KR101434337B1 - Apparatus for measuring water level - Google Patents

Abstract

An apparatus for measuring a water level according to the present invention includes: a buoy including an edge formed at a side thereof; a buoy housing which receives the edge of the buoy therein and supports the buoy so that the buoy housing may vertically move together with the edge of the buoy; an auxiliary housing installed at one side of the buoy housing; at least one switch signal generator vertically installed inside the auxiliary housing at every vertical interval, making contact with the edge of the buoy in a state where a switch edge connected to an internal switch is received in the buoy housing, and generating and transmitting a signal to a water level measuring unit according to an operation of the switch edge; and the water level measuring unit which measures a current water level according to a signal received from the switch signal generator.

Description

[0001] APPARATUS FOR MEASURING WATER LEVEL [0002]

The present invention relates to a water level measuring apparatus, and more particularly, to a water level measuring apparatus that automatically detects a current position of a buoy through an optical sensor, a switch circuit, and the like, and measures a current water level through the detected position information of the buoy.

The water level meter is usually installed in a river or a lake to measure the water level. The measured water level data can predict the occurrence of flood due to the summer rainfall. Especially, when there is a bridge in the river, it is used as an index to control the traffic of the ship passing through the bridge for safety at a certain level above the water level.

Generally, a water level table is called a skeleton or a building. It measures the height of water for leveling. It can be installed on slopes such as rivers, reservoirs, shore, etc. and on the banks and piers. , The quantity and the water level can be easily grasped and it is aimed to gain a lot of help to prepare for the flood or the flood of the river.

Such a water table is composed of a rectangular wood plate, an iron plate or an aluminum plate, and markings such as a scale and a numeral are displayed as general paint such as waterproof paint on the front surface thereof. In order to supplement it, iron plate or aluminum plate may be used on a wood plate, or it may be composed of only an iron plate or an aluminum plate.

The water level measurement through the water level table is implemented in such a manner that the difference between the reading value measured through a scale marked on a wood board or an aluminum plate installed on a bridge pier and the water level measured through an ultrasonic sensor is corrected. However, this method is highly likely to cause a large and continuous error between the indicated values depending on the sensor position, distance, and other surrounding environmental conditions.

In addition, the method of manually reading the scale or operating the sensor is not only troublesome but also involves the danger that a person must move close to a river or a pier which is likely to flood when a flood occurs. Therefore, development of a device capable of measuring a water level corresponding to a bridge pier in a simpler and more precise manner is required.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a water level measuring apparatus which automatically detects a current position of a buoy through an optical sensor or a switch circuit and measures a current water level based on the detected position information of the buoy, The purpose is to provide.

According to an aspect of the present invention, there is provided a level measuring apparatus comprising: a buoy having an edge formed on one side thereof; A buoy housing for supporting the buoy so that the buoy edge is accommodated therein and the buoy moves up and down with the edge according to a water level; An auxiliary housing installed at one side of the buoy housing; A switch edge which is installed in each of the upper and lower predetermined intervals inside the auxiliary housing and is connected to an internal switch is received in the buoy housing and is formed to be in contact with the buoy edge and generates a signal according to the operation of the switch edge One or more switch signal generators for transmitting to a level measuring unit; And a water level measuring unit for measuring a current water level according to a signal received from the switch signal generator.

In the level measuring apparatus according to the present invention, each of the switch edges of the one or more switch signal generators performs a seesaw motion according to the movement of the buoy edge, and each of the switch signal generators is turned on The ON signal is generated and transmitted to the level measuring unit. In the OFF state, generation and transmission of the ON signal are stopped.

Further, in the level measuring apparatus according to the present invention, the level measuring unit may maintain a level data table in which one or more switch signal generator identifiers and level data corresponding to the respective switch signal generator identifiers are recorded, The controller reads the transmitted switch signal generator and measures the water level at the current point through the water level data corresponding to the read switch signal generator.

According to the water level measuring apparatus of the present invention, the water level can be measured more accurately and conveniently by a simple configuration for detecting the current position of the buoy through the optical sensor or the switch circuit.

According to the water level measuring apparatus of the present invention, it is possible to measure an accurate water level according to current conditions without being affected by changes in the surroundings such as the location of sediments accumulated on a river or a river floor, the position of a shepherd, Can be obtained.

