KR20130049615A - Temperature-compensated flow rate measuring apparatus based on fiber bragg grating sensors - Google Patents

Abstract

PURPOSE: A temperature compensated flow rate change measuring device based on an optical fiber lattice sensor is provided to damp a flow rate change value caused by temperature by measuring the inner temperature, thereby removing errors caused by the temperature. CONSTITUTION: A temperature compensated flow rate change measuring device based on an optical fiber lattice sensor comprises a body(410), a level measuring unit(120), an optical fiber cable(320), a light source, and a sensor unit. The body stores fluid. The level measuring unit measures a change in the level of the fluid. The optical fiber cable includes an optical fiber lattice(310). The light source irradiates lights to the optical fiber cable. The sensor unit detects the changed amount of the wavelengths passing through the optical fiber cable. The optical fiber cable is connected to the level measuring unit so that a cycle of the optical fiber lattice is changed according to a change of the level.

Description

Temperature-compensated Flow Rate Measuring Apparatus Based On Fiber Bragg Grating Sensors

The present invention is installed in a place where a lot of electromagnetic waves or a lot of errors of the electrical sensor is generated by a flow rate measuring device based on a fiber Bragg Grating (FBG) sensor for precisely measuring the change in flow rate (or quantity) and It relates to a measuring method using the same. More specifically, the fiber optic lattice holder is provided with a float that moves according to the change of the water level or the flow rate, and when the water level change occurs, the float moves as much as the water level change. The present invention relates to a flow rate measuring device and a measuring method using the same, which detect a level or flow rate applied by using a change in wavelength by changing a period to change a specific wavelength of an optical fiber grating.

Conventionally, as a method of measuring the flow rate, the flow rate or the water level change is measured by using a flow gauge or an electric sensor, but there is a disadvantage in that measurement accuracy is poor. In particular, in the region where electromagnetic waves are formed a lot, the error of the electric sensor occurs and the reliability of the measured value is not only lowered, but it is difficult to obtain the accumulated data value of the measurement unit due to the difficulty of real-time measurement.

In case of using the conventional system, there are inconveniences in operating the system. In order to measure the amount of change occurring in a place where a large amount of measurement is required by using an electrical sensor, each sensor must be operated independently. In this case, a mechanism for compensating for the flow rate error that occurs during flow measurement is needed as the storage body (body) expands and contracts according to the change of the internal temperature.

The optical fiber grating is called FBG (Fiber Bragg Grating), and the optical fiber core part is changed into a lattice shape having a constant period of refraction, and has a characteristic of selectively reflecting light of a specific wavelength in the formed grating. When manufacturing a flow rate measuring sensor using the optical fiber grating, it is possible to know the change of the applied physical quantity by measuring the change of the unique wavelength value, and to provide a flow measuring sensor with excellent physical properties such as being hardly affected by electromagnetic waves. Can be.

The present invention for solving the above problems is installed in the optical fiber lattice fixing device moving the ball according to the change of the water level or flow rate, when the water level change occurs, the ball is moved by the change of the water level and the change The purpose of the present invention is to provide an optical fiber sensor based flow measurement device that detects the applied level or flow rate by changing the wavelength by changing the period of the optical fiber grating located in the fixed device. There is this. By applying a physical force to the optical fiber, a change occurs in a certain period of the grating formed in the optical fiber core portion, and the change in the grating period results in a change of a specific wavelength reflected from the grating, and the amount of change in the specific wavelength is detected. The physical quantity applied to the optical fiber can be detected.

Thermal expansion of the body of the flowmeter due to external temperature changes results in a change in the position of the optical fiber grating fixture fixed to the body.This changes the period of the optical fiber grating, thus changing the specific wavelength of the optical fiber grating without changing the water level or flow rate. This can cause errors to be imported. In order to minimize the error, the present invention provides a fiber-optic sensor-based flow layer device employing a temperature compensation package structure capable of minimizing the change by offsetting the change in physical quantity by the temperature change. There is this.

