SE503970C2 - Device for generating light in an optical light guide - Google Patents

Abstract

A device for generating light in an optical light guide, wherein the device includes an optical coupling between a light source (5) and a light guide (2), wherein the light source is adapted to transmit visible light or visible and ultra-violet light, wherein the light-generating element is enclosed in a glass bubble (9), wherein the light-generating element is a light arc or an electric filament, and wherein the glass bubble has a radius which corresponds generally to the length of the light-generating element. The invention is characterized by the combination that the cross-sectional dimension of the inlet orifice (8) of the light guide (2) has respectively a length and a width which corresponds generally to or is generally greater than the respective length and width of the light-generating element of the light source (5) in the same plane as the length and width respectively of the light-generating element, and the distance between the outer surface of the glass bubble (9) and the inlet orifice (8) of the light-guide (2) is shorter than the length of the light-generating element.

Description

15 20 25 30 35 503 970 2 intended for use in curing plastic dental materials. This lamp includes a light source in the form of a discharge lamp. After the discharge lamp, there is a filter in the beam path and at a distance from this the input opening of a light guide. Although light is of course input, most of the generated light will not be input in the light guide due to the relatively large distance between the arc and said input end. Therefore, the need for cooling also becomes large, which is the reason for extensive cooling fins on the house that surrounds the light source. The present invention thus relates to a device for generating light in an optical light guide, which device comprises an optical coupling between a light source and a light guide, which light source is arranged to emit visible and ultraviolet light, the light generating element being enclosed in a light source. glass bubble, which light-generating element is an arc, where the glass bubble has a radius substantially corresponding to the length of the light-generating element and is characterized by the combination of the cross-sectional dimension of the light guide input opening having a length and a width substantially corresponding to or exceeding width in the same plane as the length and width of said light generating element, that the distance between the outer wall of said glass bubble and the input opening of the light guide is less than the length of the light generating element, that the light source is a discharge lamp with an electrode distance of less than 4 millimeters. preferably 3 millimeters, that a reflector in the form of a reflecting layer is provided applied to said glass bubble on the opposite side of the light guide, which layer is arranged to substantially reflect light of wavelengths desired in the light guide into the light guide via the glass bubble and to transmit light of the light guide not desired wavelengths.

The invention is described in more detail below, partly in connection with exemplary embodiments of the invention shown in the accompanying drawings, in which - figure 1 schematically shows a light source and a light guide 10 according to a first embodiment of the invention - figure 2 shows a part of the one shown in figure 1, seen from above - figure 3 shows a second embodiment of the invention seen in a view corresponding to that shown in figure 2.

Figure 1 schematically shows a device for generating light in an optical light guide according to the present invention, which comprises an optical coupling between a light source 5 and a light guide 2. Figure 1 shows a light source 5 unmounted, i.e. what is shown is the light source 5 and its base 1. The light source is of the halogen type or discharge type. Figure 1 illustrates the light source with a discharge lamp in which there is a glass bubble 9 between the two electrodes 6,7, which encloses the tips of the electrodes. The glass bubble has a radius that substantially corresponds to the length of the light-generating element.

The light-emitting element in a discharge lamp is an arc and in a halogen lamp it is a filament. A discharge lamp is arranged to emit both visible and ultraviolet light, while a halogen lamp essentially emits only visible light.

The characteristic according to the invention is the combination of the cross-sectional dimension of the input opening 8 of the light guide 2 having a length and a width which substantially corresponds to or exceeds the length and width of the light source 5 in the same plane as the length and width of the light-emitting element and the distance between 9 outer wall and the input opening 8 of the light guide 2 is less than the length of the light-generating element. In figure 1, the inlet opening 8 abuts against the outer wall of the glass bubble, which is the best design.

With the embodiment indicated above, i.e. that the light from the light source is fed directly into the light guide without the use of reflectors or lenses has surprisingly been found to result in significantly more light being fed than with known devices. Thus, the efficiency between light emitted by the light source and light input into the light guide has been able to be significantly increased. This is due to the fact that it has been possible to use a discharge-type lamp with a very short electrode distance as a light source. Such lamps have only been developed recently and especially for the automotive industry. Such lamps have an electrode distance of only about 3 millimeters. Thus, the electrode distance is of the same order of magnitude as the diameter of light guides suitable for the purpose. The outer diameter of the glass bubble of such a lamp is about 6-7 millimeters.

