JP2018018981A - Fluorescent light confinement structure of sunlight excitation laser device - Google Patents

Abstract

Kind Code: A1 A fluorescent light guide plate is formed of a material having a refractive index higher than that of the outside and in which a fluorescent material that absorbs sunlight incident from a sunlight incident surface and emits fluorescence in a wavelength band to which a laser medium has high sensitivity is dispersed. and a fluorescence/laser conversion means for generating a laser from the fluorescence emitted from the fluorescent substance and propagated through the fluorescence light guide plate, preventing the fluorescence from leaking out of the device without generating a laser. prevent. A dichroic mirror, which transmits light in a wavelength range absorbed by a fluorescent substance but reflects fluorescence emitted by the fluorescent substance, is provided opposite to and spaced apart from the sunlight incident surface of the fluorescent light guide plate. [Selection drawing] Fig. 3

Description

  The present invention relates to a sunlight-excited laser device that emits fluorescence by irradiating a fluorescent material with sunlight, and generates a laser by irradiating the fluorescence to a fluorescence / laser conversion means. The fluorescent light is confined in the device so as to prevent leakage outside the device.

Various technologies utilizing solar energy have been proposed as one of the countermeasures against global warming and other environmental problems, and a solar-excited laser for generating laser light using sunlight as an energy source or excitation light source. Various techniques have also been proposed. In general, in the case of solar-excited lasers, solid materials such as YAG (yttrium, aluminum, garnet) crystals to which neodymium ions (Nd ³⁺ ) are added as a laser medium are used from the viewpoint of durability and convenience when installed outdoors. On the other hand, the energy density of sunlight on the ground is approximately 1 kw / m ² even under the best conditions, and laser oscillation is achieved in laser materials such as YAG crystals using sunlight. In order to do so, it is necessary to concentrate the intensity of sunlight reaching the ground to several thousand to 10,000 times. Therefore, for example, in Patent Documents 1 and 2, Non-Patent Document 1 and the like, sunlight is condensed using a large lens or a Fresnel lens, and a laser material is arranged at the focal point of those lens systems. A configuration has been proposed. In such a configuration, since the direction of sunlight (incident angle to the ground) changes every moment, the configuration of changing the direction of the condenser lens system in accordance with the direction of sunlight (sunlight tracking system) ) Is used. Further, in Non-Patent Document 2, in the wavelength distribution of the intensity of sunlight as it is, the wavelength of light that can be used for excitation of the laser medium is limited, so that the absorption wavelength band is wide and A configuration has been proposed in which sunlight is absorbed by a fluorescent material having a narrow emission wavelength, and a laser medium is pumped by fluorescence from the fluorescent material, thereby reducing the light collection magnification to about 300 times.

JP2011-23377 JP2013-235930A JP2015-201464

Applied Physics Letters 90, 261120, 2007 Nature Insight Scientific Reports 5, 14758, 2015

As described above, in the configuration of the conventional solar pumped laser apparatus, the lens and the mechanism for changing the direction (solar tracking mechanism) are used to track the sunlight. When installing the apparatus, it is necessary to secure a space for the solar light tracking mechanism, and therefore, a larger facility and place than the laser body are required. In addition, there is a limit to increasing the size of the condensing lens, and it is considered to convert sunlight irradiated over a wide area of several km ² or more into laser light as in a large-scale photovoltaic power generation facility. It is necessary to provide a large number of condenser lenses having a size of several m ² to several tens m ² and their tracking mechanisms. And, as mentioned above, the optical system is adjusted so that the focus of the condenser lens that is displaced for tracking the sunlight always hits the laser material, the wind and other factors (passing of nearby vehicles) Etc.), a configuration for maintaining the focus of the condensing lens on the laser material is necessary (laser oscillation stops when the focus is out of the laser material). . In general, when a solar light tracking mechanism is used in a solar light excitation laser apparatus, large-scale facilities, locations, labor for adjustment, and costs are required for solar light tracking. Therefore, it is very useful to have a configuration that can achieve laser oscillation by sunlight without requiring a sunlight tracking mechanism.

Therefore, under the above recognition, the same person as the present inventor is a solar-pumped laser device as a solar-pumped laser device that does not require a solar tracking mechanism in the previous Japanese Patent Application No. 2006-53073,
A laser medium comprising a first surface, a second surface, and an edge surface connecting peripheral edges of the first and second surfaces, and absorbing sunlight in the inside or on the first or second surface. A fluorescent material that emits fluorescence in a highly sensitive wavelength band is dispersed and has a plate-like structure formed of a material having a higher refractive index than the outside, and when sunlight enters from the first surface, A fluorescent light guide plate in which emitted fluorescence is substantially condensed on the edge surface and emitted;
A single optical fiber wound along the peripheral direction of the first and second surfaces on the edge surface of the fluorescent light guide plate, and the core portion in which the laser medium is dispersed, and the surface and the inside transmit the fluorescence. A clad portion formed of a material having a refractive index lower than that of the core portion, a first reflecting means for reflecting substantially all of the light emitted by the laser medium at one end face of the optical fiber, A second reflecting means for transmitting a part of the light emitted from the laser medium at the other end face of the optical fiber and reflecting the remaining light, and the fluorescence emitted from the edge of the fluorescent light guide plate is the surface of the cladding part. Proposed an apparatus including an optical fiber that passes through the core and reaches the core, and that can excite a laser medium by fluorescence to achieve laser oscillation, and that laser light is emitted from the other end face of the optical fiber.

