KR101246396B1 - Light collecting apparatus and light transmitting system having the same - Google Patents

Abstract

Disclosed are a solar light concentrating device and a light transmission system having the same, which are capable of increasing the light condensing efficiency while reducing the size by using the optical characteristics of the light reflected by the reflectors. The light collecting device includes a first reflecting mirror having a reflecting surface for reflecting and converging light, a second reflecting mirror reflecting light reflected by the first reflecting mirror, and converging light reflected by the first and second reflecting mirrors. And first optical means.

Description

Light collecting apparatus and light transmitting system having the same

The present invention relates to a light transmission system having a light concentrating device for condensing light such as sunlight, and more particularly, to double the light condensing efficiency while reducing the size by using optical characteristics of light reflected by reflectors. The present invention relates to an optical transmission system having a light collecting device.

Solar power is an endless power source that can be obtained from nature without the addition of additional energy sources from the outside, and it can be used for lighting or heating buildings, generating electricity, or growing various land and marine plants. It is utilized.

However, solar light requires a light collecting area of a predetermined area or more in order to obtain a light collecting amount of a scale that can be utilized for the above applications.

In order to solve this problem, a solar light concentrating device capable of concentrating solar light and supplying it to a light utilization means requiring solar light, for example, a heat collecting tube, a solar panel, a lighting device, and the like has been developed and used.

The solar light collecting device generally includes a parabolic cup reflector and a lens disposed at the center of the cup reflector to converge the light reflected from the cup reflector to light using means such as a heat collecting tube, a solar panel, and a lighting fixture. .

However, in such a conventional solar light collecting device, the light collecting efficiency depends on the curvature of the parabolic surface of the cup reflector. In other words, the greater the curvature of the parabolic surface, the closer the focus of reflection is to the vertex of the parabola (the center of the cup-shaped reflector), so that the amount of light that converges to the center of the cup-shaped reflector increases as the curvature of the parabolic surface increases. This means that the curvature of the parabolic surface must be increased by increasing the height of the cup reflector in order to obtain the maximum light collecting amount under the condition that the entrance size of the cup reflector into which sunlight is incident.

As a result, when the curvature of the parabolic surface is increased in order to obtain the maximum amount of light condensing, the size of the solar light concentrator increases, and when the curvature of the parabolic surface is reduced in order to reduce the size of the solar light concentrating device, that is, When the distance between the solar light collecting device and the light using means is far from each other due to the lack of intensity and brightness, there is a problem in that the collected solar light cannot be used for the purpose of use.

In addition, when the solar light is transmitted to and used inside the building, plant cultivation room, or a place that requires sunlight, such as fish, from a light collecting place where a solar light collecting device is installed, such as outside the building or at sea, the light is collected by the light collecting device. In addition to the original solar form, it may be necessary to convert the light into light having a necessary wavelength band, such as, for example, the ultraviolet light required for plant photosynthesis, and supply it to the required place.

However, conventionally, a technique for converting sunlight collected by a solar light collecting device into light having a required wavelength band and supplying it to a required place has not been disclosed.

Therefore, there is a demand for a light converging device capable of increasing the light condensing efficiency of sunlight while reducing its size, and a light transmission system capable of converting the condensed sun light into light having a required wavelength band and supplying it to a required place.

The present invention has been made to solve the above problems, one object of the present invention by using the optical properties of the light reflected by the reflectors to reduce the size of the light condensing device to double the light collection efficiency It is to provide an optical transmission system having a.

Another object of the present invention is to provide a light transmission system having a light collecting device capable of converting concentrated solar light into light having a required wavelength band and supplying it to a required place.

Another object of the present invention is to provide an optical transmission system having a light collecting device capable of freely communicating with the outside.

According to an aspect of the present invention for achieving the above object, the light collecting device, the first reflector having a reflecting surface for reflecting and converging light, the second reflector for reflecting light reflected by the first reflector again And first optical means for converging the light reflected by the first and second reflecting mirrors.

The first reflector may include a cup reflector.

The second reflecting mirror may include a reflecting mirror having a reflecting curved surface or a reflecting plane that faces the reflecting surface of the first reflecting mirror. In this case, the second reflector may be disposed at the center of the transparent dome covering the opening of the first reflector to which light is incident.

