KR102590685B1 - Non-contact pressure type water level sensor and Contactless pressure type water level measurement method - Google Patents

Abstract

One embodiment of the present invention provides a non-contact pressure-type water level sensor that generates a correction coefficient using the length of the chamber, burial depth, and ambient temperature, and reduces measurement errors by correcting the calculated water level with the correction coefficient. A non-contact pressure type water level sensor according to an embodiment of the present invention includes a housing having a space therein; a chamber coupled to the housing and at least a portion of which is inserted into water; a pressure measuring unit that is inserted into the housing and coupled to the chamber and measures the internal pressure of the chamber; and a circuit unit that receives pressure information measured by the pressure measuring unit and converts the pressure value measured by the pressure measuring unit into water level data.

Description

Non-contact pressure type water level sensor and Contactless pressure type water level measurement method}

The present invention relates to a non-contact pressure type water level sensor and a non-contact pressure type water level measurement method. More specifically, the present invention relates to a non-contact pressure type water level measurement method, generating a correction coefficient using the length of the chamber, burial depth, and ambient temperature, and correcting the calculated water level using the correction coefficient. This relates to a non-contact pressure type water level sensor that reduces measurement errors.

In the early stages of rainfall, heavy metals and pollutants from road surfaces, etc., float away all at once and become the main cause of river pollution and fish death, so early rainwater treatment is recognized as an important issue. For this reason, it is very important to install a measurement facility that can control a certain amount of rainwater at the beginning of rainfall to be transferred to a rainwater treatment facility and any excess rainwater to be discharged into the river.

At this time, a water level measurement sensor that measures the amount of rainwater is very important in order to control the measurement target facility. Conventional water level measurement sensors include ultrasonic, buoy, and pressure type water level measurement sensors, but these water level measurement sensors have a problem in that errors occur in measured values depending on the surrounding environment.

Republic of Korea Patent No. 10-1983816 (title of the invention: Device and method for constant water level monitoring and control using ultrasonic waves in high temperature conditions) includes an ultrasonic probe that transmits ultrasonic pulses and receives ultrasonic echo signals, and is connected to the ultrasonic probe. An ultrasonic module including a delay member connected to the pipe, receiving and analyzing the ultrasonic echo signal from the ultrasonic module to detect a plurality of peak values from the ultrasonic echo signal, and a first signal associated with the peak reflected by the delay member. Calculating a path time, a second path time associated with a peak reflected by the pipe, a third path time associated with a peak reflected by a liquid level surface in the pipe, the first path time from the third path time, and A control unit that calculates the level of the liquid using the value obtained by subtracting the second path time and the ultrasonic speed in the liquid, and the ultrasonic module is installed in the pipe so that the longitudinal direction of the ultrasonic transducer and the liquid level surface are perpendicular. A clamp that adheres to the lower part is disclosed.

However, this prior art has a problem in that it is affected by waves, floating objects, etc., and disturbances such as light reflection occur, causing errors in water level measurement. Therefore, there is a need for a non-contact pressure type water level sensor that can efficiently correct the influence of the external environment on the water level gauge, prevent contamination of the sensor by non-contacting with rainwater, and minimize measurement errors due to water waves and obstructions.

Republic of Korea Patent No. 10- 1983816

The purpose of the present invention to solve the above problems is to minimize measurement errors by efficiently correcting the influence of the external environment of the non-contact pressure type water level sensor.

In addition, the purpose of the present invention is to prevent contamination and minimize measurement errors caused by water waves and obstructions by providing a pressure sensor that does not come into contact with rainwater.

The technical problem to be achieved by the present invention is not limited to the technical problem mentioned above, and other technical problems not mentioned can be clearly understood by those skilled in the art from the description below. There will be.

The configuration of the present invention for achieving the above object is a non-contact pressure type water level sensor that measures the water level of rainwater flowing into a measurement target facility, comprising: a housing having a space therein; a chamber coupled to the housing and at least a portion of which is inserted into water; a pressure measuring unit that is inserted into the housing and coupled to the chamber and measures the internal pressure of the chamber; And a circuit unit that receives the pressure information measured by the pressure measuring unit and converts the pressure information measured by the pressure measuring unit into water level information, wherein the circuit unit corrects the pressure error due to the change in the length of the chamber. It is characterized by

In an embodiment of the present invention, the chamber may be separated from or combined with the housing.

In an embodiment of the present invention, the chamber may be replaced depending on the height of the measurement target facility.

In an embodiment of the present invention, the circuit unit may form a correction equation based on the length of the chamber, the ambient temperature, and the burial depth of the chamber.

In an embodiment of the present invention, the housing may further include a communication unit that is inserted into the housing, receives the converted water level value converted by the circuit unit, and receives the converted water level value.