According to a preferred embodiment of the invention, the light source consists of a discharge lamp with an electrode distance of less than 4 millimeters, preferably 3 millimeters.

Thus, if a light guide with a diameter of, for example, 3 - 4 millimeters is used at the same time as the light opening of the light guide is placed near the glass bubble, so much light will be input that, as stated above, the efficiency will be significantly higher than that of the prior art. together with discharge lamps with larger, conventional, electrode distances.

According to a second embodiment of the invention, which is illustrated in Figure 3, the above-mentioned light guide comprises two or more separate light guides 10, 1, 12. Together, these have a cross-sectional dimension which has a length and a width, respectively, which substantially correspond to or exceed the length and width of the light-generating element of the light source in the same plane as the said length and width of the light-generating element, respectively. Each of the respective inlet openings of the light guides 10, 11, 12 is located next to each other and tangentially relative to the outer surface of said glass bubble 9. This design allows an additional amount of light to be input into the light guides. These light guides can be connected to a single light guide after a certain length. Figure 3 shows three light guides. However, it is obvious that additional light guides can be arranged around the glass bubble 9.

Light sources of the type mentioned generate a considerable amount of heat.

However, according to a preferred embodiment, said light guide 2 is made of a material which, without special cooling, resists the temperature which the light opening of the light guide 2 assumes. Preferably a quartz material is used.

Normally, light guides have a circular cross section. However, the arc of a discharge lamp is substantially shaped like an ellipsoid with a major axis that is significantly longer than the minor axis. For example, an arc with a length of 3 millimeters can have a maximum width of 1.5 millimeters. For this reason, according to an advantageous embodiment, the light guide or light guides have a cross section which deviates from being circular and which has a larger dimension in the longitudinal direction of the light-generating element than perpendicular thereto. For example, the light guide may have a cross section which, at least at its input end, is correspondingly elliptical in order to thereby capture more light from the light source compared with a light guide with the same surface but with a circular cross section. Such a light guide, the input end of which has an elliptical cross-section, can gradually, along its length, change to have a circular cross-section, so that its output end has a circular cross-section.

In order to further increase said efficiency, according to a preferred embodiment of the invention there is a reflector 13 placed at said glass bubble on the opposite side of the light guide 2, which reflector is arranged to reflect light into the light guide via the glass bubble 5. According to one embodiment the reflector is a separate device located near or in contact with the glass bubble 9.

According to a preferred embodiment, however, there is a reflector 13 in the form of a reflecting layer applied to the outside of said glass bubble 9 on the opposite side of the light guide 2.

In this case, the layer 13 is arranged to reflect light into the light guide 2 via the glass bubble.

According to a further preferred embodiment of the invention, said layer 13 is arranged to substantially reflect light of wavelengths desired in the light guide 2 and to transmit light of wavelengths undesired in the light guide 2. This is achieved by choosing the composition of the layer. In order to obtain high reflection of ultraviolet light and at the same time achieve a high transmission of visible light, the layer 13 can consist of Rhodium. Furthermore, different layers with different composition can be laid on top of each other to together provide a reflective and transmitting layer with desired optical properties. The properties of different compositions are per se known and accessible knowledge, which is why this is not described in more detail here.

According to a highly preferred embodiment of the invention, said layer 13 is arranged to reflect ultraviolet light and to transmit a substantial part of the visible light.

As mentioned above, the light guide 2 located closest to the light source must withstand the temperature that its input end will assume. In this case, quartz is a suitable material.

However, it may be desirable to make most of the light guide in another material, for example a plastic material. For this reason, according to an embodiment, said light guide 2 is connected at its output end 14 to a second light guide 4 in which the light is further transported. This second light guide 4 can also be constituted by a liquid-filled light guide.