The first optical means may comprise at least one convex lens.

According to another aspect of the present invention, an optical transmission system includes a light concentrating device for condensing the light described above, an optical transmission line having one end connected to the light concentrating device, and a light transmission line disposed at the other end of the optical transmission line and diffusing the light transmitted through the optical transmission line. And second optical means.

The optical transmission line may comprise an optical fiber cable having at least one optical fiber cable shim.

The second optical means may comprise at least one concave lens.

In order to pass only light having a wavelength band requiring transmission, the optical transmission system of the present invention may further include a wavelength band adjusting unit disposed between the light collecting device and the optical transmission line. The wavelength band adjusting section includes a filter exchanger for selectively placing one of a plurality of filters passing light having different wavelength bands in accordance with a control signal from the outside between the condenser and the optical transmission line, and optical fiber grating according to a control signal from the outside. A grating strain type wavelength band converter which applies a voltage to a piezoelectric element connected to the strain to strain the period of the optical fiber grating according to the applied voltage to change the light passing through the optical fiber cable into light having a required wavelength band, Alternatively, a heat-changing wavelength that dissipates unnecessary specific wavelength band light passing through the optical fiber cable according to the applied temperature by applying heat to the optical fiber cable injecting liquid crystal into the cladding region according to a control signal from the outside. And a band converter. Optionally, the wavelength band adjusting unit may include a spacer that maintains the distance between the light concentrator and the light transmission line at a focal length of light having the required wavelength band.

In order to change the wavelength band of light incident on the optical transmission line or to inform the outside of the system itself by controlling the wavelength band adjusting unit according to a control signal from the outside, the optical transmission system of the present invention further includes a communication unit capable of communicating with the outside. It may include.

In an embodiment, the optical transmission system of the present invention may be an optical transmission buoy system having a floating body that keeps the light collecting device floating above the sea surface and supplies sunlight to a necessary place such as an artificial reef on the seabed.

As described above, the light collecting device and the light transmission system having the same according to the present invention have a first reflector for reflecting and converging light, and a reflecting surface or a reflecting plane to reflect back light reflected by the first reflector. A second reflecting mirror is provided. Therefore, the light collecting device and the light transmission system having the same of the present invention can converge sufficient light toward the first optical means through the second reflecting mirror even if the first reflecting mirror has little curvature or increases the vertical height. Therefore, the height of the first reflecting mirror can be formed lower than that of the conventional reflecting apparatus, so that the focusing apparatus and the light transmission system are reduced in size.

In addition, the optical transmission system having a light collecting device according to the present invention includes a wavelength band adjusting unit capable of passing only the light having the required wavelength band through the collected sunlight. Therefore, the light transmission system of the present invention can convert the concentrated solar light into light having a necessary wavelength band such as, for example, ultraviolet light required for plant photosynthesis, and supply it to a required place.

In addition, the optical transmission system having a light collecting device according to the present invention further includes a communication unit capable of communicating with the outside. Therefore, the optical transmission system of the present invention can freely communicate with the outside to control the wavelength band adjusting unit according to a control signal from the outside to change the wavelength band of the light or inform the outside of the system itself.

1 is a perspective view schematically illustrating a light transmission system having a light collecting device according to an embodiment of the present invention;
2 is a partial cross-sectional view of the optical transmission system shown in FIG.
3 is a partial cross-sectional view illustrating a modification of the first and second reflecting mirrors of the light collecting device of the optical transmission system shown in FIG. 1;
4A and 4B are a plan view and a side view illustrating a wavelength band adjusting unit of the optical transmission system shown in FIG. 1;
5A and 5B are partial cross-sectional views illustrating modifications of the wavelength band adjusting portion of the optical transmission system shown in FIG. 1; and
6 is a partial cross-sectional view illustrating another modified example of the wavelength band adjusting unit of the optical transmission system shown in FIG. 1.

Hereinafter, an optical transmission system having a light collecting device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

First, referring to FIG. 1, an optical transmission system 1 having a light collecting device according to an embodiment of the present invention is schematically illustrated.

