This application claims priority of Taiwanese application no. 096126006, filed on Jul. 17, 2007.
1. Field of the Invention
The invention relates to an illuminating system, more particularly to an optical illuminating system capable of receiving and scattering light from a primary light source, such as the sun.
2. Description of the Related Art
In recent years, solar powered devices have been proposed to supply power to electrical illuminating systems. In practice, solar energy is converted into electrical energy using solar cells, and the electrical energy is subsequently converted into light energy when the electrical illuminating system is activated. While electric power consumption can be saved through such a scheme, conversion from solar energy into electrical energy and from electrical energy into light energy are inefficient. In particular, since efficiency of conversion from solar energy into electrical energy is only about 12%, and since efficiency of conversion from electrical energy into light energy is only about 25%, only 3% of solar energy is actually utilized for illumination.
There is thus a need to find ways to make more efficient use of solar energy.
Therefore, the object of the present invention is to provide an optical illuminating system that is capable of using solar energy efficiently.
According to the present invention, there is provided an optical illuminating system adapted to receive and scatter light from a primary light source, such as the sun. The optical illuminating system comprises a light input device adapted for receiving the light from the primary light source, a light output device, and a light transmission device that is coupled optically to the light input device and the light output device for transmitting the light received by the light input device to the light output device by total reflection. The light output device scatters the light received from the light transmission device for output.
Other features and advantages of the present invention will become apparent in the following detailed description of the embodiments with reference to the accompanying drawings, of which:
Before the present invention is described in greater detail with reference to the accompanying embodiments, it should be noted herein that like elements are denoted by the same reference numerals throughout the disclosure.
Referring to
The primary light source 1 is the sun.
The auxiliary light source 2 is an artificial light source, such as a metal Halide discharge lamp.
The control device 3 is coupled to the auxiliary light source 2 for controlling intensity of illumination of the auxiliary light according to illumination of the light from the primary light source 1. Through control of the auxiliary light source 2 by the control device 3, adequate illumination can be ensured even when illumination from the primary light source 1 is insufficient.
The light input device 4 is configured to receive the light from the primary light source 1 and the auxiliary light from the auxiliary light source 2, and is movable to follow direction of the primary light source 1. In this embodiment, the light input device 4 includes: a condenser 41 for gathering the light from the primary light source 1 and the auxiliary light from the auxiliary light source 2; an input component 42 having a light incident side located proximate to a focal point of the condenser 41, and a light exit side coupled optically to the light transmission device 5; a reflective film 43 formed on the condenser 41 for reflecting infrared light and ultraviolet light; an anti-reflective film 44 formed on an end face of the light incident side of the input component 42 for preventing reflection of visible light; and a control unit 45 for controlling magnitude of light flux received by the condenser 41. In this embodiment, the light incident side of the input component 42 has a cross-sectional area larger than that of the light exit side. In addition, the light incident side of the input component 42 may have a flat or a concave end face. In this embodiment, the cross-sectional area of the light incident side of the input component 42 is slightly larger than a beam area of light received from the condenser 41. The control unit 45 can be halogen glass widely used in sunglasses or an adjustable iris mechanism used in cameras, and serves to block overabundant sunlight in summer, sunny days or noontime into a room that is installed with the optical illuminating system of this invention. In this embodiment, the area of the condenser 41 is designed according to average sunlight in an entire year. Thus, when there is overabundant sunlight in summer, sunny days or noontime, the control unit 45 is used to limit the magnitude of light flux received by the condenser 41. As a result, large differences in brightness in a room between summer and winter, sunny days and cloudy days, noontime and other time periods, etc., can be avoided.
The light transmission device 5 includes a light transmitting component 51 coupled optically to the input component 42 of the light input device 4 and the light output device 6 for transmitting the light received by the input component 42 of the light input device 4 to the light output device 6 by total reflection. The light propagating through the input component 42 enters the light transmitting component 51 at incident angles of less than 15 degrees.
The light output device 6 is used to scatter the light received from the light transmission device 5 for output, and includes: an output component 61 that has a light input side coupled optically to the light transmitting component 51 of the light transmission device 5 and that has a light output side; a hemispherical lampshade 62 having the output component 61 extending therein and having an open side; a transparent lens plate 63 for closing the open side of the hemispherical lampshade 62; and a scattering lens 64 located in the lampshade 62 between the light output side of the output component 61 and the transparent lens plate 63. In this embodiment, the output component 61 gradually diverges from the light input side to the light output side. The light output side of the output component 61 may have a flat or a concave end face.
In operation, the light from the primary light source 1 and the auxiliary light from the auxiliary light source 2 pass in sequence through the condenser 41 and the input component 42 and enter the light transmitting component 51 at incident angles of less than 15 degrees. The light transmitting component 51 transmits the light from the input component 42 to the output component 61 by total reflection. The light that exits the output component 61 is scattered by the scattering lens 64 and is subsequently outputted through the transparent lens plate 63.
