KR101491112B1 - Apparatus for measuring water level of reservoir - Google Patents

Abstract

The present invention relates to an apparatus to measure a water level of a reservoir and, more specifically, to an apparatus to measure a water level of a reservoir which installs an insertion rod on an inclined surface of a reservoir weir, and connects a pressure sensor to a wire circulated along the insertion rod to circulate the wire, such that the pressure sensor may easily be inserted deep to measure a water level and be raised; thereby being easily installed, maintained, and repaired. According to the present invention, an apparatus to measure a water level of a reservoir includes: a long insertion rod installed in an inclined surface of a reservoir weir by having one end portion inserted underwater along the inclined surface of the reservoir weir; a circulating wire hung on a wire support unit disposed on one end portion of the insertion rod to have both parts extended toward the other end portion of the insertion rod along the insertion rod; and a pressure sensor attached to the circulating wire to be moved from the other end portion to one end portion of the insertion rod by a one-way circulation of the circulating wire in order to be inserted underwater, and moved from one end portion to the other end portion of the insertion rod by the other-way circulation of the circulating wire to be raised above the water.

Description

[0001] APPARATUS FOR MEASURING WATER LEVEL OF RESERVOIR [0002]

The present invention relates to a reservoir level meter, and more particularly, to a reservoir level meter, in which a charging rod is installed on an inclined surface of a reservoir bank, a pressure sensor is connected to a circulating wire along the charging rod, To a water level meter for easy installation and maintenance.

In order to maintain the quality and quantity of agricultural products, irrigation is required to artificially supply deficient water from irrigation facilities such as reservoirs and pumping stations in addition to rainwater. In recent years, the need for scientific and efficient management of agricultural reservoirs due to frequent droughts and floods has been urgently needed in Korea, along with the global deepening of water shortage.

In addition to the agricultural water supply, which is the original function of the agricultural reservoir, it is essential to accurately measure the water level of the reservoir and the accumulated water quantity in order to prevent flood prevention. Accurate and reliable low- Based on this, it is used as judgment data of water management by grasping the amount of water storage and the rate of water storage.

The water gauge developed for reservoir water level measurement is divided into sub-land, pressure, and ultrasonic. The buoy equation is a method of measuring the water level by the height of the buoy, and the ultrasonic method is a method of measuring the distance of the water surface by installing it in the same facility as the water intake tower.

However, the buoy equation has a disadvantage in that it is difficult to measure the water level accurately and reliability of data is poor, and the ultrasonic method requires a facility such as a water intake tower, which requires a large installation cost. On the other hand, the pressure equation is a method in which a pressure sensor is installed in the water and the water level is measured by the pressure change according to the change of the water level, and the installation cost is relatively low and accurate. Therefore, the pressure sensor Recently, the introduction of the water level measurement method using the pressure sensor is increasing as in the water level observation system.

In the pressure type, the pressure sensor should be inserted to the depth of the bottom of the reservoir. Normally, the pressure sensor is installed below the slope of the reservoir and the pressure sensor is placed below the water surface. However, it is difficult to put the pressure sensor under the water surface at a desired position, and it is difficult to put the pressure sensor back into the original installation position when the pressure sensor is reinstalled for maintenance after charging.

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus and a method for disposing a charging rod on a slope of a reservoir bank, connecting a pressure sensor to a wire circulating along the charging rod, The present invention is intended to provide a water level gauge which can be easily inserted into and taken out of a pressure sensor for a depth measurement to facilitate installation and maintenance.

Yet another object of the present invention is to provide a water level gauge capable of preventing the pressure sensor from being damaged by locating the pressure sensor in the inside of the tube by forming the input rod into a tube and circulating the wire inside the tube will be.