Further, according to the water level measuring apparatus of the present invention, since the shepherd and the sensor for measuring the water level are integrally provided, it is possible to measure the water level more accurately by minimizing the error caused by the distance depending on each position or by human eyes The effect can be obtained.

1 is a view showing a configuration of a water level measuring apparatus according to an embodiment of the present invention.
FIG. 2 is a view showing a level table according to the present invention. FIG.
3 is a view showing a configuration of a water level measuring apparatus according to another embodiment of the present invention.
4 is a view showing a configuration of a water level measuring apparatus according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a configuration of a water level measuring apparatus according to an embodiment of the present invention.

The level measuring apparatus according to an embodiment of the present invention includes a buoy housing 110, a buoy 120, an optical sensor unit, and a water level measuring unit 150. The buoy housing 110 may be implemented as a column or sheath with a space formed therein. On the surface of the buoy housing 110, a ruler 112 for level measurement can be shown. The buoy housing 110 may be attached to a bridge pier or may be implemented as a stand-alone device.

The upper and lower ends of the buoy housing 110 may have an open shape. External water can be introduced into the internal space of the buoy housing 110 through the open top and bottom openings. In addition, one or more perforations 111 may be formed on the side surface of the buoy housing 110. The water level of the river or river and the water level of the inner space of the buoy housing 110 are always at the same level (for example, Lt; / RTI >

The buoys 120 are accommodated in the inner space of the buoy housing 110. The buoys 120 are manufactured to have floating properties and can be moved up and down according to the water level change in the buoy interior 110 space. The sizes of the buoys 120 may be realized to correspond to the installation intervals of the light emitting sensors 131 to 135 and the light receiving sensors 141 to 145. That is, the intervals between the light emitting sensors 131 to 135 and the light receiving sensors 141 to 145 can be set to a predetermined minimum length for the water level measurement. Even if the buoy 120 is at any position, A size set to overlap with the position of the light receiving sensor. Also, the buoy 120 may be implemented as an opaque material that does not transmit light.

The optical sensor unit includes a first auxiliary housing 130, at least one light emitting sensor 131 through 135, a second auxiliary housing 140, and at least one light receiving sensor 141 through 145.

The first auxiliary housing 130 may be installed on one side of the buoy housing 110. The first auxiliary housing 130 may be configured to be shielded from the outside to prevent water from being introduced into the first auxiliary housing 130. The first auxiliary housing 130 may be formed of a material through which light is transmitted. One or more light emitting sensors 131 to 135 are accommodated in the first auxiliary housing 130. In this specification, for convenience of explanation, the case where the first to fifth light emitting sensors 131 to 135 are housed in the first auxiliary housing 130 will be described as an example.

The first to fifth light emitting sensors 131 to 135 may be installed at predetermined intervals. The interval may be implemented at an interval set by the administrator to measure the water level. The interval between the sensors may be equal to each other, or the intervals between the sensors may be different from each other. The first light emitting sensor 131 to the fifth light emitting sensor 135 can emit light at predetermined intervals. The light irradiation direction may be realized in the direction of the second auxiliary housing 140 and one or more light receiving sensors 141 to 145 provided on the buoy housing 110 and the other side of the buoy housing 110.

The second auxiliary housing 140 may be installed on the other side of the buoy housing 110. The second auxiliary housing 140 may be installed 180 degrees away from the position of the buoy housing 110 where the first auxiliary housing 130 is installed. The second auxiliary housing 130 may be configured to be shielded from the outside to prevent water from being introduced into the second auxiliary housing 130. The second auxiliary housing 140 may be formed of a material through which light is transmitted. One or more light receiving sensors 141 to 145 are accommodated in the second auxiliary housing 140. For convenience of description, the first to fourth light receiving sensors 141 to 145 are accommodated in the second auxiliary housing 140 in this specification.

The first light receiving sensor 141 to the fifth light receiving sensor 145 may be installed at predetermined intervals. The interval may be the same as the interval between the first light emitting sensor 131 and the fifth light emitting sensor 135 installed in the first auxiliary housing 130. That is, the first light receiving sensor 141 to the fifth light receiving sensor 145 internally correspond to the respective light emitting sensors so as to easily receive the light irradiated from the first light emitting sensor 131 to the fifth light emitting sensor 135 Respectively.

