CA1254417A - Photoradiator - Google Patents

Abstract

ABSTRACT
A photoradiator has a light conducting rod and a casing which surrounds the rod to define an annular space therebetween. Disposed in the annular space are transparent members which are engaged with both the light conducting rod and the casing in order to effectively radiate light, which propagates through the light conducting rod. The transparent members comprise rods arranged parallel to the light conduct-ing rod, rings coaxially surrounding the light conducting rod, a combination of such rods and rings, a pack of small pieces, or bars extending parallel to the light conducting rod and having a generally triangular cross-section. The transparent members are dimensioned and arranged to set up an even distribution of light throughout the length of the light conducting rod.

Description

1~4~7 PHOTORAD IATOR

BACKGROUND OF THE INVENTION
The present invention relates to a photoradiator for diffusing light to the ambience which is introduced thereinto from a light conducting cable or the like.
The photoradiator is usable, for example, as a light source for photosynthetic reactions.
To meet the increasing demand for energy saving today, effective use of solar energy has been studied in various fields actively. For the most effective use of solar energy, it is the primary requisite that the solar energy be used as optical energy without being transformed into another kind of energy such as thermal energy or electrical energy. In light of this, the applicant has proposed in various forms a lighting system iIl which the sunlight converged by lenses or the like is introduced into light conducting cables to propagate therethrough to desired locations.
Light advancing through a light conducting cable has directivity. Hence, concerning the application of the solar energy to lighting as stated above, the angular range available for the radiation of light is usually not larger than about ~6 degrees when the light is discharged from a simply cut end of the light conducting cable. Such a narrow radiation range is ~25 incapable of lighting a room or the like in an even ;luminous intensity distribution. The applicant has made various propositions concerned with a ~hoto-radiator which effectively diffuses light introduced thereinto from a light conducting cable over ~S~a~17' ~ 2 --substantial range and in an even luminous intensity distribution.
Meanwhile, fish farming or like industry requires zooplunkton in order to feed small fish or the like.
Zooplunkton, in turn, propagates with chlorella employed as a feed. What is necessary for effective cultivation of chlorella is the adequate supply of optical energy and carbon dioxide, as well known in the art. A dillematic situation encountered with chlorella cultivation is that as chlorella propagates to a substantial density, it prevents light from reaching distant places with its own shadow and, thereby, fails to be evenly supplied with optical energy. The lighting systems and photoradiators proposed by the applicant are a solution to such a situa-tion.
The present invention constitutes an improvement over the proposed photoradiators.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide a simple photoradiator which allows light propagating through a light conducting cable to be effectively radiated by diffusion in an even intensity distribution.
It is another object oE the present invention to provide a generally improved photoradiator.
According to the present invention there is provided a photoradiator for diffusing light introduced from a light source comprising, in combination:
a cylindrical light conducting member having one end and an other end, said light being introduced into said one end and propagating through the light conducting member;
a casing coaxially and hermetically surrounding said conducting member to define an annular space in B cooperation with the light conducting member, said casing - 3 ~ ~ZS~ o being made of a light transmitting material; and a plurality of transparent members arranged in said annular space to engage with an outer periphery of the light conducting member and an inner periphery of the casing, said t.ransparent members comprising trans-parent rods each of which extends parallel to the light conducting member and has a longitudinal length substantially equal to the longitudinal length of said cylindrical light conducting member;
whereby the light propagating through the photoradiator is discharged radially outwardly from the photoradiator through the transparent members and the casing.
Preferably, the transparent rods have a diameter substantially equal to the radial width of said annular space, said transparent rods being disposed in said annular space such that adjacent rods contact each other.
Preferably, the transparent rods have a refractive index which increases in a direction from the outer periphery of the casing.
According to the present invention, there is also provided a photoradiator for diffusing light intro-duced from a light source comprising, in combination:
a cylindrical light conducting member having one end and an other end and being formed with recesses in the outer periphery thereof, said light being introduced into said one end and propagating through the light conducting member;
a casing coaxially and hermetically surrounding said light conducting member to define an annular space in cooperation with the light conducting member, said casing being made of a light transmitting material; and a plurality of transparent members arranged in said annular space to engage with the outer periphery of the light conducting member and the inner periphery - 3a ~ 1~54~ f' of the casing, said transparent members comprising trans-parent rods each of which extends parallel to the light conducting member and has a longitudinal length substantially equal to the longitudinal length of said cylindrical light conducting member;
whereby the light propagating through the photoradiator is discharged radially outwardly from the photoradiator through the transparent members and the casing.
According to the present invention, there is also provided a photoradiator for diffusing light introduced from a light source comprising, in combination:
a cylindrical light conducting member having ;: one end and an other end, said light being introduced into said one end and propagating through the light conducting member;
a casing coaxially and hermetically surrounding said light conducting member to define an annular space in cooperation with the light conducting member, said casing being made of a light transmitting-material ; and a plurality of transparent members arranged in said annular space to engage with the outer periphery of the light conducting member and the inner periphery of the casing, said transparent members comprising trans-parent rings which coaxially surround the light conductingmember, are arran~ed parallel to each other along the length of the light conducting member and are spaced ~rom each other by distances which sequentially decreases from said one end toward said other end of the light conducting member;
whereby the light propagating through the photoradiator is discharged radially outwardly from -the photoradiator through the transparent members and the casing.