The technical objects to be achieved by the present invention are not limited to the above-mentioned technical problems, and other technical subjects which are not mentioned can be clearly understood by those skilled in the art from the description of the present invention .

The present invention for solving the above problems is a housing for storing a fluid, a water level measuring unit for measuring the level change of the fluid, an optical fiber cable including an optical fiber grid, a light source for irradiating light to the optical fiber cable and the optical fiber cable It includes a sensor unit for detecting the amount of change of the wavelength passing, wherein the optical fiber cable is connected to the water level measuring unit provides a flow rate measuring device, characterized in that the period of the optical fiber grid changes in accordance with the level change.

The present invention provides a flow measurement device, comprising a temperature sensor including an optical fiber grid, the sensor unit is characterized in that for correcting the water level change due to expansion or contraction of the enclosure according to the temperature measured by the temperature sensor Provides a flow measurement device to

The present invention provides the flow rate measuring apparatus, wherein the optical fiber cable includes two or more optical fiber gratings.

According to the present invention, it is possible to completely measure the water level or the flow rate change in the area where the flow measurement was impossible due to the influence of the electromagnetic wave.

According to the present invention, the precision of the optical fiber grating sensor can be improved due to its excellent physical properties, and up to 20 or more sensors can be connected in series with one strand of optical fiber, which requires much less space than the conventional electric system. Since the sensor itself has a unique wavelength value, there is an effect that can measure the cumulative deformation compared to the initial value of the object to be measured.

According to the present invention, a temperature compensation sensor is placed inside to compensate for an error in a measured value due to an internal or external temperature change. There is an effect that can eliminate the error caused by.

1 illustrates an optical fiber cable including an optical fiber grating;
2 is a block diagram of an optical fiber sensor based flow layer device according to an embodiment of the present invention;
3 is a block diagram of a flow layer device based on a temperature-compensated optical fiber sensor according to an embodiment of the present invention.
Figure 4 is a specific implementation of the optical fiber sensor based flow measurement device according to an embodiment of the present invention
5 to 6 is a view showing a state of measuring the fluid level of the optical fiber sensor based flow measurement device according to an embodiment of the present invention
Figure 7 is an illustration of the case of operating several optical fiber gratings for flow measurement in one optical fiber cable

An optical fiber sensor-based flow layer device according to an embodiment of the present invention is an optical fiber cable including a housing for storing a fluid 410, a water level measurement unit 120 for measuring a level change of the fluid, and an optical fiber grating 310. 320, a light source 510 for irradiating light to the optical fiber cable 320, and a sensor unit 520 for detecting a change amount of a wavelength passing through the optical fiber cable 320.

The housing 410 is a container for storing the fluid 420 such as water or oil, and the inlet 210 through which the fluid 420 enters the housing 410 and the drain 220 through which the fluid flows out. It may include. Enclosure 410 is not necessarily to be manufactured in the form of a container, it may be applied to a form such as a pipeline that can adjust the flow rate.

The water level measurement unit 120 includes a float 110 and a float-optical fiber connecting lever 120. The float 110 is always in contact with the surface of the water level, and the position of the float 110 changes according to the quantity (or flow rate). The change in the position of the float 110 is transmitted to the optical fiber cable 320 through the connection lever 120 connected to the float 110, the lever fixed shaft 140 to fix the lever to change the water level of the float 110 By converting the vertical motion to the horizontal motion, and connecting the end of the connection lever 120 with the optical fiber cable 320 may be to vary the magnitude of the force transmitted to the optical fiber cable 320 according to the water level.

The optical fiber grating 310 changes the optical fiber core part into a grating form having a predetermined period of refraction, and has a characteristic of selectively reflecting only light having a specific wavelength in the formed grating. When a force is applied to the optical fiber cable 320 including the optical fiber grid 310, the grid period of the optical fiber grid 310 is changed, and when the grid period is changed, the light irradiated from the light source 510 is applied to the optical fiber grid 310. The reflected wavelength changes. The sensor unit 520 may detect the change in the wavelength to measure the water level.