The first auxiliary housing 130, the buoy housing 110 and the second auxiliary housing 140 can transmit light when the first light emitting sensor 131 to the fifth light emitting sensor 135 emit light. The first to the fifth light receiving sensors 141 to 145 can receive the irradiated light, respectively. The first light receiving sensor 141 to the fifth light receiving sensor 145 generate a light receiving event signal and transmit the light receiving event signal to the water level measuring unit 150 when the light receiving sensor detects the light receiving light. However, when the buoy 120 is located in the area equivalent to the third light-emitting sensor 133 and the third light-receiving sensor 143 as shown in Fig. 1, the light emitted from the third light- The light receiving sensor 143 can not receive light. Therefore, the third light receiving sensor 143 can not transmit the light receiving event signal to the water level measuring unit 150.

The water level measuring unit 150 measures the current water level through a light receiving event signal received from each light receiving sensor. To this end, the level measuring unit 150 maintains a level data table as shown in FIG. In the level data table 200, one or more light receiving sensor identifiers and level data corresponding to the respective light receiving sensor identifiers may be recorded. The water level measuring unit 150 receives the light receiving event signal only from the first light receiving sensor 141, the second light receiving sensor 142, the fourth light receiving sensor 144, and the fifth light receiving sensor 145 And when the light receiving event signal is not received from the third light receiving sensor 143, the water level measuring unit 150 may measure the current water level as the C value corresponding to the third light receiving sensor 143. [

That is, the position of the current buoy 120 can be detected and the current water level corresponding thereto can be measured. The level measuring unit 150 may be connected to the light emitting sensor and the light receiving sensor by wire. In addition, when the current level is measured, the level measuring unit 150 may transmit the measured level information to a remote server or a terminal of the administrator. In addition, the water level measuring unit 150 may include a display unit, which can display information on the currently measured water level through the display unit. Accordingly, the manager checks the level measured visually and the level measured through the buoy 120 through the external ruler 112 of the buoy housing 110 in the field through the display means and compares them with each other, can do.

3 is a view showing a configuration of a water level measuring apparatus according to another embodiment of the present invention.

The level measuring apparatus according to another embodiment of the present invention includes buoys 310 and 311, a buoy housing 320, an auxiliary housing 330, one or more switch signal generators 331 to 335, and a water level measuring unit 340 .

An edge 311 is formed at one side of the buoy 310. The buoy 310 body may be located outside the buoy housing 320 and the edge 311 may be received within the buoy housing 320. The buoy housing 320 can support the buoy edge 311 so that the buoy 310 and the edge 311 can move up and down according to the level of the external river or river. A ruler for measuring the water level can be visually displayed on the surface of the buoy housing (320).

The auxiliary housing 330 is installed on one side of the buoy housing 320. The auxiliary housing 330 may be installed on the opposite side of the buoy 310. The auxiliary housing 330 may be configured to be blocked from the outside to prevent water from being introduced into the auxiliary housing 330. The first switch signal generator 331 to the fifth switch signal generator 335 may be installed within the auxiliary housing 330 at predetermined intervals. The interval may be implemented in units of a minimum circle length for measuring the water level.

Each switch signal generator includes a switch edge. The switch edge may be installed such that one end protrudes out of the auxiliary housing 330 and is accommodated in the buoy housing 320. The switch edge may be installed to seesaw motion. The end of the switch edge may be installed so as to overlap the buoy edge 311. That is, when the buoy edge 311 is moved up and down according to the water level, each switch edge can be implemented such that a force due to the movement of the buoy edge 311 is applied to seesaw motion.

3, when the buoy edge 311 is located in the area corresponding to the fourth switch signal generator 334, the switch edge of the fourth switch signal generator 334 is in contact with the buoy edge 311 And is moved upward. The internal switch of the fourth switch signal generator 334 can be switched to the ON state in accordance with the seesaw motion of the switch edge of the fourth switch signal generator 334. The fourth switch signal generator 334 generates a signal and transmits the signal to the level measuring unit 340. [

The level measuring unit 340 measures the current level according to a signal received from each switch signal generator 334. To this end, the level measuring unit 340 maintains a level table in which one or more switch signal generator identifiers and level data corresponding to the respective switch signal generator identifiers are recorded.