The light transmission system 1 of the present invention is, for example, mounted on the sea surface 4 so as to float, and provides an optical transmission buoy for supplying sunlight 3 to a necessary place 2 such as an artificial reef of the seabed 7. The system includes a light collecting device 10, a light transmission line 20, and a second optical means 30.

The light collecting device 10 constitutes a light fixture for condensing sunlight 3 and illuminating the light 3 to the artificial reef 2, for example, a light utilization means requiring sunlight 3. It is supplied to the optical transmission line 20 is connected to the second optical means (30).

The light concentrating device 10 is installed on an ellipsoid-shaped subbody 11 and includes a first reflecting mirror 13, a second reflecting mirror 14, and a first optical means 15. The secondary body 11 is formed of a hollow ellipsoid of a plastic material or a metal material having a space capable of forming a predetermined buoyancy therein so as to keep the entire condenser 10 floating above the sea surface 4. It is fixed near the artificial reef 2 of the seabed 7 by a wire 6 connected to the anchor 5.

The first reflecting mirror 13 reflects and converges the sunlight 3 toward the first optical means 15. The first reflecting mirror 13 has an upper portion of the subsidiary body 11 by suitable fixing means (not shown) such as a screw and a fixing bracket. It is fixed at the center and provided with a reflective surface 13a therein. In the present embodiment, as shown in FIG. 2, the first reflector 13 may be configured as a cup-shaped reflector in the form of a conical shape having a large conical shape in which the inner reflecting surface 13a has almost no curvature. Here, although the reflective surface 13a has been described as having almost no curvature, as shown in FIG. 3, the concave constant is increased to increase the amount of sunlight 3 directly converged toward the second optical means 15. It may be configured to have a curvature.

Referring again to FIG. 1, the second reflector 14 reflects sunlight 3 upwardly reflected by the first reflector 13 toward the first optical means 15, and the first reflector 14 reflects the first light to the first optical means 15. The corresponding reflection surface 14a which faces the reflection surface 13a of the reflector 13 is provided. The second reflecting mirror 14 is disposed at the upper center of the semi-spherical transparent dome 17 covering the opening 13b of the first reflecting mirror 13 to which the sunlight 3 is incident. The transparent dome 17 may be formed of glass or transparent plastic material so as to transmit sunlight 3. Accordingly, the incident space of the solar light 3 in the form of a circular band is formed at the portion of the transparent dome 17 between the first reflecting mirror 13 and the second reflecting mirror 14.

In this embodiment, as shown in FIG. 2, the second reflecting mirror 14 faces the reflecting surface 13a of the first reflecting mirror 13 and is smaller than the diameter of the opening 13b of the first reflecting mirror 13. It may be composed of an inverted dish reflector having a reflective curved surface 14a having a diameter. However, as shown in FIG. 3, the curvature of the reflecting surface 13a ′ of the first reflecting mirror 13 ′ may increase the amount of convergence of the sunlight 3 directly toward the first optical means 15. When configured to have, the second reflector 14 'may be configured as a reflector having a reflecting plane 14a' on the lower surface instead of the dish-shaped reflector 14 having the reflecting curved surface 14a.

As described above, the optical transmission system 1 of the present invention uses the second reflector 14 to emit sunlight 3 even though the first reflector 13 does not converge the sunlight 3 toward the first optical means 15. Is further converged toward the first optical means 15, so that the curvature of the first reflector 13 is increased to increase the amount of condensing under the same opening condition, and as a result, the first reflector 13 and the condenser 10 Even if the height, that is, the size is not increased, the light collecting efficiency of the sunlight can be doubled.

The first optical means 15 collects the sunlight 3 that is reflected by the first and second reflectors 13 and 14 and is incident as parallel light and converges to one place, that is, the second optical means. Converging to the optical transmission line 20 connected to the means 30, it is fixed to the receiving opening (13c) formed in the lower center of the first reflecting mirror (13).

In the present embodiment, the first optical means 15 may be composed of at least one convex lens 16. Here, in order to facilitate the example, although the convex lens 16 is illustrated and described as one, it may be composed of a plurality of, for example, six.

In the optical transmission line 20, the incident end of the light penetrating the lower part of the sub-body 11 is fixed at a predetermined distance from the first optical means 15, and the sunlight 3 converged by the first optical means 15. ) Is transferred to the second optical means 30 arranged at the exit end.

