body 110 and is connected to the space 111.

The sample discharge unit 130 includes a sample discharge port 131 and a sample discharge valve 132, and when the sample discharge valve 132 is opened, the water quality measurement sample water in the space 111 of the main housing 110 is discharged to the outside.

The sample inlet pipe 140 is formed to be long upward from the position where the inlet 120 penetrates the bottom surface of the space 111, and the upper part is open, so that the water quality measurement sample flows in through the inlet 120. Water is supplied, air bubbles contained in the water quality measurement sample water are collected, and the rising water quality measurement sample water overflows through the open top and flows down into the space 111 of the main body housing 110 along the outer peripheral surface. . Air bubbles contained in the water quality measurement sample water are exposed to the space 111 when the water quality measurement sample overflows from the sample inlet pipe 140 and are removed by spreading into the air.

When the space 111 of the main housing 110 is formed in a cylindrical shape, the pipe diameter R1 of the sample inlet pipe 140 is preferably formed larger than the pipe diameter of the inlet 120, and the main housing 110 ), but is preferably formed to be less than 1/3 of the pipe diameter (R), and is formed to the maximum size within a range that does not interfere with the sample outflow pipe 150. In order for the pipe diameter R1 to be larger than 1/3 of the pipe diameter R of the main housing 110, the sample outflow pipe 150 should not be installed in the center of the space 111. In this case, the pipe diameter (R1) of the sample inlet pipe 140 may be formed to be less than 1/2 of the pipe diameter (R) of the main housing 110. However, since the sample outflow pipe 150 is preferably installed in the center of the space 111 due to design considerations, the pipe diameter R1 of the sample inflow pipe 140 is 1 of the pipe diameter R of the main housing 110. It would be desirable to form the maximum size at /3 or less.

The sample outflow pipe 150 is formed from the ceiling to the floor of the space 111 of the main housing 110, and has a second height (H2) lower than the first height (H1) of the sample inflow pipe 140. ) is configured to go down to. That is, the first height (H1) must be greater than the second height (H2) (H1>H2). For example, if the first height (H1) of the sample inlet pipe 140 is 20cm, the sample outflow pipe 150 must come down from the ceiling to a second height (H2) of 19cm or less, which is lower than the first height (H1). do. In addition, since the water quality measurement sample water must flow down to the bottom of the space 111 and rise above a certain height, the second height H2 is preferably determined to be a value between 1 cm and 19 cm in the above example. That is, the maximum level of the water quality measurement sample water flowing into the space 111 is the maximum H2. The water level of water quality measurement sample water does not change in H2 unless there is a separate manipulation. It is preferable that the second height (H2) is configured to be lower than 1/2 of the first height (H1). This ensures that the water surface of the water quality measurement sample water filling up in the space 111 is formed at less than 1/2 of the first height (H1), and the area of the air (space without water quality measurement sample water) of the space 11 is set to the maximum. This is to remove as many air bubbles as possible.

The outlet 160 passes through the upper surface of the main housing 110 from the upper part of the main housing 110 and is connected to the sample outflow pipe 150, and the other side is connected to the water quality meter 30, so that the sample outflow pipe 150 ) are removed, and water quality measurement sample water at a constant static pressure according to the air pressure in the space 111 is supplied to the water quality meter 30.

The pressure control unit 170 configured according to the embodiment may include a pressure control pipe 171 and a pressure control valve 172, and may further include a pressure control unit 173 according to the embodiment.

The pressure control pipe 171 is formed to penetrate into the space 111 from one side of the upper portion, and supplies air supplied from the outside to the space 111.

The pressure control valve 172 is configured at the inlet portion of the pressure control pipe 171 to block air supplied from the external air pressure supply unit (not shown) or to control air supplied from the space 111 through the pressure control pipe 171. supplied by The pressure control valve 172 may be able to adjust the amount of air injected into the space 111 depending on the level of the object.

