Patent Description:
Precipitation refers to the depth of water that falls on a horizontal ground surface or a horizontal projection surface of the ground surface within a predetermined period of time and stagnates thereon without being evaporated or discharged.

The above precipitation collectively refers to the amount of rainfall measured after rain has fallen and the amount of snowfall measured after snow, hail and the like have fallen, refers to the depth of the water obtained by melting ice in the case that the precipitation is the ice such as snow, snow pellets, or hail, and includes dew, frost, and fog.

For example, Patent Document <NUM> below discloses a precipitation meter technology for measuring precipitation.

Patent Document <NUM> discloses the configuration of a tipping bucket type precipitation measuring apparatus operated in a seesaw type, in which a bucket for collecting introduced water is divided into left and right buckets, so as to be tilted toward the bucket filled with a certain amount of water around a rotating shaft to selectively discharge the certain amount of water into a drain container.

The above tipping bucket type precipitation meter measures the amount of precipitation by detecting the number of operations of the tipping bucket by using an electric measuring sensor.

However, since the electric measuring sensor is applied, the tipping bucket type precipitation meter as in Patent Document <NUM> is very vulnerable to moisture from the precipitation, and may cause a malfunction due to lightning or the like when it rains.

Meanwhile, an optical fiber sensor refers to a sensor that estimates the amount to be measured by using changes in the intensity of light passing through an optical fiber, the refractive index, length and mode of the optical fiber, and a polarization state, and the like.

Light incident to an optical fiber core is reflected at an interface between a core layer having a high refractive index and a cladding layer having a low refractive index and propagated along the optical fiber core part.

The optical fiber sensor is classified into intensity type, phase type, diffraction grating type, mode modulation type, polarization type, and distribution measurement type according to used effects, and provides various measured values such as voltage, current, temperature, pressure, strain, rotation rate, sound, and gas concentration.

Accordingly, the optical fiber sensor is capable of ultra-precise broadband measurement, is not affected by electromagnetic waves, is capable of easy measurement, does not use electricity in a sensor unit, and has an excellent corrosion resistance due to a silica material, so there is no limit in using environments.

A representative of the optical fiber sensors is a fiber Bragg grating sensor type optical fiber sensor.

The fiber Bragg grating sensor refers to a sensor that uses properties in which a wavelength of light reflected from each Bragg grating varies according to changes in external conditions such as temperature or intensity, after several fiber Bragg gratings are engraved on a single fiber by predetermined lengths.

Accordingly, in the fiber Bragg grating sensor, a light refraction change is triggered in the grating when the optical fiber formed with the grating is deformed due to an action of physical force, and a strain speed of the optical fiber is measured by measuring the above refraction change, thereby measuring the strain speed of a structure to which the optical fiber is fixed, so that loads and stresses acting on the structure may be calculated.

The fiber Bragg grating sensor is formed by changing the refractive index of the optical fiber core part at a predetermined period, and accordingly, selectively reflects only the light having a specific wavelength.

The fiber Bragg grating sensor serving as an excellent physical quantity measuring device having a unique wavelength value and having excellent physical properties such as prevention of being affected by electromagnetic waves, and accordingly, has been replacing the conventional electric gauges, and recently, the applied scope is rapidly increasing.

Accordingly, the fiber Bragg grating sensor is used as a sensor that detects strain, angle, acceleration, displacement, temperature, pressure displacement, and the like, by using the principle of total reflection in which light within a predetermined angle is entirely reflected from an interface therebetween when light proceeds from a material having a high refractive index to a material having a low refractive index in the optical fiber.

For example, the applicant of the present invention has filed applications and received registrations on various technologies using the fiber Bragg grating sensor disclosed in the following Patent Document <NUM>, Patent Document <NUM>, etc..

Accordingly, the development of a technology is required for applying the fiber Bragg grating sensor to the precipitation meter to prevent malfunctions caused by external environmental conditions such as moisture or lightning, and increase the reliability on the precipitation measured by the precipitation meter.