- 3b ~ 5~7 According to the present invention there is also provided a photoradiator for diffus1ng light introduced from a light source comprising, in combination:
a cylindrical light conducting member having one end and an other end, said light being introduced into said end and propagating through the light conducting member;
a casing coaxially and hermetically surrounding said light conducting rnember to define an annular space in cooperation with the light conducting member, said casing being made of a light transmitting material; and a plurality of transparent members arranged in said annular space to engage with the outer periphery of the light conducting member and the inner periphery of the casing, said transparent members comprising a ~` plurality of parallel rods extending parallel to the light conducting member and engaged with the outer periphery of the light conducting member, and a plurality of trans-parent rings each surrounding said transparent rods and being engaged with the rods at an inner periphery of said rings, the casing being engaged with the outer peri-phery of each of the rings at the inner periphery of said casing, the rings being spaced from each other by distances which sequentia}ly decreases from said one end toward said other end of the light conducting member whereby the light propagating through the photoradiator is discharged radially outwardly from the : photoradiator through the transparent members and the casing According to the present invention, there is also provided a photoradiator for idiffusing light intro-duced from a light source cornprising, in combinati.on:
a cylindr.ical light conducting member having one end and an other end, said light being introduced - 3c - 1 ~ S~ f' into said one end and propagating through the light conducting rnember in a direction toward said other end;
a casing coaxially and hermetically surrounding said light conducting member to define an annular space in cooperation with the light conducting member, said casing being made of a ligh~ transmitting material; and a plurality of transparent members arranged in said annular space to engage with the outer periphery of the light conducting member and the inner periphery of the casing, said transparent members comprising a plurality of small transparent -pieces packed in the annular space, the small pieces becoming sequentially smaller in size along the direction of light propagation through the light conducting member;
whereby the light propagating through the photoradiator is discharged radially outwardly from the photoradiator through the transparent pieces and the casing.
According to the present invention, there is also provided a photoradiator for di~fusing light intro-duced from a light source comprising, in combination:
a cylindrical light conducting member having one end and an other end, said light being introduced into said one end and propagating through the light conducting member in a direction toward said other end;
a casing coaxially and hermetically surrounding said light conducting member to define an annular space in cooperation with the light conducting member, said casing being made of a light transmitting material; and a plurality of transparent members arranged in said annular space to engage with the outer periphery of the light conducting mernber and the inner periphery of the casing, said transparent members comprising transparent bars each having a substantially triangular cross section, B