In addition, the pressure control valve 172 includes an air pressure sensor configured to the pressure control valve 172 to measure air pressure according to the amount of air supplied to the space 111, and the pressure control unit 173 includes the air pressure sensor. The air pressure supply unit (not shown) is turned on or off so that the air pressure measured through the air pressure sensor maintains the preset air pressure, and the pressure control valve 172 is adjusted to control the amount of air pressure injected or discharged to the outside. An air pressure discharge pipe (not shown) and an air pressure discharge control valve (not shown) that discharge the air in the space 111 to the outside may be separately configured.

The water quality measurement sample water flowing through the inlet 120, which is connected to the static pressure valve 10 of FIG. 1 and the conduit, is supplied to the sample inlet pipe 140, rises from the sample inlet pipe 140, and flows into the sample inlet pipe 140. It overflows through the upper part and flows down into the space 111 along the outer peripheral surface of the sample inlet pipe 140. At this time, air bubbles contained in the water quality measurement sample water are exposed to the air of the space 111, diffuse into the air of the space 111, and are removed.

The water quality measurement sample water from which air bubbles have been removed rises from the bottom of the space 111 to the second height (H2), and the water quality measurement sample water supplied after the second height (H2) flows through the sample outflow pipe (150). It is supplied to the water quality meter 30 through the outlet 160.

The air pressure of the space 111 may vary due to air bubbles collected from the water quality measurement sample water overflowing the sample inlet pipe 140.

At this time, the pressure regulator 170 monitors the air pressure in the space 111, and when the air pressure changes more than a preset standard value, it adjusts the pressure control valve 172 to discharge the air in the space 111 to the outside. It may be configured to maintain the air pressure of (111) constant. Additionally, when the air pressure in the space 111 is lowered due to a special operation, the pressure regulator 170 will inject air pressure to maintain the air pressure in the space 111 at a constant static pressure.

Figure 5 and Table 1 below show a turbidity graph measured under specific experimental environmental conditions to confirm the performance of the water quality measurement sample water stabilization device of the present invention.

The experimental conditions were as follows.

In the experimental environment, water quality measurement sample water is supplied from a large water tank, and a bubble generator (pump) and positive pressure valve are selectively applied. The fluid moves from the large water tank through a water quality measurement sample water stabilization device to a water quality meter, and the bubble removal effect is achieved. To view this, the change in turbidity value of the water quality meter was recorded, and to check the change in flow rate, a flow meter was installed in the drain pipe of the water quality meter to check the change in flow rate.

First, six conditions were set depending on whether the water quality measurement sample water stabilization device was installed, whether the bubble generator was operating or not, and whether the static pressure valve was installed. Each experiment lasted 30 minutes and then proceeded with the next experiment.

Second, the bubble removal effect for each experimental condition is confirmed using the turbidity value of the water quality meter connected to the device.

Third, the flow stabilization effect for each experimental condition is confirmed by the change in flow rate of the flow meter installed in the drain pipe of the water quality meter.

Referring to Figure 5 and Table 1 below obtained according to the above experimental environment and conditions, as shown in ① of Table 1 and Figure 5, air bubbles are formed in the water quality measurement sample water even without installing the water quality measurement sample water stabilization device of the present invention. If there is no , it can be seen that the turbidity value remains constant.

However, if the water quality measurement sample water stabilization device of the present invention is not installed, the flow rate increases and the flow rate is not stabilized. If the flow rate is not stabilized, it affects the measured values of other water quality measurement items such as hydrogen ion concentration and residual chlorine concentration, reducing the accuracy of the water quality instrument.

On the other hand, as shown in ② of Table 1 and FIG. 5, when the water quality measurement sample water stabilization device of the present invention is installed, it can be seen that the turbidity value is stable and the flow rate is also stabilized.

As shown in Table 1 and ③ of Figure 5, when installing the water quality measurement sample water stabilization device and static pressure valve of the present invention, it can be seen that the turbidity value is stable and the flow rate is more stable.

As shown in ④ of Table 1 and Figure 5, when a bubble generator is installed arbitrarily and a large amount of bubbles are forcibly injected into the water quality measurement sample water, the turbidity value becomes very high and unstable, and the change in flow rate is large, causing different water quality. Affects the measured value of a measurement item.