  As shown in the attached FIG. 1, the above-described solar-pumped laser apparatus has a fluorescent substance FM that absorbs sunlight SL and emits fluorescence in a wavelength band with a high sensitivity of the laser medium and is dispersed from the outside. The fluorescent light guide plate 2 having a plate-like structure made of a material having a high refractive index is provided, and the fluorescent material FM is irradiated with the sunlight SL incident thereon, and the fluorescent FL is emitted. A laser propagating along the optical fiber 3a is generated by irradiating the optical fiber 3a having the core of the laser medium mounted around the fluorescent light guide plate 2. In such a structure, the fluorescent light is emitted from the optical fiber 3a. However, when the optical fiber 3a is directly irradiated as in FL (1), the light is incident on the sunlight incident surface 2a of the fluorescent light guide plate 2 with a relatively large deflection angle as in FL (2) and is totally reflected. In the case where the optical fiber 3a is irradiated and the light is reflected by the reflecting mirror 6 and irradiated to the optical fiber 3a as in FL (3), the fluorescence effectively acts on the generation of the laser. Since the reflectance at the surface 2a with respect to the incident angle of the fluorescence with respect to 2a changes as shown in FIG. 2, the fluorescence is incident with a relatively small deflection angle with respect to the sunlight incident surface 2a of the fluorescent light guide plate 2 as FL (4). In this case, there is a problem that a large proportion of the light leaks out of the fluorescent light guide plate 2 without being reflected by the surface 2a.

  The present invention is a fluorescent light guide formed of a material in which a fluorescent material that absorbs sunlight incident from a sunlight incident surface and emits fluorescence in a wavelength band with a high sensitivity of the laser medium is dispersed and has a higher refractive index than the outside. An optical plate and a core portion in which the laser medium in the above example is dispersed, for example, an optical fiber that generates a laser by fluorescence emitted from the fluorescent material and propagated through the fluorescent light guide plate, and absorbs the fluorescence as an optical fiber. Focusing on the above-mentioned problem in the solar-excited laser device having the fluorescence / laser conversion means to be generated, the fluorescence is applied so that the fluorescence emitted from the fluorescent material is prevented from leaking out of the device without generating a laser. It is an object to provide a structure to be confined inside.

  In order to solve the above-described problems, the present invention is a phosphor material that absorbs sunlight incident from a sunlight incident surface and emits fluorescence in a wavelength band with high sensitivity of the laser medium, and has a refractive index that is higher than that of the outside. In a solar light excitation laser apparatus having a fluorescent light guide plate formed of a high material and a fluorescence / laser conversion means for generating a laser by fluorescence emitted from the fluorescent material and propagated in the fluorescent light guide plate, A structure that prevents the emitted fluorescence from leaking out of the fluorescent light guide plate from the sunlight incident surface of the fluorescent light guide plate allows light in a wavelength region that is absorbed by the fluorescent material to be transmitted but the fluorescent material is Proposed is a structure characterized in that a dichroic mirror for reflecting emitted fluorescence is provided opposite to and spaced from the sunlight incident surface of the fluorescent light guide plate. Than is.

  In the above structure, a low refractive index layer may be provided between the sunlight incident surface of the fluorescent light guide plate and the dichroic mirror spaced apart from the sunlight incident surface.

  As described above, a fluorescent material made of a material in which a fluorescent material that absorbs sunlight incident from the sunlight incident surface and emits fluorescence in a wavelength band with high sensitivity of the laser medium is dispersed and has a higher refractive index than the outside. In a sunlight-excited laser device having an optical plate and a fluorescence / laser conversion means for generating a laser by fluorescence emitted from the fluorescent material and propagated in the fluorescent light guide plate, the fluorescence emitted from the fluorescent material is converted into the fluorescent light guide. As a structure for preventing leakage from the sunlight incident surface of the light plate to the outside of the fluorescent light guide plate, a dichroic mirror that transmits light in a wavelength region absorbed by the fluorescent material but reflects fluorescence emitted from the fluorescent material is provided. If the fluorescent light guide plate is provided so as to be opposed to and spaced from the sunlight incident surface of the fluorescent light guide plate, as shown by FL (4) in FIG. The fluorescence leaking fluorescent light plate outside by entering with a relatively small deflection angle to the light incident surface, can either be returned dichroic is reflected by dichroic mirror to the fluorescent light guide plate within. In this case, the reflection characteristic of the dichroic mirror with respect to the fluorescence is disturbed by the contact with the fluorescent light guide plate because the dichroic mirror is provided facing the sunlight incident surface of the fluorescent light guide plate and spaced apart therefrom. It is avoided.