- 3d ~

one side of said triangular cross-section being formed arcuate and engaged with the outer periphery of the light conducting rnember, said arcuate side hav:ing a length which sequentially increases along the d:irection of light propagation through the light conducting member, whereby the light propagating through the photoradiator is discharged radially outwardly from the photoradiator through the transparent members and the caslng.
According to the present invention there is also provided a photoradiator for ~iffusing light introduced from a light source ccmprising , in combination:
a cylindrical light conducting member having one end and an other end, said light being introduced into said one end and propagating through the light conducting member ina direction toward said other end;
a casing coaxially and hermetically surroun~ing said li~ht conducting member to define an annular space in cooperation with the light conducting member, said : 20 casing being made of a light transmitting material; and a plurality of transparent members arranged in said annular space to engage with the outer periphery of the light conducting member and the inner periphery of the casing;
said transparent members comprising transparent bars each having a substantially triangular cross-section, one side of said triangular cross-section being formed arcuate and engaged with the outer periphery of the light conducting member, said arcuate side having a length which sequentially increases along the d.irection of light propagation through the light conducting member, said bars having a ridge formed at the junction of two of the side walls of said triangular cross-section;
said cas.ing being formed with channels in ~ZS~ 7 - 3e -the inner periphery thereof for receiving said ridges of the bars;
whereby the light propagating through the photoradiator is discharged radially outwardly from the photoradiator through the transparent members and the casing.
The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description taken with the accompanying drawing.
BRIEF DESCRIPTION OF THE DRAWING
Figs~ 1-3 are views of prior art photoradiators which the applicant has proposed;
Figs. 4A and 4B are views of a photoradiator embodying the present invention;
Figs. 5A and 5B are views of another embodiment 7 .i ,~b.''.

of the present invention corresponding to Figs. 4A
and 4B respectively;
Figs. 6A and 6B are views of another embodiment of the present invention also corresponding to Figs.
4A and 4~ respectively;
Fig. 7 is a view of another embodiment of the present invention;
Figs. ~A-8D are views of another embodiment of the present invention;
Figs. 9A and 9B are views of a modification to a sheath included in the embodiment of Figs. 8A-8D.