As shown in ⑤ of Figure 5 of Table 1, even when a bubble generator is installed and a large amount of bubbles are injected into the water quality measurement sample water, the water quality measurement sample water stabilization device of the present invention must be installed, or the water quality measurement sample water stabilization device It can be seen that when installing a constant pressure valve, the turbidity level and flow rate are stabilized.

Whether stabilization device is installed Whether a constant pressure valve is installed bubble generator
Installation status Turbidity (NTU) Flow rate (ml/min) ① 0.076 700 or more ② ○ 0.078 500 ③ ○ ○ 0.078 420 ④ ○ 70.8±0.7 700 or more ⑤ ○ ○ 0.44±0.03 500 ⑥ ○ ○ ○ 0.35±0.02 420

Meanwhile, it is common knowledge in the technical field that the present invention is not limited to the above-described typical preferred embodiments, but can be implemented by various improvements, changes, substitutions, or additions without departing from the gist of the present invention. Anyone who has will be able to understand it easily. If the implementation by such improvement, change, replacement or addition falls within the scope of the appended patent claims below, the technical idea thereof should also be regarded as belonging to the present invention.

10: Constant pressure valve 20: Water quality measurement sample water stabilization device
30: water quality meter 110: main body housing
111: space 120: inlet
130: sample outlet 131: sample outlet
132: sample discharge valve 140: sample inlet pipe
150: sample outlet pipe 160: outlet
170: pressure regulator 171: pressure regulator
172: pressure control valve 173: pressure control unit

Claims (8)

A main body housing that is sealed to form a constant air pressure and has a space formed on the inside so that the supplied water quality measurement sample water fills up from the inner bottom surface;
an inlet that passes through the bottom of the main housing and is connected to the space to receive water quality measurement sample water;
The space portion of the main housing is formed elongated from the bottom surface to the top, and the upper part is open, and the pipe of the inlet is formed to extend, so that water quality measurement sample water flowing through the inlet fills up from the bottom and overflows along the outer peripheral surface of the space portion. a sample inflow pipe that flows to allow air bubbles contained in the water quality measurement sample water to spread into the air of the space;
It is formed in the direction from the ceiling to the floor of the space of the main housing, and is formed to descend to a position lower than the height of the sample inlet pipe. When immersed in the water quality measurement sample water rising in the space, the water quality measurement sample water is supplied after being immersed. a sample outflow pipe that rises into the inner pipe and flows out of the main housing;
an outlet formed to penetrate the upper surface of the main housing to extend from the outside of the main housing to the outlet pipe, and supply the water quality measurement sample water flowing out of the outlet pipe to a water quality measuring device; and
It includes a pressure control unit formed to penetrate the space from the outer upper part of the main body housing to adjust the air pressure of the space,
The pressure regulator,
a pressure control pipe that is formed to penetrate into the space from the outer upper part of the main body housing and forms an air supply path that receives air and supplies air to the space to establish air pressure in the space; and
It includes a pressure control valve configured in the pressure control pipe to control the amount of air supplied to the space,
The pressure control valve is,
It includes an air pressure sensor that measures the air pressure in the space,
The pressure regulator,
A water quality measurement sample water stabilization device further comprising a pressure control unit that adjusts the pressure control valve so that the air pressure measured by the air pressure sensor is maintained at a preset air pressure.
According to paragraph 1,
The main body housing,
It is formed in a cylindrical shape,
The sample outflow pipe is,
A water quality measurement sample water stabilization device, characterized in that formed at the center of the cylindrical shape.
delete delete delete According to paragraph 1,
The diameter of the sample inlet pipe is,
A water quality measurement sample water stabilization device characterized in that it is formed larger than the diameter of the sample outflow pipe.
According to paragraph 2,
The diameter of the sample inlet pipe is,
A water quality measurement sample water stabilization device, characterized in that it is formed to be less than 1/2 of the pipe diameter of the main housing, but is configured to be maximized within a range that does not overlap the sample outflow pipe.
According to paragraph 2,
The height of the sample inlet pipe is formed as a first height (H1),
The sample outflow pipe is,
A water quality measurement sample water stabilization device, characterized in that it is configured to descend to a second height (H2), which is more than 1/2 lower than the first height.