In an embodiment of the present invention, the chamber may be formed of one or more materials selected from stainless steel, plastic, and PVC.

In an embodiment of the present invention, the pressure measuring unit is coupled to one end of the chamber and may not come into contact with rainwater.

In an embodiment of the present invention, the chamber may further include a filter that is coupled to the other end of the chamber and prevents the inflow of suspended matter.

In an embodiment of the present invention, a cross section of the chamber in a direction parallel to the ground may be formed as a circle.

In an embodiment of the present invention, a non-contact pressure type water level measurement method includes the steps of: (a) inputting environmental information, which is information about the environment within the measurement target facility, into the circuit unit; (b) the pressure measuring unit measures the pressure inside the chamber, and the circuit unit measures a measured water level, which is the water level inside the chamber, using the measured pressure value; (c) deriving, in the circuit unit, a calculated water level, which is a water level derived using the design information of the chamber and the measured water level; and (d) the circuit unit calculates a correction coefficient, which is a correction value for the operation water level, using the pre-stored correction data, the environmental information, and the design information of the chamber, and corrects the operation water level using the correction coefficient, thereby providing excellent performance. A step in which the actual water level is derived may be included.

In an embodiment of the present invention, the environmental information may include the temperature of the measurement target facility, the pressure inside the measurement target facility, and the area of the water surface within the measurement target facility.

In an embodiment of the present invention, the design information may include one or more of the length of the chamber, the cross-sectional area of the flow path of the chamber, and the burial depth of the chamber.

The effect of the present invention according to the above configuration has the advantage of minimizing measurement errors by efficiently correcting the external environmental influence of the non-contact pressure type water level sensor.

In addition, the effect of the present invention has the advantage of preventing contamination and minimizing measurement errors caused by water waves and obstructions by providing a pressure sensor that does not come into contact with rainwater.

The effects of the present invention are not limited to the effects described above, and should be understood to include all effects that can be inferred from the configuration of the invention described in the detailed description or claims of the present invention.

1 is a front view of a non-contact pressure type water level sensor according to an embodiment of the present invention.
Figure 2 is an image of a non-contact pressure type water level sensor according to an embodiment of the present invention.
Figure 3 is a diagram showing the chamber of a non-contact pressure type water level sensor according to an embodiment of the present invention.
Figure 4 is a diagram showing the measurement principle of a non-contact pressure type water level sensor according to an embodiment of the present invention.
Figure 5 is a graph showing the actual water level and corrected water level according to the length of the chamber according to an embodiment of the present invention.
Figure 6 is a graph showing the water level of the non-contact pressure type water level sensor according to the amount of rainfall according to an embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the attached drawings. However, the present invention may be implemented in various different forms and, therefore, is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts that are not related to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

Throughout the specification, when a part is said to be "connected (connected, contacted, combined)" with another part, this means not only "directly connected" but also "indirectly connected" with another member in between. "Includes cases where it is. Additionally, when a part is said to “include” a certain component, this does not mean that other components are excluded, but that other components can be added, unless specifically stated to the contrary.

The terms used in this specification are merely used to describe specific embodiments and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as “comprise” or “have” are intended to indicate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

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

Figure 1 is a front view of a non-contact pressure type water level sensor according to an embodiment of the present invention, Figure 2 is an image of a non-contact pressure type water level sensor according to an embodiment of the present invention, and Figure 3 is an image of a non-contact pressure type water level sensor according to an embodiment of the present invention. This is a diagram showing the chamber 200 of a non-contact pressure type water level sensor.

Figure 4 is a diagram showing the measuring principle of a non-contact pressure-type water level sensor according to an embodiment of the present invention, and Figure 5 shows the actual water level and corrected water level according to the length of the chamber 200 according to an embodiment of the present invention. It is a graph, and Figure 6 is a graph showing the water level of the non-contact pressure type water level sensor according to the amount of rainfall according to an embodiment of the present invention.

As shown in Figures 1 to 3, the non-contact pressure type water level sensor includes a housing 160 having a space therein; A chamber 200 coupled to the housing 160, at least a portion of which is inserted into water; A pressure measuring unit 110 that is inserted into the housing 160 and coupled to the chamber 200 and measures the internal pressure of the chamber 200; It may include a circuit unit 120 that receives pressure information measured by the pressure measuring unit 110 and converts the measured pressure measured by the pressure measuring unit 110 into water level data.

As shown in FIG. 2, the non-contact pressure type water level sensor can measure the water level of rainwater flowing into the measurement target facility 10 where rainwater flows.

As shown in FIG. 1, the housing 160 may be formed in a shape with a space inside, and the housing 160 includes a pressure measuring unit 110 that measures the pressure of the chamber 200, and a pressure measuring unit. A circuit unit 120 that converts the pressure value measured in 110 into water level data, a communication unit 130 that transmits the water level data converted in the circuit unit 120 to the control unit, and a battery 140 that supplies power can be inserted. there is.