(Patent Document <NUM>) Korean Registered Patent No. <CIT>).

Other examples of precipitation meters can be found in <CIT>, <CIT> and <CIT>.

In order to solve the problems as mentioned above, the present invention provides a precipitation measuring apparatus using a fiber Bragg grating sensor in which a seesaw type bucket detects the number of rotations by using the fiber Bragg grating sensor so as to accurately measure precipitation, as described in claim <NUM>.

The present invention further provides a precipitation measuring apparatus using a fiber Bragg grating sensor to prevent malfunctions caused by external environmental conditions such as moisture or lightning, and provide precise measured values.

The present invention still further provides a precipitation measuring apparatus using a fiber Bragg grating sensor to measure both rainfall and snowfall.

In order to achieve the above-mentioned objects, the precipitation measuring apparatus using a fiber Bragg grating sensor according to the present invention includes: a base horizontally installed at a position for measuring precipitation; a cylindrical cover fixedly installed on the base; a bucket for collecting a predetermined amount of water introduced into the cover to discharge the collected water; and a detecting unit for detecting the number of times of discharging the water from the bucket by using the fiber Bragg grating sensor.

As described above, according to the precipitation measuring apparatus using the fiber Bragg grating sensor of the present invention, the change in the load applied onto the water collecting tank at a predetermined amount of water discharged from the bucket can be detected using the fiber Bragg grating sensor, and the amount of precipitation can be precisely measured using the number of changes in the wavelength of the light outputted from the fiber Bragg grating sensor.

Thus, according to the present invention, the fiber Bragg grating sensor is used, so that malfunctions caused by external environmental conditions such as moisture or lightning can be prevented, and the reliability on the precipitation measured by the precipitation meter can be increased.

In addition, according to the present invention, the detecting unit and the water collecting tank may be separately installed at different positions, and the detecting unit and the water collecting tank may be connected to each other by using the connection module, so that the optical fiber can be prevented from being cut or damaged due to the flux of the water collecting tank during movement.

In addition according to the present invention, the heating module may be applied to the precipitation measuring apparatus to heat and melt snow, snow pellets, hail, frost, and the like, and supply the water heated and melted to the water collecting tank, so that the amount of snowfall can be measured.

In addition, according to the present invention, the water is discharged to the ground through the discharge port and the discharge hose provided in the water collecting tank to control the speed of the water discharged from the water collecting tank, so that a measurement-available time for detecting the change in the load of the water collected in the water collecting tank can extend.

Thus, according to the present invention, measurement errors, which occur when the measurement-available time is shortened due to intensive rainfall within a short period of time, can be prevented, and the economic feasibility of the precipitation meter can be improved.

Hereinafter, a precipitation measuring apparatus using a fiber Bragg grating sensor according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

The present embodiment will be described based on the configuration of the tipping bucket type precipitation measuring apparatus cited in Patent Document <NUM>.

It will be apparent that the present invention is not limited thereto, and various modifications may be available so as to repeatedly discharge a predetermined amount of precipitation.

<FIG> is a perspective view showing a precipitation measuring apparatus using a fiber Bragg grating sensor according to a preferred embodiment of the present invention. <FIG> is a schematic diagram showing the configuration inside the precipitation measuring apparatus shown in <FIG>. <FIG> is an enlarged view of the detecting unit shown in <FIG>.

The terms indicating directions such as "left ", "right", "front", "rear", "upper" and "lower" are defined to indicate directions on the basis of a status shown in drawings, respectively.

As shown in <FIG> and <FIG>, a precipitation measuring apparatus <NUM> using a fiber Bragg grating sensor according to a preferred embodiment of the present invention includes: a base <NUM> horizontally installed at a position for measuring precipitation; a cylindrical cover <NUM> fixedly installed on the base <NUM>; a bucket <NUM> for collecting a predetermined amount of water introduced into the cover <NUM> and discharging the collected water; and a detecting unit <NUM> for detecting the number of times of discharging the water from the bucket <NUM> by using the fiber Bragg grating sensor <NUM>.