Another object of the present invention is to provide a buoy to the tip of a loading rod, adjust the position of the loading rod from the bottom of the reservoir to the water surface, remove buoys, and sink the tip of the loading rod below the water surface, The present invention relates to a water level gauge,

According to another aspect of the present invention, there is provided a reservoir water level meter for measuring a reservoir water level, the reservoir water level meter comprising: A circulation wire which is hooked on a wire support part provided at one end of the insertion rod and which is bent at both ends and extends to the other end of the insertion rod along both ends of the insertion rod; And a pressure sensor which is moved from the other end of the charging rod to the one end and charged down to the water surface and is moved from one end of the charging rod to the other end by the other circulation of the circulating wire and taken out to the surface of the water.

According to another aspect of the present invention, there is provided a water level gauge according to the present invention, wherein the charging rod is formed of a tubular body having a long length and has a flow hole formed at one end thereof, the wire support portion is formed inside a tube at one end of the charging rod, Is inserted into the tube of the charging rod and circulated inside the tube.

In the reservoir level meter according to the present invention, the circulation wire is provided with a latch stopper at a position prior to the pressure sensor based on the circulation direction in the direction in which the pressure sensor is inserted below the water surface, The pressure sensor is circulated in a direction in which the pressure sensor is moved from the other end of the charging rod toward the one end so that the locking stopper is circulated to the position where the locking stopper is caught by the wire supporting portion.

Further, in the reservoir water level meter according to the present invention, a rope supporting portion is provided on one end side and the other end side of the charging rod, and one of two forks is hooked on the rope supporting portion, And a buoyant body attached to the other of the forkings of the circulating rope, wherein the buoyant body is moved to one end side of the charging rod to catch the circulating rope And the loop is loosened so that the charging rod is dropped down to the surface of the water by the weight of the charging rod to be installed on the slope of the reservoir bank.

According to the above-described structure, the reservoir level meter according to the present invention is characterized in that a charging rod is installed on an inclined surface of a reservoir bank, and a pressure sensor is connected to a wire circulating along the charging rod to circulate the wire, So that it is easy to install and maintain.

Further, the reservoir level meter according to the present invention has an advantage that the pressure sensor can be prevented from being damaged due to the pressure sensor being located inside the tubular body by forming the input rod as a tubular body and circulating the wire inside the tubular body.

In addition, a reservoir level meter according to the present invention is characterized in that a buoy is provided at the tip of a charging rod, the charging rod is moved from the reservoir bank to the water surface to adjust its position and the buoy is removed to sink the tip of the charging rod below the water level, Can be easily installed.

1 is a view conceptually showing a reservoir level observation system to which a reservoir level meter according to an embodiment of the present invention is applied
FIG. 2 is a cross-sectional view illustrating a reservoir water level meter according to an embodiment of the present invention
FIG. 3 is a side view illustrating a flow sensor of a reservoir level observation system to which a reservoir level meter according to an embodiment of the present invention is applied.
4A and 4C are diagrams illustrating a process of installing a reservoir level meter according to an embodiment of the present invention

Hereinafter, a reservoir water level meter according to the present invention will be described in detail with reference to embodiments shown in the drawings.

FIG. 1 is a conceptual view of a reservoir level monitoring system to which a reservoir level meter according to an embodiment of the present invention is applied, FIG. 2 is a detailed sectional view of a reservoir level meter according to an embodiment of the present invention, FIG. 3 is a side view illustrating a flow sensor of a reservoir level monitoring system according to an embodiment of the present invention in detail. FIGS. 4A and 4C are views for explaining the installation of a reservoir level meter according to an embodiment of the present invention. FIG.

The reservoir level meter 10 according to the present invention can be used in a reservoir level monitoring system for measuring and managing reservoir level.

First, a water level monitoring system using a water level meter 10 according to the present invention will be described with reference to FIGS. 1 and 3. FIG. 1 is a system for measuring and managing the level of a reservoir. The system includes a water level meter 10 according to the present invention and includes a water level observation control panel 20, a flow rate sensor 30, a management server 41 and a management terminal 42.

The level gauge 10 according to the present invention is for measuring the level of a reservoir and can be used in a reservoir level monitoring system as described above.