DESCRIPTION OF THE P~EFERRED Er~BODIMENTS
While the photoradiator of the present invention is susceptible of numerous physical embodiments, depending upon the environment and requirements of use, substantial numbers of the herein shown and described embodiments have been made, tested and used, and all have performed in an eminently satisfactory manner.
To facilitate understanding of the present invention, some prior art photoradiators which 'che applicant has proposed will be described with reference to Figs. 1-3.
In Fig. 1I the photoradiator comprises a light conducting me~ber 10 which has a spiral recess or groove 12 formed in the periphery thereof. Light L
introduced into the light conducting member 10 propagates therethrough to be effectively radiated to the ambience reflected by the walls of the spiral groove 12. The radiated light may be used for light-ing purpose by way of example.
The pitch P of the spiral groove 12 may be sequentially reduced along the direction of light propagation through the light conductor 10 in order to discharge the light substantially in an even intensity distribution over the entire length of the light conductor 10. A reflector 14 may be mounted on the light outlet end of the light conductor 10 so as to steer radially outwardly even the light returned by the reflector 14 into the light conductor 10.
A transparent or semitransparent casing or sheath 16 may be employed to hermetically encapsulate the light conductor 10. The sheath 16 will keep the light conductor 10 from contamination or damage while pre-venting one from being hurt by the sharp edges of the spiral groove 12. Especially, where the photoradiator is used under water as a light source for the cultiva-tion of chlorella, for example, the sheath 16 will allow no fur to gather on the surface of the light conductor 10 thereby maintaining it clean all the time.
Another advantage attainable with the sheath 16 is that the air layer between the light conductor 10 and the sheath 16 allows the light to be scattered into the water over a desired range and in a desired direction.
Should the sheath 16 be absent, the light would be radiated in quite a limited range from the end portion of the light conductor 10.
The photoradiators shown in Figs. 2 and 3 are essentially similar in function to the photoradiator described above with reference to Fig. 1. In these drawing, structural elements common or similar to those of Fig. 1 are designated by the same reference numerals. In Fig. 2, the cylindrical light conductor 10 is formed with a plurality of spiral grooves in the peripheral surface thereof, grooves 161-166 in the illustrated example. In Fig. 3, the cylindrical light conductor 10 is formed with a plurality of annular grooves 161-16n at spaced locations along the length thereof. The sheath 16 shown in Fig. 1 125~7 may be employed with the photoradiator of Fig. 2 or 3, if desired. Again, the pitch of the spiral grooves 161-16n or the depth of the annular grooves 161-16n may be se~uentially increased along the length of the light conductor 10 in order to set up an even distribution of lightO
Referring to Figs. 4A and 4B, a photoradiator embodying the present invention is shown and includes a cylindrical light conducting member 40. A light conducting cable 42 extending from a light source (not shown) is connected to one end of the light conductor 40. A transparent or semitransparent casing or sheath 44 coaxially and hermetically surrounds the light conductor 40 in such a manner as to define an annular spacing therebetween. Arranged in this annular space are a plurality of transparent elongate members, or rods, 46 which are parallel to the light conductor 40 and engaged with the outer periphery of light conductor 40 and the inner periphery of the sheath 44. Although not shown for the simplicity of illustration, the light conductor 40 is formed with a recess or recesses as described in conjunction with the prior art photo-radiators.
In the construction shown in Figs. 4A and 4B, light introduced from the cable 42 into the light conductor 40 emanates therefrom in the previously described manner and then directed to the outside through the transparent rods 46. It will be understood that the light appears in vertical lines which corre-spond in number to the transparent rods 46.
Referring to Fi~s. 5A and 5B, another embodimentof the present invention is shown. In these drawing, the same structural elements as those shown in Figs.
4A and 4B are designated by like reference numerals.
As shown, the photoradiator comprises a plurality of ~5~ 7 annular transparent members, or rings, 48 which are stacked one upon another in the annular spacing between the light conductor 40 and the sheath 44.
Each of the transparent rings 48 is engaged with the outer periphery of the light conductor 40 and the inner periphery of the sheath 44. In this construction, light will be emitted as horizontal lines which are identical in number with the transparent rings 48.
The photoradiator construction of Figs. 4A and 4B and that of Figs. 5A and 5B may be combined as illustrated in Figs. 6A and 6B. In Figs. 6A and 6B, structural elements common or similar to those of Figs. 4A and 4B and 5A and 5B are designated by like reference numerals. The transparent rods 46 are arranged around and in contact with the light conductor 40, and the transparent rings 48 around the rods 46 in contact with the rods 46 and sheath 44. In this combined photoradiator configuration, light will emanate in the form of spots the number of which is equal to the number of the intersecting points of the rods 45 and rings 48.
The grooved configuration of the light conductor 40 shown and described is not essential in accordance with the present invention. Where use is made of a light conductor without a groove and the transparent rods and/or rings are arranged therearound, the spacing between adjacent rings may be sequentially decreased along the direction of light propagation to substantially evenly discharge the light from the 3~ respective rings.
In any of the foregoing embodiments, the refrac-tive index may be sequentially increased from the light conductor 40 toward the sheath 44 so as to more effectively steer the light from the light conductor 40 to the outside of the sheath 44. For ~LZ~17 additionally effective conduction of the light to the outside of the sheath 44, the refractive indexes and diameters of the transparent rods 46 and rings 48 may be selected such that the light incident on the rods 46 or the rings 48 are focused to the inlet/outlets of the rods 46 or rings 48.
While the rods 46 and rings 48 have been shown and described as having circular cross sections, such is only illustrative and they may be provided with triangular or arcuate cross-sections instead. The mirror 50 at the end of the light conductor 40 is not always necessary; where it is absent, the light pro-pagating through the light conductor 40 will be discharged also from the end of the light conductor 40. It should be noted that to set up an even distribution of light over the entire length of the light conductor 40 under the presence of the mirror 50, the pitch of the grooves or the spacing between the rings has to be calibrated taking into account the component of light which is reflected by the mirror 50 into the light conductor 40.
Referring to Fig. 7, another embodiment of the photoradiator in accordance with the present invention is shown. In Fig. 7, structural elements common or similar to those of the foregoing embodiments are designated by like reference numerals and description thereof will be omitted for simplicity. The photo-radiator in accordance with this embodiment comprises a number of small transparent pieces 70 which are confined in the annular space defined between the light conductor 40 and the sheath 44. Each of the transparent pieces 70 may have a spherical shape.
The mass of the transparent pieces 70 are retained in the sheath 44 by a closure member 72 in contact with the outer periphery of the light conductor 40 ~S4 ~L7 and the inner periphery of the sheath 44.
In the construction shown in Fig. 7, the light propagating through the light conductor 40 is effec-tively steered by the interengaged portions of the transparent pieces 72 to the outside of the sheath 44~
While the light conductor 40 in Fig. 7 is shown to have spiral grooves 12, such is only illustrative.
Where the light conductor 40 lacks the recessed configuration, the refractive index of the transparent pieces 70 may be selected to be larger than that of the light conductor 40. Concerning the non-recessed light conductor con~iguration, should the transparent pieces 70 have identical diameters, the quantity of light inside the light conductor ~0 would sequentially decrease along the direction of light propagation resulting in uneven lighting. This may be overcome by sequentially reducing the diameter of the trans-parent pieces 70 along the direction of light propagation. Again, the reflector 50 at the end o the light conduc,tor 40 does not constitute any essential part of the present invention, although desirable in the case where the photoradiator is applied to a chlorella cultivating apparatus or the like.
Referring to Figs. 8A-8D, still another embodiment of the present invention is shown, in which the same reference numerals as those shown in Figs. 4A to 7 designate the same structural elements. The light conductor 40 and the transparent or semitransparent sheath 44 define therebetween an annular spacing in which a plurality of transparent elongate members, or bars, 80 are disposed. Each of the bars 80 is positioned parallel to and in contact ~ith the light conductor 40 and provided with a generally triangular ~54~1~