The cover <NUM> may be formed with a water inlet <NUM> at an upper end thereof through which rainwater flows, in which the cover may be provided therein with a filtering net <NUM> and a water intake tank <NUM> for collecting rainwater introduced through the water inlet <NUM> to have a substantially funnel shape.

A water collecting cup <NUM> that collects water discharged through the water intake tank <NUM> and discharges the collected water stably downward may be installed in an upper bracket <NUM> under the water intake tank <NUM>, and a bucket <NUM> that seesaws left and right according to the amount of rainwater dropped may be connected and installed to a lower bracket <NUM> under the water collecting cup <NUM>.

Left and right water collecting units <NUM> and <NUM> each filled with a predetermined amount of water may be provided at both sides of the bucket <NUM>.

In general, the precipitation meter includes <NUM> type and <NUM> according to a unit amount of rainwater to be measured.

In regard to the <NUM> type, the amount of precipitation when rainwater accumulates at a height of <NUM> on an area of <NUM> square meter (m2) is called '<NUM>', and the weight of rainwater at this time is about <NUM>.

The present embodiment will be described based on the <NUM> type.

A pair of drain pipes <NUM> for receiving the water contained in the bucket <NUM> while the water is discharged by the seesaw operation may be provided on the base <NUM> at lower ends of both sides of the bucket <NUM>, respectively.

The precipitation meter according to the related art is install with drain cylinders (not shown), instead of the drain pipes <NUM>, on both lower sides of the bucket <NUM> to guide the water discharged from the bucket <NUM> so as to be received and drained to the ground.

On the contrary, in the embodiment, the pair of drain pipes <NUM> may extend toward a lower part of the base <NUM>, and a lower end of each of the drain pipe <NUM> may be disposed above a water collecting tank <NUM>.

The water collecting tank <NUM> is fixed at a position spaced apart from the base <NUM> by a predetermined interval downward by an optical fiber <NUM> provided in the detecting unit <NUM>.

A slit <NUM> for discharging the water, which is discharged through the drain pipes <NUM> and collected in the water collecting tank <NUM>, to the outside may be formed at one side of the water collecting tank <NUM>.

Accordingly, the detecting unit <NUM> may include the optical fiber <NUM> installed between a lower surface of the base <NUM> and the water collecting tank <NUM>; and a fiber Bragg grating sensor <NUM> installed on the optical fiber <NUM> to detect the number of discharged times of water by the seesaw operation of the bucket <NUM>.

As shown in <FIG>, both ends of the optical fiber <NUM> may be fixed to a fixing block <NUM> installed to the lower part of the base <NUM>, and a middle portion of the optical fiber <NUM> may be installed along an outer surface of a fixing member <NUM> installed in the water collecting tank <NUM>.

The fixing member <NUM> may be formed in a substantially cylindrical shape, and may be installed on a shaft installed in the horizontal direction to an installation bracket <NUM> installed inside the water collecting tank <NUM>.

Accordingly, one end of the optical fiber <NUM> may be fixed to one surface of the fixing block <NUM> and mounted along the outer surface of the fixing member <NUM>, and then the other end of the optical fiber may be fixed to the other surface of the fixing block.

Light may be incident to one end of the optical fiber <NUM> from a measuring apparatus (not shown), and the other end of the optical fiber <NUM> may output light having a wavelength changed according to a load applied to the water collecting tank <NUM> as the incident light passes through the fiber Bragg grating sensor <NUM>.

Hereinafter, the one end of the optical fiber <NUM> to which the light is incident is referred to as an 'input end', and the other end of the optical fiber <NUM> through which the light is outputted is referred to as an 'output end'.

The measuring terminal may simultaneously monitor a plurality of precipitation measuring apparatuses <NUM>.

To this end, the optical fiber <NUM> may be continuously installed in the precipitation measuring apparatuses <NUM>.

In other words, the output end of the optical fiber <NUM> may be connected to an input end of the next precipitation measuring apparatus <NUM>, and an output end of the optical fiber <NUM> installed in the precipitation measuring apparatus <NUM> provided at the final stage may be connected to the measuring apparatus again.