The water level meter (10) according to the present invention is provided with a pressure sensor (13) installed below the water surface of the reservoir to sense the water pressure in order to measure the water level of the reservoir. In order to accurately measure the water level of the reservoir, the pressure sensor 13 is inserted into the bottom of the reservoir and fixed at a predetermined position. The water level meter 10 according to the present invention drops the pressure sensor 13 below the reservoir water surface And the input rod 11 is used to fix the pressure sensor 13. That is, according to the present invention, in the state where the pressure sensor 13 is fixed to one end of the rod 11, which is a rod member having a long length, one end of the rod 11 is connected to the bottom of the reservoir So that the pressure sensor 13 is placed below the surface of the reservoir and is fixed below the surface of the reservoir. The pressure sensor 13 is attached to the circulating wire 12 so as to maintain and replace the pressure sensor 13. The pressure sensor 13 is circulated from one end to the other end of the input rod 11, The structure is such that only the pressure sensor 13 can be pulled out above the water surface in the state where the rod 11 is provided on the inclined plane S of the reservoir bank B and can be put back.

The input rod 11 is a rod-shaped member having one long end which is inserted into the sloped surface S of the reservoir bank B, one end of which is inserted below the water surface along the sloped surface S of the reservoir bank B. The slope S on which the slurry S is installed is formed with a slurry support rod Sf so that the slurry S is not buried in the sediment deposited on the slope S.

The input rod 11 may be a rod-shaped member having a long length, but it may be a pressure sensor 13 installed at one end thereof, a sensor cable 131 wired along the input rod 11, The supporting rod 11 formed of a tubular body will be described in detail below. Referring to FIG. 1, a pressure sensor 13 is installed in one end of a tubular input rod 11, and the circulating wire 12 is circulated into the tubular body. The sensor cable 131 connected to the observation control panel 20 is also passed.

A pressure sensor 13 is disposed inside the one end of the charging rod 11 so as to be inserted below the water surface and a flow hole 111a through which the water flows can be measured by the pressure sensor 13, (11). In addition, a wire support 113 for supporting the circulation wire 12 is provided at one end of the support 11 for circulation of the circulation wire 12. Referring to the drawing, the wire support part 113 is formed as a U-shaped pipe so as to reduce the friction with the circulation wire 12 and to prevent the circulation wire 12 from being detached. The circulating wire 12 is supported by the wire supporting part 113 so as to pass through the U-shaped pipe. The wire support portion 113 and the pressure sensor 13 are located inside the one end of the input rod 11 and the input rod 11 is provided at one end of the input rod 11, A casing 111 having a larger diameter than the body of the casing 111 is connected to the casing 111 and the wiper section 113 and the pressure sensor 13 are positioned inside the casing 111. [

The other end of the input rod 11 provided with one end where the pressure sensor 13 is located is inserted below the water surface is exposed on the water surface along the inclined surface S and the end of the other end is connected to the axial tube coupler 112 To the piping casing (22). The axial tube coupler 112 is a tubular body having a short length in a shape of being short-circuited at one end to the other end so as to connect the input rod 11 having a large diameter and the pipe casing 22 having a small diameter. The pipe casing 22 is configured to provide a passage through which the sensor cable 131 passing through the input rod 11 leads to the water level control panel 20 and is connected to the input rod 11 at one end, Is connected to the water level control panel (20).

The circulation wire 12 is configured to insert and remove the pressure sensor 13 in a state where the support rod 11 is installed along the inclined surface S for maintenance of the pressure sensor 13. [ Referring to FIG. 1, the circulating wire 12 is hooked on a wire supporting part 113 provided at one end of the insertion rod 11, that is, inside the casing 111, When the circulation wire 12 is pulled on one side of the circulation wire 12 on the water surface, the circulation wire 12 is moved to the other side while being hooked on the wire support 113. The pressure sensor 13 is attached to the circulating wire 12 which is inserted into the tube of the charging rod 11 and circulated inside the charging tube 11 as described above and circulates the circulation wire 12 to the pressure sensor 13) can also move along the inside of the pipe of the input rod (11).