- 1 0~

cross-section. One side of the triangle is formed arcuate to remain in intimate contact with the outer periphery of the light conductor ~0. The top of the sheath 44 is closed by a top plate 82, and the bottom by a bottom plate 84. The top plate 82 carries a mirror 86 therewith and the bottom plate, a mirror 88.
In the photoradiator described abovel light introduced from the light conducting cable 42 into the light conductor 40 is routed through the bars 80 radially outwardly to illuminate the ambience.
It will be noted in Figs. 8A-8D that the mirror 88 carried by the bottom plate 84 may be omitted to allow that part of the light which reaches the end of the light conductor 40 to emanate to the outside thereat.
As shown in Fig. 8C, each of the bars 80 has a generally triangular cross-section which includes an arcuate side a engageable with the light conductor 40 and an apex or ridge _. The side a has a length 1 (Fig. 8D) which progressively increases along the direction of light propagation through the light conductor 40, that is, the bar 80 engages with the light conductor 40 over an area which progressively increases along the direction of light propagation.
In other words, although the luminous flux density in the light conductor 40 sequentially decreases along the direction of light propagation, it is compensated for by the sequentially increasing contact area of the bar 80 with the light conductor 40. This allows the light to be discharged in a substantially even intensity distribution from the apex or ridge _ of the bar 80.
A modification to the sheath 80 of the photo-radiator shown in Figs. 8A-8D is shown in Fiys. 9~ and 9B.
The modi~ied sheath 90 is formed with channels 92 in ~;~S~

the inner periphery thexeGf in order to receive the ridges _ of the bars 80. Assuming that the bars 80 have a common height _ (Fig. 8C) as measured from their arcuate sides a, arranging the bars 80 around the light conductor 40 and then coupling the sheath 90 over the bars 80 will automatically position the bars 80 with accuracy relative to the light conductor 40. Positioned in this manner, the bars 80 may be bonded to the light conductor 40. Thus, the modified sheath configuration shown in Figs. 9A and 9B facili-tates positioning of the bars 80.
In summary, it will be seen that the present invention provides a simple photoradiator which is capable of effectively diffusing light in an even intensity distribution from a light conducting cable.
Various modifications will become possible for those skilled in the art after receiving the teachings of the present disclosure without departing from the scope thereof.