The optical fiber cable 320 may include one or more optical fiber grids 310. FIG. 7 shows an example of operation in the case of including n optical fiber gratings 310. The light irradiated from the light source is transmitted to the optical cable through the coupler, and each time the optical fiber grid meets the light of a certain wavelength is reflected, and the reflected light is passed back through the coupler to the receiver (sensor). The change in the lattice wavelength of light can be measured by comparing it with a reference light source.

Looking at the operation of the optical fiber sensor based flow layer device according to an embodiment of the present invention in detail.

In the case where the quantity of water is increased, when the quantity of water (flow rate) is introduced through the water inlet 210, the position of the buoy 110 in contact with the surface of the water level rises according to the change of the water surface. The connecting lever 120 between the accessory 110 and the optical fiber cable 320 having the optical fiber grid 310 exerts a force on the grating in the left direction (the direction in which the optical fiber cable extends), and the optical fiber grid in the optical fiber cable 320 ( It serves to increase the lattice period of 310 to change the lattice wavelength reflected by the optical fiber grid 310.

When the amount of water decreases When the amount of water (flow) flows out through the drain hole 220, the position of the float 110 in contact with the surface of the water level is lowered according to the change of the water surface. The connecting lever 120 between the accessory 110 and the optical fiber cable 310 having the optical fiber grid 310 exerts a force on the grid in the right direction (the direction in which the optical fiber cable is reduced), and the optical fiber grid in the optical fiber cable 320 ( It serves to reduce the lattice period of the 310 to change the lattice wavelength reflected through the optical fiber grid 310.

An optical fiber sensor-based flow layer device according to an embodiment of the present invention is an optical fiber cable including a housing for storing a fluid 410, a water level measurement unit 120 for measuring a level change of the fluid, and an optical fiber grating 310. 320, a light source 510 for irradiating light to the optical fiber cable 320, a sensor unit 520 for detecting an amount of change in wavelength passing through the optical fiber cable 320, and an optical fiber grid (not shown). And a temperature sensor 530. The sensor unit 520 provides a flow rate measuring device, characterized in that for correcting the change in the water level due to the expansion or contraction of the enclosure in accordance with the temperature measured by the temperature sensor 530.

The water level measurement unit 120, the optical fiber grid 310, the optical fiber cable 320, the housing 410, and the sensor unit 520 operate in the same manner as in the other embodiments described above.

If the internal temperature changes, the flow meter expands or contracts with heat according to the temperature change, and the lattice cycle of the optical fiber grating fixed for flow measurement changes due to this expansion or contraction, thereby causing an error in the flow measurement value. Will occur. The temperature sensor 530 has a built-in optical fiber grating sensor to measure the temperature and can cancel the error due to temperature by software offsetting the flow rate change value according to the temperature.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and should be construed in a sense and concept consistent with the technical idea of the present invention. It should be noted that the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention so that various equivalents And variations.

110: float
120: fiber-optic connection lever
130: optical fiber lever lever
140: lever fixed shaft
210: inlet
220: drain
310: optical fiber grating
320: fiber optic cable
410: enclosure for storing fluid
420: fluid (water / oil)
510: light source
520: sensor

Claims (3)

A housing for storing the fluid;
A water level measuring unit measuring a level change of the fluid;
An optical fiber cable including an optical fiber grid;
A light source for irradiating light onto the optical fiber cable; And
And a sensor unit detecting a change amount of a wavelength passing through the optical fiber cable.
The optical fiber cable is connected to the water level measuring unit flow rate measuring device, characterized in that the cycle of the optical fiber grid changes in accordance with the change in the water level.
The flow rate measuring apparatus of claim 1, further comprising a temperature sensor including an optical fiber grid, wherein the sensor unit corrects a level change due to expansion or contraction of the enclosure according to a temperature measured by the temperature sensor. .
The flow rate measuring apparatus according to claim 1 or 2, wherein the optical fiber cable includes two or more optical fiber gratings.

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