In case a filtering of the light emitted from the light source is desired, according to a preferred embodiment one or more filters 3 are present between the first-mentioned light guide 2 and the said second light guide 4. This avoids placing filters between the glass bubble 9 and the first-mentioned light guide 2. input opening 8, which would mean that the distance between the light-generating element and the input opening 8 would increase, with a lower efficiency as a result.

Furthermore, filters do not normally withstand prevailing temperatures near the glass bubble.

According to an alternative embodiment, instead, one or more corresponding filters 15 are located at the light output opening 16 of the last light guide 4 in the beam path, see Figure 2, where such filters 15 are shown in broken lines. Such a filter can be mounted on the tip of the light guide, and can be designed so that it is easy to switch between filters with different properties depending on the current use.

Filters can be used to filter out unwanted parts of the spectrum generated by the light source. The need and choice of filters of course depends on the application. In many applications, so-called UVA radiation and UVB radiation are filtered out. In other cases, a reduction of the heat radiation is desired, whereby a so-called

IR blocking filter is used. In other cases, it is desirable to filter out visible light and retain ultraviolet light.

In such a case, Wood's glass is used. For example, in the application of curing dentifrice material, the filter is designed to substantially transmit light with a wavelength range of 400-480 nanometers. For some dental materials, UVA radiation is used instead.

The present invention thus solves the disadvantages mentioned in the introduction and offers a very compact and simple device with a high efficiency. The invention is suitable for all kinds of purposes, and especially for applications where ultraviolet or blue-violet light is used. An example of such use is for curing plastic materials in dentistry.

A number of embodiments have been mentioned above. However, the invention may be further modified in a manner obvious to those skilled in the art.

The present invention should therefore not be construed as limited to the above embodiments but may be varied within the scope of the appended claims.

Claims (8)

A device for generating light in an optical light guide, which device comprises an optical coupling between a light source (5) and a light guide (2), which light source is arranged to emit visible and ultraviolet light, wherein the light-emitting element is enclosed in a glass bubble (9), which light-emitting element is an arc, wherein the glass bubble has a radius substantially corresponding to the length of the light-emitting element, characterized by the combination of The cross-sectional dimension of the inlet opening (8) has a length and a width, respectively, which substantially corresponds to or exceeds the length and width of the light-emitting element of the light source (5) in the same plane as the length and width of said light-generating element, respectively. ) outer wall and the input opening (8) of the light guide (2) is less than the length of the light-generating element, that the light source (5) is constituted by a discharge lamp with an electrode distance of less than 4 millimeters, preferably 3 millimeters, that a reflector (13) in the form of a reflecting layer is present applied to said glass bubble (9) on the opposite side of the light guide (2; 10, 11, 12), which layer is arranged to substantially reflect light of wavelengths desired in the light guide (2; 10, 11,12) into the light guide via the glass bubble and to transmit light of wavelengths not desired in the light guide. Device according to claim 1, characterized in that said light guide (2) comprises two or more separate light guides (10,11,12) which together in cross-sectional dimension have a length and a width, respectively, which substantially corresponds to or exceeds the light emitting of the light source (5). length and width of elements in the same plane as the length and width of said light-generating elements, respectively, in that each of the input openings of the light guides (10, 11, 12) is located next to each other and tangentially relative to the outer surface of said glass bubble (9). Device according to claim 1 or 2, characterized in that the light guide (2) or the light guides (10, 1, 12) have a cross section which deviates from being circular and which has a larger dimension in the longitudinal direction of the light-generating element than perpendicular to it. Device according to claim 1, 2 or 3, characterized in that said light guides (2; 10,11,12) are made of a material which without special cooling withstands the temperature which the light opening of the light guide assumes, preferably a quartz material. Device according to claim 1, 2, 3 or 4, characterized in that said layer (13) is arranged to reflect ultraviolet light and to transmit a substantial part of the visible light. Device according to any one of the preceding claims, characterized in that the output end (14) is connected to a second light guide (4) a v, that said light guide (2; 10,11,12) in which the light is further transported. Device according to claim 6, characterized in that one or more filters (3) are present between the first-mentioned light guide (2; 10,11,12) and the said second light guide (4). Device according to one of Claims 1 to 7, characterized in that one or more filters (15) are located at the light output opening (16) of the last light guide (4) in the beam path.