Claims (20)

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows:

1. A photoradiator for diffusing light intro-duced from a light source comprising, in combination:
a cylindrical light conducting member having one end and an other end, said light being introduced into said one end and propagating through the light conducting member;
a casing coaxially and hermetically surrounding said conducting member to define an annular space in cooperation with the light conducting member, said casing being made of a light transmitting material; and a plurality of transparent members arranged in said annular space to engage with an outer periphery of the light conducting member and an inner periphery of the casing, sand transparent members comprising trans-parent rods each of which extends parallel to the light conducting member and has a longitudinal length substantially equal to the longitudinal length of said cylindrical light conducting member;
whereby the light propagating through the photoradiator is discharged radially outwardly from the photoradiator through the transparent members and the casing.

2. A photoradiator according to claim 1, wherein said transparent rods have a diameter substantially equal to the radial width of said annular space, said transparent rods being disposed in said annular space such that adjacent rods contact each other.

3. A photoradiator according to claim 1, wherein said transparent rods have a refractive index which increases in a direction from the outer periphery of the casing.

4. A photoradiator for diffusing light intro-duced from a light source comprising, in combination:
a cylindrical light conducting member having one end and an other end and being formed with recesses in the outer periphery thereof, said light being introduced into said one end and propagating through the light conducting member;
a casing coaxially and hermetically surrounding said light conducting member to define an annular space in cooperation with the light conducting member, said casing being made of a light transmitting material; and a plurality of transparent members arranged in said annular space to engage with the outer periphery of the light conducting member and the inner periphery of the casing, said transparent members comprising transparent rods each of which extends parallel to the light conducting member and has a longitudinal length substantially equal to the longitudinal length of said cylindrical light conducting member;
whereby the light propagating through the photoradiator is discharged radially outwardly from the photoradiator through the transparent members and the casing.

5. A photoradiator according to claim 4, wherein said transparent rods have a refractive index which increases in a direction from the outer periphery of the light conducting member to the inner periphery of the casing.

6. A photoradiator for diffusing light introduced from a light source comprising, in combination:

a cylindrical light conducting member having one end and an other end, said light being introduced into said one end and propagating through the light conducting member;
a casing coaxially and hermetically surrounding said light conducting member to define an annular space in cooperation with the light conducting member, said casing being made of a light transmitting material; and a plurality of transparent members arranged in said annular space to engage with the outer periphery of the light conducting member and the inner periphery of the casing, said transparent members comprising trans-parent rings which coaxially surround the light conducting member, are arranged parallel to each other along the length of the light conducting member and are spaced from each other by distances which sequentially decreases from said one end toward said other end of the light conducting member;
whereby the light propagating through the photoradiator is discharged radially outwardly from the photoradiator through the transparent members and the casing.

7. A photoradiator according to claim 6, wherein said transparent rings have a refractive index which increases in a direction from the outer periphery of the light conducting member to the inner periphery of the casing.

8. A photoradiator according to claim 6, wherein said rings have a circular cross-section with the diameter of said circular cross-section being substan-tially equal to the radial width of said annular space.

9. A photoradiator for diffusing light intro-duced from a light source comprising, in combination:
a cylindrical light conducting member having one end and an other end, said light being introduced into said one end and propagating through the light conducting member;
a casing coaxially and hermetically surrounding said light conducting member to define an annular space in cooperation with the light conducting member, said casing being made of a light transmitting material; and a plurality of transparent members arranged in said annular space to engage with the outer periphery of the light conducting member and the inner periphery of the casing, said transparent members comprising a plurality of transparent rods extending parallel to the light conducting member and engaged with the outer periphery of the light conducting member, and a plurality of transpa-rent rings each surrounding said transparent rods and being engaged with the rods at an inner periphery of said rings, the casing being engaged with the outer periphery of each of the rings at the inner periphery of said casing, the rings being spaced from each other by distances which sequentially decreases from said one end toward said other end of the light conducting member;
whereby the light propagating through the photoradiator is discharged radially outwardly from the photoradiator through the transparent members and the casing.