The fiber Bragg grating sensor <NUM> provided in each precipitation measuring apparatus <NUM> may output light having a different wavelength band according to the change in the load of the water collecting tank <NUM>.

Accordingly, the measuring terminal can measure the amount of precipitation at different locations by simultaneously monitoring the consecutively connected precipitation measuring apparatuses <NUM> in real time using one optical fiber <NUM>.

Meanwhile, <FIG> shows that both ends of the optical fiber <NUM> are connected to the fixing block <NUM> while the middle portion is wound around the fixing member <NUM> in order to maintain an equilibrium state of the water collecting tank <NUM>, however, the present invention is not necessarily limited thereto.

In other words, the present invention may be modified such that the one end of the optical fiber <NUM> may be fixed to the fixing block <NUM>, and the other end of the optical fiber <NUM> may be fixed to the water collecting tank <NUM>, the fixing member <NUM>, or the installation bracket <NUM> to fix the water collecting tank <NUM> by using a single strand of optical fiber <NUM>.

Thus, according to the present invention, the change in the load applied onto the water collecting tank at a predetermined amount of water discharged by the seesaw operation of the bucket may be detected using the fiber Bragg grating sensor, and the amount of precipitation may be precisely measured using the number of changes in the wavelength of the light outputted from the fiber Bragg grating sensor.

Next, the coupling relationship and operation method of the precipitation measuring apparatus using the fiber Bragg grating sensor according to the exemplary embodiment of the present invention will be described in detail with reference to <FIG> and <FIG>.

<FIG> is a view showing an operation state of the precipitation measuring apparatus using the fiber Bragg grating sensor according to a preferred embodiment of the present invention. <FIG> is a graph showing the wavelength of light outputted from the fiber Bragg grating sensor shown in <FIG>.

<FIG> shows a state in which the bucket <NUM> rotates right downward to discharge a predetermined amount of water filled in the right water collecting unit <NUM>.

First, the operator installs the upper bracket <NUM> on the upper part of the base <NUM>, and installs the water collecting cup <NUM> on the upper bracket <NUM>.

In addition, the operator installs the bucket <NUM> on the lower bracket <NUM> such that the bucket <NUM> can be seesawed in the left and right directions.

Left and right water collecting units <NUM> and <NUM> are provided at both sides of the bucket <NUM>, and each of the water collecting units <NUM> and <NUM> rotates left or right downwards when a predetermined amount of water is filled.

For example, as shown in <FIG>, when a predetermined amount of water is collected in the right water collecting unit <NUM>, the bucket <NUM> rotates right downward to discharge the collected water. Then, the left water collecting unit <NUM> arranged upward collects water discharged from the water collecting cup <NUM>.

To this end, the operator installs a pair of drain pipes <NUM> on both sides of the base <NUM>, and connects a lower end of each drain pipe <NUM> to the water collecting tank <NUM>.

The water collecting tank <NUM> is fixedly installed under the base <NUM> by using the optical fiber <NUM> provided in the detecting unit <NUM>.

The operator arranges the middle portion of the optical fiber <NUM> along the outer surface of the fixing member <NUM> provided in the water collecting tank <NUM>, and then fixes the both ends of the optical fiber <NUM> to the fixing block <NUM> installed on the lower surface of the base <NUM>.

When the assembly of the precipitation measuring apparatus <NUM> is completed through the above process, the bucket <NUM> discharges the water filled by the seesaw operation when the predetermined amount of water is filled in the left or right water collecting unit <NUM> and <NUM> provided on the both sides.

The water discharged from the bucket <NUM> is filled in the water collecting tank <NUM> through the drain pipes <NUM>.

Accordingly, the fiber Bragg grating sensor <NUM> outputs light having a wavelength changed according to the load acting on the water collecting tank <NUM>, and the measuring terminal precisely measures the amount of precipitation by using the number of changes in the wavelength of the light received through the optical fiber <NUM>.