The housing 160 may have a shielded accommodating space inside and outside, and the cross section of the housing 160 may be formed in a rectangular shape. The housing 160 may be made of one or more materials selected from stainless steel, PVC pipe, and plastic.

The pressure measuring unit 110 may be coupled to one end of the chamber 200, and the pressure measuring unit 110 can measure the change in pressure inside the chamber 200 according to the change in the water level of the measurement target facility 10. And, the pressure information measured by the pressure measuring unit 110 may be received by the circuit unit 120.

The pressure measuring unit 110 is coupled to one end of the chamber 200 and does not directly contact rainwater, thereby preventing sensor contamination due to sedimentation sludge in the rainwater conduit inside the pipe, and the pressure measuring unit 110 does not directly contact rainwater. Even if it is touched, it has a high waterproof rating to prevent the sensor from being submerged.

The pressure measuring unit 110 can measure the change in pressure of the chamber 200 according to the change in water level using the diaphragm, and a change in the upper part of the diaphragm may occur depending on the change in pressure inside the chamber 200, and thus mV/ A signal can be output at V. A signal at the output mV/V may be received by the circuit unit 120. At this time, when the water level is not measured, the pressure measuring unit 110 can measure it at atmospheric pressure.

The circuit unit 120 may be electrically connected to the pressure measuring unit 110, can receive measured pressure information transmitted from the pressure measuring unit 110, and can measure the chamber 200 measured by the pressure measuring unit 110. By converting changes in internal air pressure into measured water level (L2), facility managers can visually see changes in water level.

The circuit unit 120 may generate measurement water level (L2) information by calculating an average pressure based on the pressure value of the measurement point measured by the pressure measurement unit 110.

At this time, the circuit unit 120 may generate a water level difference between the measurement water level (L2) and the measurement target facility 100 depending on the cross-sectional area difference between the chamber 200 and the measurement target facility 100, and uses the measurement water level (L2). The calculated water level can be derived by calculating the water level of the measurement target facility 10.

The calculation formula can be calculated using design information within the measurement target facility 10, and the design information includes one or more of the length of the chamber 200, the cross-sectional area of the flow path of the chamber 200, and the burial depth of the chamber 200. May contain information.

Afterwards, the circuit unit 120 includes a UI with a built-in self-correction program to form a correction coefficient applied to the operation level using previously stored correction data, and the circuit unit 120 calculates the operation level using the correction value. By correcting the water level and calculating the actual water level (L1), measurement errors can be minimized.

The previously stored correction data may include a plurality of correction coefficients formed according to the values of environmental information and design information, and the circuit unit 120 may provide pre-stored corrections corresponding to the environmental information and design information of the measurement target facility 10. The corresponding correction coefficient value can be derived using the data value.

In other words, the correction coefficient corresponding to the design information of the current measurement target facility 10 and chamber 200 can be calculated from the previously stored correction data, and the calculated water level is corrected by calculating the correction coefficient to correct the actual water level (L1). ) can be calculated.

The design information may include one or more of the length of the chamber 200, the cross-sectional area of the flow path of the chamber 200, and the burial depth of the chamber 200.

At this time, the length of the chamber 200 can be changed depending on the depth of the measurement target facility 10, the calculated water level according to the length of the chamber 200 is calculated, and the calculated water level is corrected using a correction coefficient to measure the water level. Errors can be minimized. In addition, by forming a correction coefficient according to the surrounding environment, it can be applied in a customized field to various measurement target facilities (10) without replacing the non-contact pressure type water level sensor.

The communication unit 130 can transmit the data corrected by the circuit unit 120 to the user terminal, and at this time, the communication unit 130 is formed as an IoT-based communication model and can receive data from the user terminal using the LTE (eMTC) communication method. It communicates via RS485 and can output 4 to 20 mA, allowing the same measurement value to be output regardless of the wire distance. Additionally, the communication unit 130 may be formed at IP68 level.

As a result, the communication unit 130 can transmit and receive data online in real time with the user terminal, measuring and transmitting data in real time, so that the user can check the data in real time. It also supports IP68 waterproofing to prevent submersion when in contact with water.

The battery 140 can supply power to the communication unit 130, the pressure measurement unit 110, and the circuit unit 120, and the battery 140 may be formed of a lithium-ion battery 140. The battery 140 can be connected to the solar panel 141 and can be powered by DC power charging or the solar panel 141. The battery 140 is formed by being inserted into the non-contact pressure type water level sensor and can be installed within the measurement target facility 10 regardless of whether power is supplied.