In the present embodiment, the optical transmission line 20 may be composed of an optical fiber cable 21 having at least one optical fiber cable shim wrapped by cladding. Here, in order to facilitate the example, the optical fiber cable 21 is illustrated and described as having one optical fiber cable shim, but may be composed of a plurality, for example, six corresponding to each convex lens 16. .

Only light with wavelength bands that require transmission, such as infrared light, visible light, ultraviolet light to aid photosynthesis of artificial reefs 2, two or more complex lights, or light similar to natural light reaching through clear sea water In order to pass the light, the wavelength band adjusting unit 25 is disposed between the first optical means 15 and the optical transmission line 20 of the light collecting device 10.

As shown in Figs. 4A and 4B, in this embodiment, the wavelength band adjusting section 25 is controlled from an external control station (not shown) to be transmitted through the antenna 36 of the communication section 35 described later. It may be composed of a filter changer 26 driven by the control unit 33 installed in the sub-body 11 according to the signal. The filter changer 26 is connected to the motor 28 driven by the motor drive part (not shown) of the control part 33, and the motor shaft 28a under the control of the control part 33, respectively, and the other wavelength as mentioned above. Spokes 31 are equipped with a plurality of filters 29 for passing light having a band. The control unit 33 is supplied with the necessary power by the power supply unit 37, such as a battery disposed on one side of the control unit 33 in the subsidiary body 11,

Therefore, when a control signal from the outside is transmitted to the control unit 33 through the communication unit 35, the control unit 33 drives the motor 28 through the motor driving unit to select a specific wavelength band required among the plurality of filters 29. An ultraviolet filter for passing only light having, for example, ultraviolet light, is positioned between the first optical means 15 and the light transmission line 20.

Optionally, as shown in FIG. 5A, the wavelength band adjusting unit 25 ′ is driven by the control unit 33 in accordance with a control signal transmitted from an external control station through the antenna 36 of the communication unit 35. It may be composed of a grating strain type wavelength band converter 41. The grating modified wavelength band converter 41 applies a voltage to the piezoelectric element 41a connected to the grating of the optical fiber cable 21 'under the control of the control unit 33, thereby modifying the period of grating according to the applied voltage to the optical fiber cable. The sunlight 3 passing through 21 'is changed into light having a specific wavelength band required.

In addition, as shown in FIG. 5B, the wavelength band adjusting unit 25 ″ is driven by the control unit 33 according to a control signal transmitted from an external control station through the antenna 36 of the communication unit 35. It can be composed of a variable wavelength band converter 41 '. The thermal variable wavelength band converter 41' is connected to an optical fiber cable 21 "injecting liquid crystal into a cladding region under the control of the control unit 33. Of the sunlight 3 passing through the optical fiber cable 21 "by applying heat through the thermoelectric element 41a 'or the like, the light of the wavelength band which is not necessary is quenched and only the light having the required wavelength band is quenched. Pass it through.

The wavelength band adjusting section 25, 25 ', 25 " is controlled in accordance with a control signal from an external control station to change the wavelength band of the sunlight 5 incident on the optical transmission line 20, or the system 1 In order to inform its external control station via satellite GPS, the optical transmission system 1 of the present invention further includes a communication unit 35 capable of communicating with the outside.

The communication unit 35 is connected to the control unit 33 inside the subcarrier 11, and under the control of the control unit 33, the satellite GPS and the control station through the antenna 36 protruded and fixed to an upper side of the subcarrier 11. A communication system for wirelessly transmitting and receiving a signal, for example, may be a satellite communication system or a wireless communication system. Alternatively, the communication unit 35 may be a Ubiquitous Sensor Network (USN) system. When the communication unit 35 is a USN system, a sensor network may be formed through a plurality of optical transmission systems.