The circulation wire 12 is circulated so that the pressure sensor 13 moving in the insertion rod 11 does not collide with the wire support part 113 and the circulation wire 12 is provided with a latch stopper 12a. That is, the circulation wire 12 is provided with a latch stopper 12a at a position prior to the pressure sensor 13 with reference to the circulation direction in the direction in which the pressure sensor 13 is inserted below the water surface, The wire 12 is circulated in the direction in which the pressure sensor 13 is moved in the direction of one end from the other end of the insertion rod 11 to the position where the engagement stopper 12a is engaged with the wire support portion 113, do. Accordingly, the pressure sensor 13 stops immediately before the wiper support 113 and is positioned inside the casing 111.

The pressure sensor 13 is installed below the water surface, senses the water pressure at the inserted depth, and transmits the sensed value to the water level control panel 20 as an electrical signal. The present invention is characterized in that the pressure sensor 13 is attached to the circulating wire 12 and is inserted into the water surface from one end to the other end of the charging rod 11 by one circulation of the circulating wire 12, Is moved from one end to the other end of the rod (11) by the other circulation of the wire (12) and taken out above the water surface.

The reservoir level meter 10 according to the present invention has a function to measure the level of the slope S when the slurry S is dropped along the slope S, It is possible to take out the input rod 11 in the reverse order to the dropping using the buoyancy body 15 even when the float body 15 is used to float on the water surface and then to unload the input rod 11 as well as to take out the input rod 11 . 4A to 4C conceptually show a process in which the input rod 11 is installed on the inclined plane S by using the buoyant body 15. The buoyant body (15) is attached to the circulating rope (14) and floats on the water surface. The loop rope 14 is hooked by a rope fastening hole 114 provided at one end and the other end of the rod 11 and the buoyant body 15 is attached to the other fork do. In the state that the buoyant body 15 attached to the circulating rope 14 is moved toward the one end side of the charging rod 11, one end of the charging rod 11 is inserted along the water surface. 4A shows the state in which the support rods 11 are positioned near the water surface by placing the buoyant body 15 at one end of the introduction rod 11 in a state in which the circulation rope 14 is pulled tightly. On the other hand, when the circulation rope 14 is loosened in a state floating near the water surface of the support rod 11 as described above, the support rod 11 is dropped by the weight of the support rod 11 below the water surface. 4B shows a state in which the input rod 15 is dropped below the water surface due to the loosening of the circulation rope 14, Respectively. 4C shows a state of pulling the circulation rope 14 in a state where the input rod 15 is seated on the slope S and pulling the buoyancy body 15 in the direction of the reservoir bank B.

As described above, according to the present invention, it is possible not only to use the buoyant body 15 to submerge the charging rod 11 on the water surface so as to easily mount the charging rod 11 on the inclined surface S, It is possible to remove the insertion rod 11 by floating it on the water surface.

In the meantime, when the reservoir level meter 10 according to the present invention is used in a reservoir level monitoring system, the level measured by the reservoir level meter 10 according to the present invention is applied to the level monitoring control panel 12 of the reservoir level monitoring system And transmitted to the management server 41 or management terminal 42. That is, the water level value is calculated from the pressure value or the pressure value transmitted from the pressure sensor 13 of the reservoir level meter 10 according to the present invention, and the water level value is calculated by the water level observation control panel 12 from the management server 41 or the management terminal 42. The water level control panel 20 receives the flow rate of the water overflowing the overflow gate F formed at the upper end of the reservoir bank B with a full water level from the flow rate sensor 30 and transmits the value to the management server or the management terminal. On the other hand, the water level control panel 20 is programmed to correct the error with respect to the water level using the water level information at the instant when the reservoir is full so as to correct the error of the pressure sensor 13 caused by passage of time or the like. More specifically, the water level observation control panel 20 senses a moment when the water flows from the flow rate sensor 30 to the overflow gate F, which will be described later, (I.e., the water level value of the high water level) corresponding to the pressure value of the pressure sensor 13 sensed by the pressure sensor 13.