The housing 160 may be equipped with a temperature sensor 150 on the exterior of the housing 160, and the temperature sensor 150 may measure the temperature within the measurement target facility 10. The temperature sensor 150 can transmit the measured temperature value to the circuit unit 120, and as a result, the circuit unit 120 can calculate the calculation formula and correction coefficient using the measured temperature value, which is one of the environmental information.

One end of the chamber 200 may be coupled to the pressure measuring unit 110, one end of the chamber 200 may be formed in communication with the lower surface of the housing 160, and the other end may be inside the measurement target facility 10. It can be installed to be inserted into the rainwater present in the water. In another embodiment, as shown in FIG. 4, one end of the chamber 200 may be coupled to the pressure measuring unit 110, and the pressure measuring unit 110 may be connected to the housing 160 by a wire.

The pressure measuring unit 110 is coupled to one end of the chamber 200 so that rainwater and the pressure measuring unit 110 can be non-contacted. As a result, the pressure measuring unit 110 prevents contamination of the sensor due to sedimentation sludge in the rainwater conduit. It is possible to prevent and protect the pressure measuring unit 110 by preventing floating substances on the surface of the water from coming into contact with the pressure measuring unit 110.

At this time, the pressure measuring unit 110 changes the water level inside the chamber 200 according to a change in the water level inside the measurement target facility 10, thereby forming a change in air pressure inside the chamber 200, so that one end of the chamber 200 The pressure measuring unit 110 coupled with can measure the pressure change inside the chamber 200.

The chamber 200 may be formed of a tubular member having a certain length, and the cross-section of the chamber 200 in a direction parallel to the ground may have a streamlined cross-sectional shape to minimize resistance to fluid flow. there is.

The material of the chamber 200 can be made of a material that has excellent acid resistance, alkali resistance, chemical resistance, and oil resistance and has low thermal conductivity and good non-combustibility. In detail, the material of the chamber 200 can be selected from stainless steel, PVC pipe, and plastic. It can be formed from any one or more materials. As a result, the chamber 200 is made of a material with low thermal conductivity to minimize the influence of the surrounding temperature, thereby maximizing the influence of the measured value. The chamber 200 is formed with high durability to protect the sensor from floating objects on the water surface. can do.

The chamber 200 may be screwed to the housing 160 and separated from the housing 160, and the length of the chamber 200 may vary depending on the height of the measurement target facility 10. As a result, the pressure measuring unit 110 coupled to one end of the chamber 200 can be prevented from coming into contact with rainwater. At this time, the length of the chamber 200 may be 1 m to 5 m.

A mesh-shaped filter 230 may be formed at the other end of the chamber 200 to prevent foreign substances located in rainwater from flowing into the chamber 200. As a result, it is possible to prevent foreign substances floating on the water surface (tree branches, plastic bottles, etc.) that enter the rainwater from entering the chamber 200 and causing the pressure measuring unit 110 to malfunction.

A water quality sensor 240 can be attached to the other end of the chamber 200 and can collect the water quality of flowing rainwater. The water quality sensor 240 may be formed by being drawn into rainwater. The water quality sensor 240 may be formed in a probe type or a lab-on-a-chip type. When formed in a probe type, it can be formed as an electrochemical sensor, an optical sensor, a nano sensor, and It can be formed with one sensor selected from biosensors, and in the case of an electrochemical sensor, water quality can be measured by recognizing changes in the potential of the analyte.

Due to this, the water quality of the rainwater can be measured, and if the water quality of the rainwater measured by the water quality sensor 240 is outside the set water quality, the rainwater can be transported to a rainwater treatment facility. If the water quality of the rainwater is within the set water quality, the rainwater can be discharged into the river. You can. This can prevent river pollution and fish death. The water quality sensor 240 may be electrically connected to the circuit unit 120.

A distance detection sensor 250 may be attached to the other end of the chamber 200, and the distance detection sensor 250 may measure the distance between the other end of the chamber 200 and the measurement target facility 10. The measured distance burial depth (D2) may be transmitted to the circuit unit 120, and the circuit unit 120 may calculate a correction coefficient based on the burial depth (D2) measured by the distance detection sensor 250. The distance sensor 250 may be electrically connected to the circuit unit 120.

A flow sensor 260 may be attached to the other end of the chamber 200 and can measure the flow rate of rainwater flowing within the measurement target facility 10. The flow sensor 260 may be formed as an ultrasonic flow meter. Two sensors alternately transmit and receive ultrasonic signals, using the difference in transmission time of the ultrasonic signals measured by the two sensors to measure the ultrasonic flow rate within the measurement target facility 10. The flow rate of rainwater can be measured. As a result, if the flow rate of rainwater exceeds the set flow rate, flooding of the facility can be prevented by controlling the amount of rainwater flowing into the measurement target facility (10).