Optionally, as shown in FIG. 6, the wavelength band adjusting unit 25 ″ ′ moves the incidence end of the optical transmission line 20 from the convex lens 16 of the first optical means 15 of the light converging device 10. It may include a spacer 41 "to be kept at a position separated by the focal length (D) of the light having the required wavelength band. The spacer 41 ″ has an upper end (left side of FIG. 6) fixedly supported to a lower portion of the first reflector 13 that fixes the first optical means 15, and a lower end (right side of FIG. 6) has an optical transmission line 20. It may be a transparent tube (41a ") for fixing the incidence end of. For example, as shown in Fig. 6, when the light having the required wavelength band is ultraviolet light 3a, the transparent tube 41a "is used to check the light transmission line 20 before installing the light transmission system 1 at sea. An ultraviolet transparent tube for fixing the incident end at a position separated by the focal length D of the ultraviolet ray from the first optical means 15 may be selected and installed, in this case, as shown by the dotted line in FIG. This longer visible light 3b and infrared ray 3c are externally reflected through the transparent tube 41a "and naturally quenched.

As such, when the wavelength band adjusting unit 25 ″ 'is constituted by a spacer 41 ″ that cannot be driven by the control unit 33, the communication unit 35 is controlled by an external unit via satellite GPS under the control of the control unit 33. It operates to inform only the position of the optical transmission system 1 to the control station.

The second optical means 30 is fixed to the fixture 45 installed at the output end of the optical transmission line 20, and diffuses parallel light transmitted through the optical transmission line 20 as divergent light toward the artificial reef (2). In the present embodiment, the second optical means 30 may be composed of at least one spread lens, for example, a concave lens 30a. Here, in order to facilitate the example, the concave lens 30a is illustrated and described as one, but a plurality of, for example, six, corresponding to the optical fiber cable shims of the optical fiber cable 21 of the optical transmission line 20 Can be.

As described above, the optical transmission system 1 according to the present invention is installed to be floated on the sea surface 4 as an optical transmission buoy system for supplying sunlight 3 to a necessary place 2 such as an artificial reef of the seabed 7. Although the present invention has been illustrated and described, the present invention is not limited thereto, and the solar light may be collected from another system, for example, outside the building and transmitted to an interior space or a plant cultivation room, or the solar light may be collected by condensing the sunlight in a place having a good condensing environment. The same configuration and principle may be applied to an optical transmission system that transmits to a place with poor environment.

The operation of the optical transmission system 1 having the light concentrating device 10 according to the exemplary embodiment of the present invention configured as described above will be described in detail with reference to FIGS. 1, 2, 4A, and 4B. .

First, the optical transmission system 1 drops the gravity weight or anchor 5 connected through the wire 6 below the float 11 to the sea near the artificial reef so that the float 11 floats above the sea level 4. It is fixed to the seabed 7 so as to.

In this case, as shown in FIGS. 1 and 2, the light of the light 3 is formed in the shape of a circular band formed on the transparent dome 17 between the first reflecting mirror 13 and the second reflecting mirror 14. The incident light is incident on the reflecting surface 13a of the first reflecting mirror 13 and partly reflected toward the first optical means 15 and partly reflecting toward the second reflecting mirror 14 according to the incident angle.

The sunlight 3 reflected toward the second reflector 14 is partially reflected toward the first optical means 15 depending on the incident angle incident on the corresponding reflecting surface 14a of the second reflector 14. Reflected toward the first reflector 13. The sunlight 3 reflected toward the first reflector 13 repeats the operation described above.

Thus, the sunlight 3 converged by the parallel light to the first optical means 15 is collected by the first optical means 13 and sent to the wavelength band adjusting section 25 as converged light.

At this time, if a control signal for passing only light having a required wavelength band, for example, ultraviolet rays, is transmitted from an external control station, as shown in FIGS. 2 and 4B, the controller 33 controls the antenna 36. Receives a control signal from the communication unit 35 through the, and drives the motor 28 through the motor driving unit to enter the ultraviolet filter of the plurality of filters 29 of the first optical means 15 and the optical transmission line 20 Place between stages.

As a result, the sunlight 3 passes only the ultraviolet rays through the ultraviolet filter, and the ultraviolet rays passing through the ultraviolet filter are moved to the exit end of the optical transmission line 20 through the optical transmission line 20.

The ultraviolet rays that reach the exit end of the optical transmission line 20 are converted into divergent light diffused from the parallel light toward the artificial reef 2 through the second optical means 30 again. As a result, marine plants and meat that are inhabited in the artificial reef 2 are promoted to grow or grow by ultraviolet rays.