Meanwhile, in the reservoir level monitoring system using the reservoir level meter 10 according to the present invention, the flow rate sensor 30 for detecting the overflowing water level of the reservoir bank B and allowing the manager to confirm the flow rate The flow sensor 30 is installed at the upper end of the reservoir bank at the overflow gate F so that the water is swollen. The flow rate sensor 30 measures a flow rate of the water flowing through the overflow gate F and transmits the measured flow rate to the level control panel 20. The flow sensor 30 is configured to measure a simple and precise flow rate using a tilt sensor 33, and FIG. 3 shows the flow sensor in detail. 3, a case 31 having an inflow hole 311 for inflow of water to cool water flowing through the overflow gate F is formed at a lower portion of the case 31, The hinge 312 is hinged to the hinge 312 and the other end is attached to the water inlet 322 so that the hinge 322 is moved up and down according to the water level of the water hitting the inside of the case 31, And a tilt sensor 33 attached to the tilt bar 32 for measuring a tilt value of the tilt bar 32. The tilt bar 32 is disposed on the tilt bar 32, Since the tilt bar 32 varies depending on the water level of the water flowing into the case 31, the tilt value measured by the tilt sensor 33 contains information about the water head discharged through the overflow gate F . Accordingly, the water level control panel 20 calculates the flow rate of the water discharged through the overflow gate F. FIG. That is, the water level control panel 20 includes information on the head of water discharged through the overflow gate F transmitted in the form of a slope value transmitted from the tilt sensor 33 through the sensor cable 331, The flow rate can be calculated from the width value of the overflow gate F.

10 water level meter
11 input rod
12 circulating wire
13 Pressure sensor
14 Circular rope
15 buoyancy
20 water level observation control panel
30 Flow sensor
31 cases
32 Rotary lever
33 tilt sensor
41, 42 Management server and management terminal

Claims (4)

1. A reservoir level meter for measuring a reservoir level,
A long input rod which is inserted along the slope of the reservoir dam and whose one end is inserted below the water surface and is installed on the slope of the reservoir dam,
A circulation wire which is hooked on a wire supporting part provided at one end of the charging rod and which is bent at both ends of the charging rod along the charging rod,
The circulating wire is attached to the circulating wire and is moved from one end to the other end of the circulating wire by the one circulation of the circulating wire so as to be inserted below the water surface and is moved from one end to the other end by the other circulation of the circulating wire, Characterized in that the pressure sensor is provided with a low pressure sensor. The method according to claim 1,
Wherein the charging rod is formed of a tubular body having a long length and has a flow hole formed at one end thereof,
The wire supporting part is formed inside the tube at one end of the charging rod,
Wherein the circulating wire is inserted into the pipe of the charging rod and circulated inside the pipe. 3. The method according to claim 1 or 2,
Wherein a stopper is attached to the circulating wire at a position ahead of the pressure sensor with respect to a circulation direction in a direction in which the pressure sensor is injected below the water surface,
Wherein the circulation wire is circulated in a direction in which the pressure sensor is moved from the other end of the charging rod toward the one end so as to be circulated to a position where the engagement stopper is caught by the wire support portion. 3. The method according to claim 1 or 2,
A rope support portion is provided on one end side and the other end side of the input rod,
Wherein the water level measuring device is provided with a circulation loop in which one of the two forks is hooked on the rope supporting portion and the fork extends along the introducing rod to the other end of the introducing rod and a buoyancy Further,
The float rod is moved in a state in which the float body is moved toward the one end side of the rod and the loop is pulled in the vicinity of the water surface along the water surface in a state where the loop is pulled and then the loop rod is loosened, And is installed on an inclined surface of the reservoir weir.

Images