KR20130027818A - Apparatus for providing sensor information using optical communication - Google Patents

Abstract

PURPOSE: An optical communication method sensor information collecting device is provided to transmit information by generating the driving power of a sensor through an optical line. CONSTITUTION: A terminal module(130) includes a sensor unit(139) and a terminal control unit(137). The terminal control unit generates driving power by converting light transmitted through an optical transmission unit into electrical energy. The terminal control unit transmits information sensed by the sensor unit through the optical transmission unit. A collecting module(150) transmits light for generating power to the terminal module through the optical transmission unit. The collecting module receives the measurement information of the sensor unit from the optical signal received from the terminal module through the optical transmission unit. [Reference numerals] (131) Solar cell; (133) Charging unit; (137) Terminal control unit; (139a) First sensor; (139n) n-th sensor; (155) Main control unit; (157) Manipulating unit; (159) Display unit

Description

Apparatus for providing sensor information using optical communication

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical communication type sensor information collecting device, and more particularly, to an optical communication type sensor information collecting device which is driven by using driving power generated from transmitted light to transmit sensed information.

Sensors have been developed in various ways according to the physical quantities to be measured. These sensors are also used in various types, such as temperature sensor, humidity sensor, pressure sensor, infrared sensor, acceleration sensor, ultrasonic sensor, and are appropriately selected according to the information and installation environment to be obtained.

Such a sensor module requires a power supply to operate by itself. In the case of a method of supplying power using a power line, as the distance between the power supply and the sensor module increases, power loss due to voltage drop occurs.

Unlike this, there is a method of supplying the power of a sensor module installed at a long distance by using a built-in battery, but in this case, there is a disadvantage in that the usable period is limited according to the capacity of the battery. In a non-available environment, it is not possible to add a separate charging function, thereby increasing the service life of the battery.

In order to transmit the information measured by the sensor module of the power driving method there is a disadvantage that a separate communication line is also required.

On the other hand, various optical sensors for sensing using light have been developed. However, the applicable sensing parameters are also limited, and the components are still expensive and the economy is inferior.

The present invention has been made to solve the above problems, and an object thereof is to provide an optical communication type sensor information collecting device capable of generating driving power and transmitting information of a sensor through an optical path.

In order to achieve the above object, the optical communication sensor information collecting device according to the present invention comprises: an optical transmission unit capable of transmitting light; A sensor unit for measuring a measurement target parameter, and converts light transmitted through the light transmission unit into electrical energy to generate driving power, and converts information measured from the sensor unit by the generated driving power into an optical signal through the light transmission unit; A terminal module for transmitting; And a collection module for transmitting power generation light to the terminal module through the optical transmitter and receiving and processing measurement information of the sensor unit from the optical signal received from the terminal module through the optical transmitter.

According to an aspect of the invention, the optical transmission unit is installed between the terminal module and the collection module and the first optical fiber for transmitting power generation light; And a second optical fiber installed between the terminal module and the collection module to transmit the optical signal, wherein the terminal module comprises: a first light source for transmitting the optical signal through the second optical fiber; A terminal control unit controlling the first light source to generate an optical signal corresponding to the measurement information received by the sensor unit; A solar cell which receives light transmitted through the first optical fiber and converts the light into electrical energy; A charging unit configured to charge the power generated from the solar cell and provide the charged power to the first light source, the terminal control unit, and the sensor unit, wherein the collection module is configured to generate power through the first optical fiber. A second light source for transmitting the light; A photodetector for receiving the light transmitted through the second optical fiber and converting the light into an electrical signal; And a main control unit controlling the driving of the second light source and collecting and processing measurement information of the sensor unit from the signal received by the photodetector.

According to another aspect of the present invention, the optical transmission unit includes a common optical fiber installed between the terminal module and the collection module, the terminal module and the first beam splitter installed to face the end of the common optical fiber; ; A first light source for transmitting an optical signal to the collection module through the first beam splitter; A terminal control unit controlling the first light source to generate an optical signal corresponding to the measurement information received by the sensor unit; A solar cell that receives light transmitted from the terminal module through the first beam splitter and converts the light into electrical energy; A charging unit configured to charge power generated from the solar cell and provide the charged power to the first light source, the terminal control unit, and the sensor unit; A two beam splitter; A second light source arranged to transmit power generation light to the common optical fiber through the second beam splitter; A photodetector for receiving the light transmitted from the terminal module through the common optical fiber and the second beam splitter and converting the light into an electrical signal; And a main control unit controlling the driving of the second light source and collecting and processing measurement information of the sensor unit from the signal received by the photodetector.

The sensor unit preferably includes at least one of a temperature sensor for measuring a temperature, a pressure sensor for measuring pressure, and a humidity sensor for measuring humidity.