In the first embodiment, the light from the primary light source 1 and the auxiliary light from the auxiliary light source 2 are directly received, transmitted and outputted through the light input device 4, the light transmission device 5 and the light output device 6. No energy conversion is involved, and light from the primary light source 1 and the auxiliary light source 2 are utilized directly. Since energy losses attributed to energy conversions in the prior art can be avoided, the energy utilization efficiency is significantly increased. Moreover, by using the sun as the primary light source 1, use of limited natural energy resources on the planet can be reduced. Furthermore, through the auxiliary light source 2 and the control device 3, adequate illumination can be ensured even when illumination from the primary light source 1 is insufficient (such as at night or during cloudy days).
In this embodiment, the light input device 4 is for receiving the light from the primary light source 1, whereas the auxiliary light input device 7 is for receiving the auxiliary light from the auxiliary light source 2. The auxiliary light input device 7 is coupled optically to the light transmission device 5′. The light transmission device 5′ merges the light received by the light input device 4 with the auxiliary light received by the auxiliary light input device 7 for subsequent transmission to the light output device 6 by total reflection.
The auxiliary light input device 7 includes: an auxiliary condenser 71 for gathering the auxiliary light from the auxiliary light source 2; an auxiliary input component 72 that has a light incident side located proximate to a focal point of the auxiliary condenser 71 and that has a light exit side coupled optically to the light transmission device 5′; a reflective film 73 formed on the auxiliary condenser 71 for reflecting infrared light and ultraviolet light; and an anti-reflective film 74 formed on an end face of the light incident side of the auxiliary input component 72 for preventing reflection of visible light. In this embodiment, the light incident side of the auxiliary input component 72 has a cross-sectional area larger than that of the light exit side of the auxiliary input component 72. The auxiliary light propagating through the auxiliary input component 72 enters the light transmission device 5′ at incident angles of less than 15 degrees. The light incident side of the auxiliary input component 72 may have a flat or a concave end face. In this embodiment, the cross-sectional area of the light incident side of the auxiliary input component 72 is slightly larger than a beam area of light received from the auxiliary condenser 71.
The light transmission device 5′ includes a light merging component 52 and three light transmitting components 51. The light merging component 52 has a first branch portion 521 coupled optically to the input component 42 of the light input device 4 via a first one of the light transmitting components 51, a second branch portion 522 coupled optically to the auxiliary input component 72 of the auxiliary light input device 7 via a second one of the light transmitting components 51, and a merging portion 523 coupled optically to the first and second branch portions 521, 522. The merging portion 523 is coupled optically to the output component 61 of the light output device 6 via a third one of the light transmitting components 51, which transmits light merged by the merging portion 523 to the output component 61 of the light output device 6 by total reflection. In this embodiment, the first and second branch portions 521, 522 are merged into the merging portion 523 in a same direction and at an angle not larger than 10 degrees.
In operation, the light from the primary light source 1 passes in sequence through the condenser 41, the input component 42, the first one of the light transmitting components 51, and the first branch portion 521. On the other hand, the auxiliary light from the auxiliary light source 2 passes in sequence through the auxiliary condenser 71, the auxiliary input component 72, the second one of the light transmitting components 51, and the second branch portion 522. Thereafter, the light from the first branch portion 521 and the light from the second branch portion 522 are merged by the merging portion 523, and the third one of the light transmitting components 51 transmits the merged light to the output component 61 by total reflection. The light that exits the output component 61 is scattered by the scattering lens 64 and is subsequently outputted through the transparent lens plate 63.
Each of the light receiving units 40 includes a condenser 41, an input component 42, a reflective film 43, an anti-reflective film 44, and a control unit 45 (only the condenser 41 and the input component 42 are shown in
Each of the light receiving units 40 includes a condenser 41, an input component 42, a reflective film 43, an anti-reflective film 44, and a control unit 45 (only the condenser 41 and the input component 42 are shown in
It should be noted that the primary light source 1 can be an artificial light source in other applications of the third and fourth embodiments of this invention. In such applications, the auxiliary light source 2 and the control device 3 are not required. High-power light generated by the artificial light source is similarly distributed among various output units of the light output device through the light input device and the light transmission device. Since a high-power light source consumes less energy when generating high-power light, for instance, a 1200 W metal Halide discharge lamp can emit 120000 lumens of light corresponding to the amount emitted by 100 100 W incandescent light bulbs, efficient energy utilization is still possible when the artificial light source is utilized as the primary light source 1.
Referring to
In summary, through the optical illuminating system of this invention, light from the primary light source 1 is directly received, transmitted, and outputted through the light input device 4, the light transmission device 5 and the light output device 6. No energy conversion is involved, and energy losses attributed to energy conversions in the prior art can be avoided, thereby increasing the energy utilization efficiency significantly. Moreover, by using the sun as the primary light source 1, use of limited natural energy resources on the planet can be reduced. The purpose of this invention is accordingly served.
While the present invention has been described in connection with what are considered the most practical embodiments, it is understood that this invention is not limited to the disclosed embodiments but is intended to cover various arrangements included within the spirit and scope of the broadest interpretation so as to encompass all such modifications and equivalent arrangements.
Number | Date | Country | Kind |
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096126006 | Jul 2007 | TW | national |