In another embodiment, the chamber 200 may be formed to have an adjustable length, as shown in FIGS. 3(a) to 3(b), and the chamber 200 may be fixedly coupled to the housing 160. It may include a chamber 210 and a moving chamber 220 that is inserted into the fixed chamber 210 and moves inside the fixed chamber 210.

The fixed chamber 210 may be formed in a pipe shape, and at least a portion of the movable chamber 220 may be inserted into the fixed chamber, and the fixed chamber 210 may guide the movement of the movable chamber 220. . The other side of the fixing chamber 210 may be provided with a hole, and a fixing screw 212 may be inserted into the hole so that the fixing chamber 210 and the moving chamber 220 can be coupled.

The moving chamber 220 may be formed in the shape of a pipe, and the outer diameter of the moving chamber 220 may be formed to be smaller than the inner diameter of the fixed chamber 210 by a predetermined distance, and one end of the moving chamber 220 It may be provided with an extension body 222 extending outward from the moving chamber 220. The outer diameter of the extension body 222 may be formed to be the same as the inner diameter of the fixed chamber 210, and the extension body 222 may have an outer diameter of the extension body 222. (222) is made of a rubber material and can seal the moving chamber 220 and the fixed chamber 210.

As a result, one end of the moving chamber 220 is fixed to the fixed chamber 210, thereby preventing the moving chamber 220 and the fixed chamber 210 from being separated, and the moving chamber 220 and the fixed chamber 210 can be separated. By sealing, the pressure measuring unit 110 can easily measure the pressure inside the chamber 200.

In another embodiment, as shown in FIGS. 3(c) to 3(d), the fixed chamber 210 and the moving chamber 220 may be made of a pipe, the cross section of which is a circle with two semicircles facing each other. The center of each semicircle is located eccentrically and can be formed into a shape with steps on both sides equal to the eccentric distance.

When the moving chamber 220 is rotated within the fixed chamber 210, while rotating, the moving step 221 formed in the moving chamber 220 contacts the fixed step 211 formed in the fixed chamber 210, causing the moving chamber ( 220 stops rotating and stops, thereby preventing the moving chamber 220 from sliding in the longitudinal direction of the fixed chamber 210.

As a result, after moving the movable chamber 220 inside the fixed chamber 210, the fixed chamber 210 and the movable chamber 220 are combined using the fixing screw 212 at a desired position to increase the length of the chamber 200. can be adjusted.

As shown in FIG. 4, the measuring principle of the non-contact pressure type water level sensor is that the actual water level (L1), which is the water level of the measurement target facility 10, changes from the low water level as shown in FIG. 4(a) to the low water level as shown in FIG. 4(b). When rising together, a rising actual water level (L1') may be formed within the measurement target facility 10, and the measured water level (L2), which is the water level inside the chamber 200, rises to become a rising measured water level (L2'), and the measured water level (L2') in the chamber 200 rises. As the water level inside (200) increases, the air pressure inside the chamber 200 may increase.

The pressure measuring unit 110 coupled to one end of the chamber 200 can measure changes in air pressure inside the chamber 200 and transmit the measured pressure value to the circuit unit 120. The circuit unit 120 can convert the measurement pressure transmitted to the circuit unit 120 into the measurement level (L2).

At this time, the circuit unit 120 can derive the calculated water level using the measured water level (L2) using environmental information and design information, and can derive the actual water level, which is the correction value, by multiplying the calculated water level by the correction coefficient. This can reduce measurement errors.

In Figure 5, in the graph where the x-axis represents the actual water level (L1) and the y-axis represents the measured water level (L2), the actual water level (L1) is the water level of the measurement target facility 10, and the measured water level (L2) is It refers to the chamber water level inside the chamber 200 and may correspond to the measured water level in the non-contact pressure-type water level measurement method of the present invention. In addition, the measured water level (L2), which is the water level of rainwater inside the chamber 200, is determined by the difference between the cross-sectional area of the chamber 200 and the cross-sectional area of the measurement target facility 10 according to the law of hydrostatics. It may be formed differently from the water level in (10).

When the air pressure inside the chamber 200 is applied to the water surface of the rainwater within the chamber 200 and the atmospheric pressure is applied to the water surface of the rainwater within the measurement target facility 10, the difference between the air pressure inside the chamber 200 and the atmospheric pressure and the chamber ( 200) The internal air pressure is higher than the water level of the measurement target facility (10) due to the difference between the water surface area of the rainwater in the chamber (200) and the atmospheric pressure. It can be formed high.

At this time, the combined force of the force applied to the water surface of the rainwater in the chamber 200 by the compressed air inside the chamber 200 and the force due to the weight of the water inside the chamber 200 is the atmospheric pressure within the measurement target facility 10. It can be formed identically to the force generated by acting on the water surface.