According to the optical communication method sensor information collection device according to the present invention, the optical signal corresponding to the power generation light and the sensing information of the sensor through the optical fiber can be transmitted to reduce the constraints on the installation environment of the sensor, which is driven by power It provides the advantage that various sensors can be applied without limitation.

1 is a view showing an optical communication sensor information collecting device according to an embodiment of the present invention,
2 is a view showing an optical communication type sensor information collecting device according to another embodiment of the present invention.

Hereinafter, an optical communication type sensor information collecting device according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing an optical communication type sensor information collecting device according to an embodiment of the present invention.

Referring to FIG. 1, the optical communication method sensor information collecting device 100 according to the present invention includes an optical transmitting unit 110, a terminal module 130, and a collecting module 150.

The optical transmitter 110 is installed to extend between the terminal module 130 and the collection module 150 to transmit light, and includes two first and second optical fibers 111 and 113.

The first optical fiber 111 is installed between the solar cell 131 of the terminal module 130 and the second light source 151 of the collection module 150 to emit light for power generation emitted from the second light source 151. Transfer to the battery 131.

The second optical fiber 113 is installed between the first light source 135 of the terminal module 130 and the photodetector 153 of the collection module 150 to receive an optical signal emitted from the first light source 135. 153).

Preferably, the first optical fiber 111 and the second optical fiber 113 are accommodated together in one coated cable (not shown), and the coated cable is removed only at both ends thereof.

The terminal module 130 generates driving power by converting light transmitted through the optical transmitter 110 into electrical energy, and outputs information measured from the sensor unit 139 measuring a measurement target parameter by the generated driving power. The optical transmitter 110 is configured to transmit an optical signal.

The terminal module 130 includes a solar cell 131, a charging unit 133, a first light source 135, a terminal control unit 137, and a sensor unit 139.

The solar cell 131 receives light transmitted through the first optical fiber 111 and converts the light into electrical energy to charge the charging unit 133.

The charging unit 133 charges the power generated from the solar cell 131, and supplies the charged power to the driving power of the first light source 135, the terminal control unit 137, and the sensor unit 139.

The first light source 135 is controlled by the terminal controller 137 to generate an optical signal, and transmits the generated optical signal to the collection module 150 through the second optical fiber 113.

The terminal controller 137 controls the first light source 135 to generate an optical signal corresponding to the measurement information received from the sensor 137.

The sensor unit 139 provides the measured sensing information to the terminal controller 137.

The first sensor 139a to the n th sensor 139n are applied to the sensor unit 139.

Here, the number and types of applications of the first to nth sensors 139n may be applied according to the installation environment. For example, a temperature sensor for measuring temperature, a pressure sensor for measuring pressure, and a humidity sensor for measuring humidity may be used. At least one may be applied.

On the other hand, the collection module 150 transmits the power generation light to the terminal module 130 through the optical transmission unit 110, and the sensor unit from the optical signal received from the terminal module 130 through the optical transmission unit 110 Receive processing of the measurement information of 139).

The collection module 150 includes a second light source 151, a photo detector 153, a main controller 155, an operation unit 157, and a display unit 159.

The second light source 151 is controlled by the main controller 155 to transmit power generation light through the first optical fiber 111.

The second light source 151 is preferably a high power laser diode is applied.

The photodetector 153 receives light transmitted through the second optical fiber 113, converts the light into an electrical signal, and outputs the electrical signal to the main controller 155.

The main controller 155 controls the driving of the second light source 1551, collects and processes measurement information of the sensor unit 139 from the signal received from the photodetector 153, and collects the collected information through the display unit 159. Process it to be displayed.

Although not shown, the main controller 155 may be constructed to transmit the measurement information of the resin bondin sensor unit 139 to an external device through an interface or a wireless transmitter.

The operation unit 157 is configured to set supported functions such as a sensing information collection cycle.

On the other hand, unlike the illustrated example, the optical transmission unit may be constructed to apply one optical fiber, and an example thereof is illustrated in FIG. 2. The same reference numerals denote the same elements as those in the drawings.

Referring to FIG. 2, one common optical fiber 211 is installed between the terminal module 230 and the collection module 250 as an optical transmitter.

In addition, the terminal module 230 is installed to face the end of the common optical fiber 211, the light transmitted from the collection module 250 is transmitted to the solar cell 131 as it is, and orthogonal to the solar cell 131 A first beam splitter 233 is provided to branch the optical signal incident from the first light source 135 installed in the direction to be directed to the terminal module 230.