At this time, if you want to check the position of the optical transmission system 1 in the external control station, the external control station is a position signal or position of the control station periodically transmitted by the communication unit 35 under the control of the control unit 33 It is possible to check the position of the optical transmission system 1 by receiving a positioning signal transmitted in response to the confirmation signal via satellite GPS.

As described above, the light transmission system of the present invention can increase the light condensing efficiency of the solar light while reducing the size of the light concentrating device, and can convert the condensed sun light into light having a required wavelength band and supply it to a required place.

In addition, the optical transmission system of the present invention can freely communicate with the outside, and control the wavelength band adjusting unit according to a control signal from the outside to change the wavelength band of the light or inform the outside of the system itself.

  In the above, the present invention has been described and illustrated in connection with embodiments for illustrating the principle, but the present invention is not limited to the configuration and operation shown and described as such. In addition, it will be understood by those skilled in the art that various changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims. Accordingly, all suitable changes, modifications, and equivalents to the present invention should be considered to be within the scope of the present invention.

1: optical transmission system 10: condenser
11: Vice 13: the first reflector
14: second reflecting mirror 15: first optical means
16: Convex Lens 17: Transparent Dome
20: optical transmission line 21, 21 ', 21 ": optical fiber cable
25, 25 ', 25 ", 25"': wavelength band adjusting section
26: filter replacement 28: motor
29: filter 30: second optical means
30a: concave lens 31: spoke
33: control unit 35: communication unit
41, 41 ': Wavelength Converter 41 ": Spacer

Claims (13)

A first reflecting mirror having a reflecting surface for reflecting and converging light, a second reflecting mirror reflecting the light reflected by the first reflecting mirror, and a second converging light reflecting by the first and second reflecting mirrors A light concentrating device comprising one optical means;
An optical transmission line having an incident end connected to the light collecting device;
Second optical means disposed at an output end of the optical transmission line and configured to diffuse light emitted through the optical transmission line; And
A wavelength band adjusting unit disposed between the light collecting device and the optical transmission line and passing only light having a wavelength band requiring transmission;
Optical transmission system comprising a. The light transmission system of claim 1, wherein the first reflector comprises a cup reflector. The optical transmission system according to claim 1, wherein the second reflector comprises a reflector having one of a reflection curved surface and a reflection plane facing the reflection surface of the first reflection mirror. The optical transmission system as claimed in claim 1, wherein the second reflecting mirror is disposed at the center of the transparent dome covering the opening of the first reflecting mirror. An optical transmission system according to claim 1, wherein said first optical means comprises at least one convex lens. delete 6. The optical transmission system according to any one of claims 1 to 5, wherein the optical transmission line comprises an optical fiber cable having at least one optical fiber cable shim. 6. The optical transmission system according to any one of claims 1 to 5, wherein said second optical means comprises at least one concave lens. delete The filter according to any one of claims 1 to 5, wherein the wavelength band adjusting unit selectively positions one of a plurality of filters passing light having different wavelength bands between the light converging device and the optical transmission line. A grating strain wave that applies a voltage to an exchanger and a piezoelectric element connected to an optical fiber grating to strain the period of the optical fiber grating according to the applied voltage to change the light passing through the optical fiber cable into light having a required wavelength band. One of the band converter and the heat-changing wavelength band converter which applies heat to the optical fiber cable injecting liquid crystal in the cladding region through a thermoelectric element to extinguish the unnecessary wavelength light passing through the optical fiber cable according to the applied temperature. Optical transmission system comprising a. 6. The optical transmission according to any one of claims 1 to 5, wherein the wavelength band adjusting unit includes a spacer for maintaining a distance between the light concentrating device and the optical transmission line at a focal length of light having a required wavelength band. system. The method according to any one of claims 1 to 5, wherein the wavelength band adjusting unit is controlled according to a control signal from the outside to change the wavelength band of the light incident on the optical transmission line or to inform the outside of the position of the system itself. The optical transmission system further comprises a communication unit capable of communicating with the outside. 6. The optical transmission buoy system according to any one of claims 1 to 5, wherein the optical transmission system includes an auxiliary body for keeping the light collecting device floating on the sea surface and supplies solar light to a required place on the sea floor. Optical transmission system comprising a.

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