As shown in <FIG>, the measuring terminal counts one time when a wavelength value of the light outputted from the fiber Bragg grating sensor <NUM> exceeds a predetermined reference value so as to measure the amount of precipitation by using the total number of counted time.

According to the present invention, through the processes described above, the change in the load applied onto the water collecting tank at a predetermined amount of water discharged by the seesaw operation of the bucket may be detected using the fiber Bragg grating sensor, and the amount of precipitation may be precisely measured using the number of changes in the wavelength of the light outputted from the fiber Bragg grating sensor.

Meanwhile, in the precipitation measuring apparatus <NUM> according to the above embodiment, the water collecting tank <NUM> is installed under the base <NUM> by using the optical fiber <NUM>.

Accordingly, when a flux of the water collecting tank <NUM> occurs in the process of installing the precipitation measuring apparatus <NUM> first or moving the precipitation measuring apparatus <NUM> to move the installed position, there is a risk that the optical fiber <NUM> connecting the water collecting tank <NUM> to the base <NUM> may be broken or damaged.

In order to solve the problems mentioned as above, the present invention may be modified such that the water collecting tank <NUM> and the sensing unit <NUM> are separately installed and the load applied onto the water collecting tank is transferred to the detecting unit <NUM> by using a separate connection module.

For example, <FIG> is a partially enlarged view of the precipitation measuring apparatus using the fiber Bragg grating sensor according to another embodiment of the present invention.

As shown in <FIG>, according to the precipitation measuring apparatus <NUM> using a fiber Bragg grating sensor according to another embodiment of the present invention, the water collecting tank <NUM> and the sensing unit <NUM> are installed separately from each other at different positions and connected to each other by the connection module <NUM>.

The connection module <NUM> may include a support bar <NUM> installed in the vertical direction on one side of the base <NUM>, and a connection bar <NUM> axially coupled to a lower end of the support bar <NUM> so as to be rotatable in a vertical direction around a rotation shaft. The connection bar <NUM> may have an inner end bent downward with a section having an approximately reversed and inverted 'L' shape.

The water collecting tank <NUM> may be installed at a position spaced apart from the lower end of the connection bar <NUM> by a predetermined interval, and the detecting unit <NUM> may be installed at an outer end of the connection bar <NUM>.

In other words, the one end of the optical fiber <NUM>, that is, the upper end when view in <FIG> may be fixed to the outer end of the connection bar <NUM>, and the lower end of the optical fiber <NUM> may be fixed to an installation block <NUM> fixed to the ground or the cover <NUM>.

Accordingly, the fiber Bragg grating sensor <NUM> installed on the optical fiber <NUM> may receive the change in the load applied onto the water collecting tank <NUM> through the connection bar <NUM> and output light having a wavelength changed according to the change in the load.

Thus, according to the present invention, the detecting unit and the water collecting tank may be separately install at different positions, and the load change may be detected by the rotational operation of the connection bar according to the change in the load applied onto the water collecting tank, so as to output the light having the changed wavelength.

Thus, according to the present invention, the optical fiber can be prevented from being cut or damaged due to the flux of the water collecting tank while the precipitation measuring apparatus moves.

The present invention may be modified to further include a stopper (not shown) for restricting the rotational operation of the connection bar <NUM> or fixing the water collecting tank <NUM> to prevent the flux of the water collecting tank <NUM>.

The stopper may protrude from the lower surface of the base <NUM> to fix the connection bar <NUM>, or may be provided between the water collecting tank <NUM> and the base <NUM> or between the water collecting tank <NUM> and the cover <NUM>.

<FIG> is a partially enlarged view of the precipitation measuring apparatus using the fiber Bragg grating sensor according to still another embodiment of the present invention. <FIG> is a graph showing the wavelength of light outputted from the fiber Bragg grating sensor shown in <FIG>.