3, only the fifth switch signal generator 335 and the fourth switch signal generator 334 are turned ON when the buoy edge 311 makes a seesaw motion to the switch edge of the fourth switch signal generator 334. [ The first switch signal generator 331, the second switch signal generator 332 and the third switch signal generator 333 are kept in the OFF state, so that the water level measuring unit 340 does not transmit the ON signal. In this case, the water level measuring unit 340 may measure the present water level as a water level value corresponding to the fourth switch signal generator 3340. [

4 is a view showing a configuration of a water level measuring apparatus according to another embodiment of the present invention.

The level measuring apparatus according to another embodiment of the present invention includes a buoy housing 410, a buoy 420, an auxiliary housing 430, at least one hall sensor 431 to 435, and a water level measuring unit 440.

The buoy housing 410 may be implemented as a column or sheath with a space formed therein. On the surface of the buoy housing 410, a ruler 412 for level measurement can be shown. The buoy housing 410 may be attached to a bridge pier or may be implemented as a stand-alone device.

The upper and lower ends of the buoy housing 410 may have an open configuration. External water can be introduced into the internal space of the buoy housing 410 through the open top and bottom openings. In addition, one or more perforations 411 may be formed on the side surface of the buoy housing 410. The water level of the river or river and the water level of the internal space of the buoy housing 410 are always at the same level Lt; / RTI >

The buoy 420 is housed in the inner space of the buoy housing 410. The buoy 420 may be manufactured to have a buoyant property and may be moved up and down according to a change in the level of the buoy interior 410 space. The buoy 420 may be implemented as an opaque material that does not allow transmission of light. A magnetic body 450 may be formed on one side of the buoy 420. The magnetic body 450 may protrude from the outside of the buoy 420 or may be installed inside the buoy 420.

The auxiliary housing 430 is installed on one side of the buoy housing. The auxiliary housing 430 may be configured to be blocked from the outside to prevent water from being introduced into the auxiliary housing 430. One or more Hall sensors 431 to 435 are installed in the auxiliary housing 430 at predetermined intervals. For convenience of explanation, the first hall sensor 431 to the fifth hall sensor 435 are accommodated in the auxiliary housing 430 to be described here.

4, when the buoy 420 and the magnetic body 450 approach the third hall sensor 433, the third Hall sensor 433 generates a high signal in response to the magnetic body 450. [ The third hall sensor transmits the generated signal to the level measuring unit 440. The level measuring unit 440 measures the current level through the signal.

To this end, the level measuring unit 440 maintains a level table in which one or more hall sensor identifiers and level data corresponding to the hall sensor identifiers are recorded. The water level measuring unit 440 receives the signal from the third hall sensor 433 at the first time and outputs the water level data recorded in the water level data table corresponding to the third hall sensor 433 at the first time As shown in FIG. Also, the water level measuring unit calculates the time change amount of water level by time by recording the time at which each hall sensor transmits the signal and the hall sensor corresponding thereto, and transmits a danger alarm message corresponding to the water level change amount to the remote disaster management server or the administrator terminal Lt; / RTI >

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

110: buoy housing
111: Perforation
112: Ruler
120: Buoy
130: first auxiliary housing
131 to 135:
140: Second auxiliary housing
141 to 145: Light receiving sensor
150:

Claims (3)

A buoy on which an edge is formed on one side;
A buoy housing for supporting the buoy so that the buoy edge is accommodated therein and the buoy moves up and down with the edge according to a water level;
An auxiliary housing installed at one side of the buoy housing;
A switch edge which is installed in each of the upper and lower predetermined intervals inside the auxiliary housing and is connected to an internal switch is received in the buoy housing and is formed to be in contact with the buoy edge and generates a signal according to the operation of the switch edge One or more switch signal generators for transmitting to a level measuring unit; And
A water level measuring unit for measuring a current water level according to a signal received from the switch signal generator,
Lt; / RTI >
Wherein each of the switch edges of the one or more switch signal generators performs a seesaw motion according to the movement of the buoy edge, and when each of the switch signal generators turns ON according to a seesaw motion of the switch edge, And stops generation and transmission of the ON signal when it is in the OFF state. delete The method according to claim 1,
Wherein the level measuring unit holds a level table in which level data corresponding to one or more switch signal generator identifiers and level signals corresponding to the respective switch signal generator identifiers are recorded and reads a switch signal generator that most recently transmitted an ON signal, Wherein the water level measuring unit measures the water level at the current point through the water level data corresponding to the signal generator.

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