As shown in Figure 5(a), when the length of the chamber 200 is 2.5m, the water level of the measurement target facility 10, which is the actual water level, is 500mm, the water level measured by the developed sensor measured by the pressure measuring unit 110 is 500mm. It can be seen that it is measured at about 597mm, and when the water level of the measurement target facility 10 is 1000mm, the water level measured by the developed sensor measured by the pressure measurement unit 110 is about 1194mm, and the water level of the measurement target facility 10 is 1500mm. The water level measured by the developed sensor temporarily measured by the pressure measuring unit 110 is about 1790 mm.

Here, the water level measured by the development sensor and the actual water level can each be displayed as a linear graph as a proportional relationship, and the matching rate (R ₂ ) in which the value of the water level measured by the development sensor according to the actual water level is distributed on a linear graph can be derived. You can.

At this time, the value of the matching rate R ² can be set to 0.9996, where R ² is the matching rate, and the matching rate can mean the accuracy between the actual water level and the water level value measured by the developed sensor. The matching rate is as high as 99%, It can be confirmed that the measured water level (L2) and the water level of the measurement target facility (10) are formed in a linear form and are formed at the same ratio.

As shown in FIG. 5(b), when the length of the chamber 200 is 3.5 m and the water level of the measurement target facility 10, which is the actual water level, is 500 mm, the water level measured by the developed sensor measured by the pressure measuring unit 110 is 500 mm. It is about 639mm, and when the water level of the measurement target facility (10), which is the actual water level, is 1000mm, the water level measured by the developed sensor measured by the pressure measurement unit 110 is about 1279mm, and the water level of the measurement target facility (10), which is the actual water level, is 1500mm. The water level measured by the development sensor temporarily measured by the pressure measuring unit 110 may appear to be approximately 1919 mm.

Here, the water level measured by the development sensor and the actual water level can each be displayed as a linear graph as a proportional relationship, and the matching rate (R ₂ ) in which the value of the water level measured by the development sensor according to the actual water level is distributed on a linear graph can be derived. You can.

At this time, the value of R ² can be set to 0.9999, where R ² is the matching rate, which can mean the accuracy between the actual water level and the water level measured by the developed sensor. The matching rate is as high as 99%, so the measured water level (L2) and the measurement It can be confirmed that the water level of the target facility 10 is formed linearly and at the same rate.

The calculated water level calculated in FIG. 5 can be corrected using a correction coefficient by the circuit unit 120 to derive the actual water level (L1), and the actual water level (L1) can be transmitted to the communication unit 130, and the communication unit ( The actual water level (L1) delivered to 130) can be converted into a graph according to changes in the water level and received on the user terminal. At this time, if the matching rate of the graph formed through the user terminal deviates from the set matching rate, it is judged to be an error in the non-contact pressure type water level sensor, and a notification is generated on the user terminal so that the user can inspect the facility. In addition, when the value of the actual water level (L1) exceeds the set water level, an alarm is generated on the user terminal to prevent flooding of the measurement target facility (10) in situations such as floods and to inspect the measurement target facility (10). can

Figure 6 is a graph showing corrected water level conversion data and measured water level data according to rainfall, and it can be seen that water level conversion data is measured according to changes in rainfall.

The non-contact pressure water level measurement method includes the steps of: (a) inputting environmental information, which is information about the environment within the measurement target facility, into the circuit unit; (b) the pressure measuring unit measures the pressure inside the chamber, and the circuit unit measures the measured water level (L2), which is the water level inside the chamber, using the measured pressure value; (c) deriving a calculated water level, which is a water level calculated by the circuit unit, using the environmental information, the design information of the chamber, and the measured water level (L2); and (d) the circuit unit calculates a correction coefficient, which is a correction value for the operation water level, using the pre-stored correction data, the environmental information, and the design information of the chamber, and corrects the operation water level using the correction coefficient, thereby providing excellent performance. A step in which the actual water level (L1) of is derived may be included.

In step (a), environmental information of the measurement target facility 10 may be collected, and the environmental information includes the temperature of the measurement target facility 10, the pressure inside the measurement target facility 10, and the measurement target facility 10. ) may include the area of the water surface, etc., and may include environmental information within the various measurement target facilities (10), such as water quality and flow rate of rainwater.

At this time, the temperature of the measurement target facility 10 can be measured by the temperature sensor 150, the measured temperature value measured by the temperature sensor 150 can be transmitted to the circuit unit 120, and the measurement target facility 10 ) The internal pressure is measured by a pressure sensor, and the measured pressure value obtained thereby can be transmitted to the circuit unit, and the area of the water surface within the measurement target facility (10) is determined by the vision sensor installed inside the measurement target facility (10). It can be measured and transmitted to the circuit unit 120.

Here, measuring the area of the water surface within the measurement target facility 10 by imaging the rainwater surface within the measurement target facility 10 using a vision sensor and performing image analysis is a prior art, and a detailed description thereof will be omitted. . The rainwater surface area within the measurement target facility 10 may be input by the user.