10. A photoradiator according to claim 9, wherein said transparent members have a refractive index which increases in a direction from the outer periphery of the light conducting member to the inner periphery of the casing.

11. A photoradiator according to claim 9, wherein the rings are spaced from each other by distances which sequentially decrease from said one end toward said other end of the light conducting member.

12. A photoradiator according to claim 9, wherein said rings have a circular cross-sectional configu-ration.

13. A photoradiator for diffusing light intro-duced from a light source comprising, in combination:
a cylindrical light conducting member having one end and an other end, said light being introduced into said one end and propagating through the light conducting member in a direction toward said other end;
a casing coaxially and hermetically surrounding said light conducting member to define an annular space in cooperation with the light conducting member, said casing being made of a light transmitting material; and a plurality of transparent members arranged in said annular space to engage with the outer periphery of the light conducting member and the inner periphery of the casing, said transparent members comprising a plurality of small transparent pieces packed in the annular space, the small pieces becoming sequentially smaller in size along the direction of light propagation through the light conducting member;
whereby the light propagating through the photoradiator is discharged radially outwardly from the photoradiator through the transparent pieces and the casing.

14. A photoradiator according to claim 13, wherein said transparent members have a refractive index which is larger than the refractive index of said light conducting member.

15. A photoradiator according to claim 13, wherein said small transparent pieces have a spherical shape.

16. A photoradiator according to claim 13, wherein said small transparent pieces are disposed such that adjacent pieces are in contact with each other.

17. A photoradiator for diffusing light intro-duced from a light source comprising, in combination:
a cylindrical light conducting member having one end and an other end, said light being introduced into said one end and propagating through the light conducting member in a direction toward said other end;
a casing coaxially and hermetically surrounding said light conducting member to define an annular space in cooperation with the light conducting member, said casing being made of a light transmitting material; and a plurality of transparent members arranged in said annular space to engage with the outer periphery of the light conducting member and the inner periphery of the casing, said transparent members comprising trans-parent bars each having a substantially triangular cross-section, one side of said triangular cross-section being formed arcuate and engaged with the outer periphery of the light conducting member, said arcuate side having a length which sequentially increases along the direction of light propagation through the light conducting member, whereby the light propagating through the photoradiator is discharged radially outwardly from the photoradiator through the transparent members and the casing.

18. A photoradiator according to claim 17, wherein the height of said transparent members, considered along a radial line, is constant along the longitudinal length of said transparent members.

19. A photoradiator according to claim 17, wherein said transparent members have two converging sides extending from the ends of said one side, said two sides converging to join one another at a longitudinal extending ridge, and a plurality of longitudinal spaced channels in the inner periphery of said casing for receiving said ridges.

20. A photoradiator for diffusing light introduced from a light source comprising, in combination:
a cylindrical light conducting member having one end and an other end, said light being introduced into said one end and propagating through the light conducting member in a direction toward said other end;
a casing coaxially and hermetically surrounding said light conducting member to define an annular space in cooperation with the light conducting member, said casing being made of a light transmitting material; and a plurality of transparent members arranged in said annular space to engage with the outer periphery of the light conducting member and the inner periphery of the casing;
said transparent members comprising transparent bars each having a substantially triangular cross-section, one side of said triangular cross-section being formed arcuate and engaged with the outer periphery of the light conducting member, said arcuate side having a length which sequentially increases along the direction of light propagation through the light conducting member, said bars having a ridge formed at the junction of two of the side walls of said triangular cross-section;
said casing being formed with channels in the inner periphery thereof for receiving said ridges of the bars;
whereby the light propagating through the photoradiator is discharged radially outwardly from the photoradiator through the transparent members and the casing.