As shown in <FIG>, in the precipitation measuring apparatus <NUM> using the fiber Bragg grating sensor according to still another embodiment of the present invention, at least discharge port, instead of forming the slit <NUM> on the side of the water collecting tank <NUM>, may be formed on the lower surface of the water collecting tank <NUM>, and a discharge hose <NUM> may be connected to the discharge port.

Accordingly, the water collected in the water collecting tank <NUM> is discharged to the ground through the discharge port and the discharge hose <NUM>.

In an initial phase when the water discharged from the water collecting tank <NUM> is discharged after the water is collected in the water collecting tank <NUM>, the water has only potential energy, thereby being discharge at a relatively slow speed.

Whereas, when the discharged water reaches the ground through the discharge hose <NUM>, the discharge speed gradually increases as the potential energy is converted into kinetic energy. Accordingly, as suction force for sucking the water collected in the water collecting tank <NUM> toward the discharge hose <NUM> is generated due to viscosity of the water, the speed of the water discharged from the water collecting tank <NUM> gradually increases.

Thus, in the present embodiment, the initial discharge speed of the water collected in the water collecting tank may decrease, and the discharge speed of the water may gradually increase as time passes.

Accordingly, as shown in <FIG>, the light outputted from the fiber Bragg grating sensor <NUM> maintains a wavelength value higher than the reference value when the water is initially discharged, and the wavelength value decreases rapidly as the initially discharged water reaches the ground and the discharge speed increases.

In other words, compared to the wavelength value of the light shown in <FIG>, it can be seen that the wavelength value of the light shown in <FIG> is maintained over the reference value for a longer time.

Thus, according to the present invention, the water is discharged to the ground through the discharge port and the discharge hose provided in the water collecting tank to control the speed of the water discharged from the water collecting tank, so that a measurement-available time for detecting the change in the load of the water collected in the water collecting tank may extend.

Meanwhile, as mentioned above, the precipitation measuring apparatus <NUM> measures rainfall and snowfall.

To this end, according to the present invention, a heating module such as a heating coil may be applied to the cover, filtering net, water intake tank, or water collecting cup to heat and melt snow, snow pellets, hail, frost, and the like, and supply the water heated and melted to the water collecting tank so as to measure the amount of snowfall.

In other words, the present invention may be modified such that a precipitation measuring apparatus for measuring the amount of rainfall is installed separately from a precipitation measuring apparatus applied with the heating module to measure snowfall, or a single precipitation measuring apparatus applied with the heating module may be used so as to measure both rainfall and snowfall.

To this end, the precipitation measuring apparatus applied with the heating module may be configured to be connected to the measuring terminal to communicate with each other, and drive the heating module according to the control signal of the measuring terminal, thereby heating snow and the like. In addition, the heating module may be supplied with power through a power supply unit of the measuring terminal, or supplied with power from a power generation module such as a photovoltaic module installed together with the precipitation measuring apparatus.

Claim 1:
A precipitation measuring apparatus (<NUM>) using a fiber Bragg grating sensor (<NUM>), the precipitation measuring apparatus (<NUM>) comprising:
a base (<NUM>) horizontally installed at a position for measuring precipitation;
a cylindrical cover (<NUM>) fixedly installed on the base (<NUM>);
a bucket (<NUM>) for collecting a predetermined amount of water introduced into the cover (<NUM>) to discharge the collected water; and
a detecting unit (<NUM>) for detecting a number of times of discharging the water from the bucket (<NUM>) by using the fiber Bragg grating sensor (<NUM>),
characterized in that the base (<NUM>) is provided at a lower portion thereof with a water collecting tank (<NUM>) for collecting the water discharged from the bucket (<NUM>), wherein
the detecting unit (<NUM>) includes
an optical fiber (<NUM>) installed between the base and the water collecting tank, and
a fiber Bragg grating sensor (<NUM>) installed on the optical fiber (<NUM>) to detect a number of discharging times of a predetermined amount of water from the bucket (<NUM>) to the water collecting tank (<NUM>), in which the fiber Bragg grating sensor (<NUM>) outputs light having a wavelength changed according to a load applied onto the water collecting tank (<NUM>) .