After step (a) is performed, the pressure measuring unit 110 in step (b) measures the pressure inside the chamber 200, and the circuit unit 120 uses the measured pressure value to measure the pressure inside the chamber 200. A step of measuring the measurement water level (L2), which is the water level, may be performed.

In step (b), the pressure measuring unit 110 is combined with one end of the chamber 200 and can be positioned in a non-contact state with rainwater, and the inside of the chamber 200 changes depending on the level of rainwater in the measurement target facility 10. The change in pressure inside the chamber 200 due to a change in water level can be measured.

The pressure measuring unit 110 and the circuit unit 120 are electrically connected, so that the pressure change data of the chamber 200 measured by the pressure measuring unit 110 is transmitted to the circuit unit 120, and the measured pressure information is transmitted to the circuit unit 120. ) can be converted to water level information. This allows the measurement level (L2) to be measured. At this time, the measured water level L2 may be generated by calculating the average pressure based on the pressure value of the measurement point received from the pressure measuring unit 110.

In step (b), the measurement water level data, which is data about the measurement water level (L2) according to the change in the internal air pressure of the chamber 200, is stored in advance in the circuit unit 120, and the circuit unit 120 is transferred from the pressure measurement unit 110 to the circuit unit 120. ), when the pressure change data is transmitted, a measured water level value that matches the pressure information measured from the measured water level data can be derived.

Here, the measured water level data may be data derived and organized in advance through multiple experiments using the non-contact pressure-type water level sensor of the present invention.

After step (b) is performed, step (c), the step of deriving the calculated water level, which is the water level derived by the circuit unit 120 using the design information of the chamber 200 and the measured water level (L2), is performed. It can be.

In step (c), the design information may include one or more of the length of the chamber 200, the cross-sectional area of the flow path of the chamber 200, and the burial depth of the chamber 200. The length (D1) of the chamber 200 can be input by the user and transmitted to the circuit unit 120, and the burial depth (D2) of the chamber 200 is determined by the distance sensor 250 at the other end of the chamber 200. It is attached to measure the distance between the other end of the chamber 200 and the measurement target facility 10 and transmit the measured value of the burial depth (D2) to the circuit unit 120.

Here, as shown in Figures 5 (a) and (b), calculated water level data, which is data about the relationship between the measured water level and calculated water level according to the length of the chamber 200, is stored in advance in the circuit unit 120, and the circuit unit In (120), when the measured water level is derived as described above, the measured water level is compared with the calculated water level data, and a calculated water level value matching the measured water level can be derived from the calculated water level data.

Here, the calculated water level data may be data derived and organized in advance through multiple experiments using the non-contact pressure-type water level sensor of the present invention.

By the same principle as the linear graph generated according to the length of the chamber 200 above, the cross-sectional area of the flow path within the chamber 200 can be made the same. However, it goes without saying that calculated water level data can be formed using the channel cross-sectional area as another variable. However, in the description of the embodiment of the present invention, only the case where the length of the chamber 200 is different will be described for convenience of understanding.

After step (c) is performed, the circuit unit 10 in step (d) calculates a correction coefficient, which is a correction value for the operation water level, using the pre-stored correction data, the environmental information, and the design information of the chamber 200, and , the actual water level (L1) of rainwater can be derived by correcting the calculated water level using the correction coefficient.

In step (d), correction data, which is data about correction coefficients according to each information in the environmental information and each information in the design information, may be stored in advance in the circuit unit 120, and may be transmitted or received from the circuit unit 120. A matching correction coefficient value can be derived from the correction data using each piece of information in the stored environmental information and each piece of information in the design information.

Here, the correction data may be data derived and organized in advance through multiple experiments using the non-contact pressure-type water level sensor of the present invention.

In detail, it is possible to compare environmental information and design information such as the temperature of the measurement target facility 10, the length of the chamber 200, and the burial depth of the chamber 200 with the information values stored in the previously stored correction data, and the environmental information and By comparing design information and previously stored correction data, correction coefficients corresponding to the environmental information and design information can be derived.

The calculated water level can be corrected using the correction coefficient derived by the circuit unit 120, and when the calculated water level is corrected, measurement errors due to the environment of the measurement target facility 10 are corrected, and the actual water level of rainwater (L1) is derived. It can be. Specifically, the actual water level can be derived by multiplying the calculated water level obtained as above by the correction coefficient value.

Because of this, by comparing previously stored correction data with environmental information and design information, a new correction value can be derived according to the environment in which the non-contact pressure type water level sensor is installed. As a result, without the need to develop a new water level sensor, existing water level sensors can be calibrated and applied to various external environments to measure water level values with minimal measurement errors.