The terminal module 230 transmits the optical signal generated by the driving of the first light source 135 to the collection module 250 through the first beam splitter 233 and the common optical fiber 211, and collects the collection module ( The light transmitted from 250 is incident to the solar cell 131 through the first beam splitter 233 to generate driving power.

In addition, the collection module 250 is installed to face the front end of the common optical fiber 211, the light transmitted from the second light source 151 of the terminal module 230 is the common optical fiber 211 and the first beam splitter 233 The light signal incident through the first beam splitter 233 to the first light source 135 installed in the direction perpendicular to the solar cell 131 through the first beam splitter 233 is transmitted through the photodetector 153. A second beam splitter 253 is branched so as to branch toward ().

Here, the second light source 151 is installed to transmit power generation light to the common optical fiber 211 through the second beam splitter 253, and the photodetector 153 is a common optical fiber from the terminal module 230. 211 and the second beam splitter 253 are installed in a direction orthogonal to the second light source 151 to receive light.

The main controller 155 controls the driving of the second light source 151 to generate power for driving the terminal module 230 and from the signal received through the photodetector 153 from the terminal module 230. The measurement information of the sensor unit 139 is collected and processed.

The main controller 155 drives the second light source 151 during the driving time of the second light source 151 set to correspond to the power generation time required for driving the terminal module 230, and after the driving time, the second light source ( 151 may be turned off and configured to process a signal received through the photodetector 153 from the terminal module 230.

In this case, when the terminal control unit 137 of the terminal module 230 starts power supply through the charging unit 133 by driving the second light source 151 and wakes up, the common optical fiber 211 is set after the set waiting time. The measurement information of the sensor unit 139 may be configured to be transmitted by the driving of the first light source 135, and the waiting time may be the driving time of the main controller 155 and the power supply timing of the charging unit 133. In consideration of this, the second light source 151 may be set after the off point.

Meanwhile, the charging unit 133 provides the charging state information to the terminal control unit 137, and the terminal control unit 137 is in a state in which the current charging state is difficult to continue the subsequent driving of the terminal modules 130 and 230. Previously, the information corresponding to the charging request through the second light source 135 is preferably configured to transmit through the collection module 150 and 250.

110: optical transmission unit 130, 230: terminal module
150, 250: collection module

Claims (4)

An optical transmission unit configured to transmit light;
A sensor unit for measuring a measurement target parameter, and converts light transmitted through the light transmission unit into electrical energy to generate driving power, and converts information measured from the sensor unit by the generated driving power into an optical signal through the light transmission unit; A terminal module for transmitting;
And a collection module for transmitting power generation light to the terminal module through the optical transmitter and receiving and processing measurement information of the sensor unit from the optical signal received from the terminal module through the optical transmitter. Sensor information collection device. The method of claim 1, wherein the optical transmission unit
A first optical fiber installed between the terminal module and the collection module to transmit light for power generation;
And a second optical fiber installed between the terminal module and the collection module to transmit the optical signal.
The terminal module
A first light source for transmitting an optical signal through the second optical fiber;
A terminal control unit controlling the first light source to generate an optical signal corresponding to the measurement information received by the sensor unit;
A solar cell which receives light transmitted through the first optical fiber and converts the light into electrical energy;
And a charging unit for charging the power generated from the solar cell and providing the charged power to the first light source, the terminal control unit, and the sensor unit.
The collection module
A second light source for transmitting power generation light through the first optical fiber;
A photodetector for receiving the light transmitted through the second optical fiber and converting the light into an electrical signal;
And a main control unit controlling the driving of the second light source and collecting and processing measurement information of the sensor unit from the signal received from the photodetector. The method of claim 1,
The optical transmission unit
And one common optical fiber installed between the terminal module and the collection module.
The terminal module
A first beam splitter installed opposite the end of the common optical fiber;
A first light source for transmitting an optical signal to the collection module through the first beam splitter;
A terminal control unit controlling the first light source to generate an optical signal corresponding to the measurement information received by the sensor unit;
A solar cell that receives light transmitted from the terminal module through the first beam splitter and converts the light into electrical energy;
And a charging unit for charging the power generated from the solar cell and providing the charged power to the first light source, the terminal control unit, and the sensor unit.
The collection module
A second beam splitter installed to face the front end of the common optical fiber;
A second light source arranged to transmit power generation light to the common optical fiber through the second beam splitter;
A photodetector for receiving the light transmitted from the terminal module through the common optical fiber and the second beam splitter and converting the light into an electrical signal;
And a main control unit controlling the driving of the second light source and collecting and processing measurement information of the sensor unit from the signal received from the photodetector. The apparatus of claim 2, wherein the sensor unit comprises at least one of a temperature sensor measuring temperature, a pressure sensor measuring pressure, and a humidity sensor measuring humidity.

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