  Alternatively, in the above structure, if a layer of a low refractive index material is provided between the sunlight incident surface of the fluorescent light guide plate and the dichroic mirror spaced apart from the sunlight incident surface, the fluorescent material emitted from the fluorescent material is emitted. The dichroic mirror can be stably fixed to the fluorescent light guide plate without disturbing the reflection characteristics of the dichroic mirror.

It is sectional drawing which illustrates the fluorescence behavior in the sunlight excitation laser apparatus by Japanese Patent Application No. 2006-53073 which is said previous proposal. It is a graph which shows the reflectance with respect to an incident angle when the fluorescence which propagates the inside of a fluorescence light-guide plate injects into the surface of a fluorescence light-guide plate from the inner side. It is sectional drawing which shows the Example which assembled | attached the structure which prevents the leakage of the fluorescence to the exterior of the fluorescence light-guide plate by this invention to the sunlight excitation laser apparatus shown in FIG. It is a graph which shows the state which matched the characteristic of the wavelength with respect to the transmittance | permeability of a dichroic mirror to the structure which prevents the leakage of the fluorescence out of the fluorescence light-guide plate by this invention. It is sectional drawing which shows the other Example which assembled | attached the structure which prevents the leakage of the fluorescence to the exterior of the fluorescence light-guide plate by this invention to the sunlight excitation laser apparatus shown in FIG.

  In the embodiment of the present invention shown in FIG. 3, as described above, the structure for preventing leakage of fluorescence outside the fluorescent light guide plate according to the present invention is assembled to the solar light pumped laser apparatus shown in FIG. In FIG. 3, a plate-like body shown as 10 is a dichroic mirror. The dichroic mirror here refers to a structure in which a plurality of dielectric thin films having different refractive indexes are laminated so that light having a certain critical wavelength or less is transmitted to nearly 100% as shown in FIG. Is a film body exhibiting almost blocking or reflecting characteristics, and the dichroic mirror 10 transmits light in the wavelength region absorbed by the fluorescent material FM in the sunlight SL but reflects the fluorescent FL emitted by the fluorescent material FM. Such a film body designed as described above is incorporated into a fluorescent light guide plate.

  The fluorescent light guide plate 2 may be made of quartz glass or transparent polycarbonate resin, alkali resin, acrylic resin, or silicone resin. The dichroic mirror 10 is directly attached to the fluorescent light guide plate 2 made of such a material. If so, the light transmission characteristics of the dichroic mirror 10 may be disturbed by the refractive index of the fluorescent light guide plate. Therefore, the dichroic mirror 10 is provided so as to be opposed to and spaced from the sunlight incident surface 2a of the fluorescent light guide plate 2, and as a result, the dichroic mirror 10 is designed as shown in FIG. The light transmission characteristics can be stably maintained. Thus, the fluorescence such as the fluorescence FL (4) incident on the sunlight incident surface 2a with a relatively small deflection angle leaks out of the fluorescence light guide plate 2 at one end, but is reflected by the dichroic mirror 10 and reflected by the fluorescence light guide plate. 2 is returned.

  FIG. 5 shows that the space between the sunlight incident surface 2a of the fluorescent light guide plate 2 and the dichroic mirror 10 in the solar light excitation laser device shown in FIG. 3 is filled with a layer 12 of a low refractive index material such as a low refractive index silicone resin. 4 shows another embodiment of the present invention. Thus, if the space between the sunlight incident surface 2a of the fluorescent light guide plate 2 and the dichroic mirror 10 is filled with a layer of a low refractive index material, the light transmission / reflection characteristics of the dichroic mirror 10, that is, FIG. Thus, the light of the wavelength range absorbed by the fluorescent material FM exhibits approximately 100% transmittance, but the fluorescence emitted by the fluorescent material reflects approximately 100% without disturbing the light transmission / reflection characteristics of the dichroic mirror 10. The dichroic mirror 10 can be stably fixed to the fluorescent light guide plate.

  While the invention has been described in detail with reference to embodiments, it will be apparent to those skilled in the art that various modifications can be made to the embodiments within the scope of the invention.

DESCRIPTION OF SYMBOLS 2 ... Fluorescent light guide plate, 2a ... Sunlight incident surface of fluorescent light guide plate 2, 3a ... Optical fiber, 10 ... Dichroic mirror, 12 ... Low refractive index material layer, FM ... Fluorescent material, SL ... Sunlight, FL ... Fluorescence

Claims (1)

  A fluorescent light guide plate formed of a material in which a fluorescent substance that absorbs sunlight incident from a sunlight incident surface and emits fluorescence in a wavelength band with high sensitivity of the laser medium is dispersed and has a higher refractive index than the outside; In a solar light excitation laser apparatus having a fluorescence / laser conversion means for generating a laser by fluorescence emitted from a fluorescent material and propagated in the fluorescent light guide plate, the fluorescence emitted from the fluorescent material is the sun of the fluorescent light guide plate. A structure that prevents light from leaking out of the fluorescent light guide plate from a light incident surface is provided, and a dichroic mirror that transmits light in a wavelength region that is absorbed by the fluorescent material but reflects fluorescence emitted from the fluorescent material is provided in the fluorescent light guide. A structure characterized in that it is provided facing the sunlight incident surface of the light plate and spaced apart therefrom.

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