After step (d) is performed, step (e), which is the step of receiving the corrected water level information to the user terminal, may be performed. In step (d), the corrected water level information can be transmitted to the user terminal by the communication unit 130. At this time, the communication unit 130 can receive data from the user terminal in real time, so the user can check data in real time.

Additionally, the water level conversion data transmitted to the communication unit 130 may be converted into a graph according to changes in the water level and received on the user terminal. At this time, when the value of the slope formed through the user terminal is greater than the value of the set slope, it is determined that the water level is abnormal, and a notification is generated on the user terminal to allow the user to inspect the facility.

The description of the present invention described above is for illustrative purposes, and those skilled in the art will understand that the present invention can be easily modified into other specific forms without changing the technical idea or essential features of the present invention. will be. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. For example, each component described as unitary may be implemented in a distributed manner, and similarly, components described as distributed may also be implemented in a combined form.

The scope of the present invention is indicated by the patent claims described below, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention.

10: Measurement target facility
110: pressure measuring unit
120: circuit part
130: Department of Communications
140: battery
141: solar panel
150: Temperature sensor
160: housing
200: chamber
210: fixed chamber
211: Fixed step
212: fixing screw
220: Mobile chamber
221: moving step
222: extension body
230: filter
240: Water quality sensor
250: Distance detection sensor
260: flow sensor
D1: Chamber length
D2: Burial depth

Claims (12)

In the non-contact pressure type water level sensor that measures the water level of rainwater flowing into the measurement target facility,
A housing having a space therein;
a chamber coupled to the housing and at least a portion of which is inserted into rainwater;
a pressure measuring unit that is inserted into the housing and coupled to the chamber and measures the internal pressure of the chamber; and
Receives the pressure information measured by the pressure measuring unit, converts the pressure information measured by the pressure measuring unit to the measured water level, and corrects and calculates the measured water level using real-time design information corresponding to the previously stored calculated water level data. A circuit unit that derives the water level, calculates a correction coefficient in real time using real-time environmental information and the design information corresponding to pre-stored correction data, and derives the actual water level by multiplying the correction coefficient by the calculated water level;
A temperature sensor attached to the other end of the chamber and measuring the temperature of the rainwater in real time, a distance sensor attached to the other end of the chamber and measuring the burial depth between the other end of the chamber and the measurement target facility in real time, and a distance sensor attached to the other end of the chamber to measure the buried depth between the other end of the chamber and the measurement target facility in real time. It is attached and further includes a flow sensor that measures the flow rate of the rainwater in real time,
The circuit unit measures the environmental information of the measurement target facility measured by the temperature sensor, the distance sensor, and the flow sensor in real time and forms the correction coefficient in real time.
In claim 1,
A non-contact pressure type water level sensor, characterized in that the chamber is separated from or combined with the housing.
In claim 2,
A non-contact pressure type water level sensor, characterized in that the chamber is replaced according to the height of the measurement target facility.
delete In claim 1,
The housing is,
A non-contact pressure type water level sensor further comprising a communication unit that is inserted into the housing, is electrically connected to the circuit unit, receives the actual water level corrected with the correction coefficient, and receives the actual water level.
In claim 1,
A non-contact pressure water level sensor, wherein the chamber is made of one or more materials selected from stainless steel, plastic, and PVC.
In claim 1,
A non-contact pressure type water level sensor, wherein the pressure measuring unit is coupled to one end of the chamber and does not come into contact with rainwater.
In claim 1,
The chamber is,
A non-contact pressure type water level sensor, further comprising a filter that is coupled to the other end of the chamber and prevents the inflow of suspended matter.
In claim 1,
A non-contact pressure type water level sensor, characterized in that the cross section of the chamber in a direction parallel to the ground is circular.
In the non-contact pressure-type water level measurement method using a non-contact pressure-type water level sensor according to one selected from claims 1 to 9,
(a) inputting the environmental information, which is information about the environment within the measurement target facility, into the circuit unit;
(b) the pressure measuring unit measures the pressure inside the chamber, and the circuit unit measures the measured water level, which is the water level inside the chamber, using the measured pressure value;
(c) deriving the calculated water level, which is a water level derived by using the design information of the chamber and the measured water level, in the circuit unit; and
(d) The circuit unit calculates the correction coefficient, which is a correction value for the operation water level, using the pre-stored correction data, the environmental information, and the design information of the chamber, and corrects the operation water level using the correction coefficient. A non-contact pressure type water level measurement method comprising: deriving the actual water level of rainwater.
In claim 10,
The environmental information is a non-contact pressure-type water level measurement method, characterized in that it includes the temperature of the measurement target facility, the pressure inside the measurement target facility, and the area of the water surface within the measurement target facility.
In claim 10,
The design information includes one or more of the length of the chamber, the cross-sectional area of the flow path of the chamber, and the buried depth of the chamber.

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