WO1992015484A1

WO1992015484A1 - An illuminator, especially a runway approach flashlight

Info

Publication number: WO1992015484A1
Application number: PCT/FI1992/000039
Authority: WO
Inventors: Esko Kasurinen
Original assignee: Idman Oy
Current assignee: Idman Oy
Priority date: 1991-03-07
Filing date: 1992-02-12
Publication date: 1992-09-17
Anticipated expiration: 1993-09-07
Also published as: ATE139193T1; FI911153A7; FI87948B; FI87948C; DE69211541D1; FI911153A0; EP0574425A1; US5373429A; DE69211541T2; EP0574425B1

Abstract

The invention relates to an illuminator, especially a runway approach flashlight, for forming a directable, generally rectangular light beam, comprising a light source, such as a xenon lamp, an illuminator body (1), and a reflector supported to it and comprising a generally cup-like rear reflector (2) fitted behind the light source, and means for directing the light beam. To achieve a light beam of a desired shape and to enable it to be directed, the reflector further comprises an ellipsoidal counter reflector (3) fitted in front of the light source, the main axis of the counter reflector being substantially parallel to the shorter side of the light beam, and the reflector (2, 3) is supported to the illuminator body by means of joints (11), so that the reflector can be tilted with respect to the illuminator body (1).

Description

An illuminator, especially a runway approach flash¬ light

This invention relates to an illuminator, especially a runway approach flashlight, for forming a directable, generally rectangular light beam, com¬ prising a light source, such as a xenon lamp, an illuminator body, and a reflector supported to it and comprising a generally cup-like rear reflector fitted behind the light source.

Finnish Published Specification 66074, for instance, discloses an illuminator of substantially the above-described type for similar purposes. The runway approach flashlight according to the invention should radiate a flashing light so as to form a beam having the shape of a horizontal rectangle in cross- section. This beam has to be directed at a pre¬ determined angle with respect to the horizontal plane. Within the area of the beam, the effective light intensity values have to be adjustable in com¬ pliance with various specifications both as concerns the width of the beam and the maximum/minimum ratio of the intensities. In the above-mentioned known arrangement, the illuminator with its casing has been made tiltable for directing the beam by providing the back portion of the casing with a joint with respect to which the front edge of the casing can be lifted by means of an adjusting screw. This way of adjust¬ ment requires that the electronics controlling the illuminator unit should be placed in a housing separ¬ ate from the illuminator in order that the tiltable structure would not be too heavy and clumsy. On the other hand, the directing of this kind of illumin¬ ator, that is, the adjustment of the angle of tilt, has to be checked at least after the illuminator has been installed e.g. on a light support possibly several metres above the surface of the earth, in this known arrangement, the light beam itself is shaped by an elliptical rear reflector and optical means positioned in front of a light source. The light distribution in the illuminator is fixed and cannot be adjusted in compliance with various speci¬ fications, but possible changes in the distribution of light have to be made by modifying the structure of the illuminator unit itself.

The object of the present invention is to provide an illuminator in which the light beam is more easily and more simply adjustable in both shape and direction than in the illuminators known from the prior art. This is achieved by means of an illumin¬ ator according to the invention, which is character¬ ized in that the reflector further comprises an ellipsoidal counter reflector fitted in front of the light source, the main axis of the counter reflector being substantially parallel to the shorter side of the light beam.

The arrangement of the invention also provides an illuminator in which the illuminator casing need not be tilted for directing the light beam but the light beam is directed by tilting only the reflector and the light source supported to it.

Two prismatic refraction plates of transparent material are supported preferably to the rear re¬ flector, substantially in the plane of its mouth, in such a way that they cover the mouth of the rear re¬ flector with the exception of a substantially centrally positioned area of uniform width. By means of these prismatic refraction plates, both the dimensions and the intensity distribution of the rectangular light beam emitted by the illuminator can be varied. Preferably, the refraction plates are supported to the rear reflector so as to be adjust¬ able. As to the maximum/minimum ratio of the light beam intensities, it is preferable that light can be guided to the corner areas of the primary beam by means of the refraction plates, whereby the refract¬ ing angle of the refraction plates may be about 15° and the directional angle within the range from 2 to 5°. The width of the area of uniform width between the refraction plates also affects substantially the maximum/minimum ratio of the intensities.

Furthermore, it is preferable that the rear reflector is divided into three sections substantial¬ ly parallel with the shorter side of the light beam in such a way that when light beams emitted from the light source and returned from the front reflector are reflected from the two outermost sections, they are directed sidewardly, forming an acute angle with respect to the light beams reflected from the middle section. In this way the light reflected from the rear reflector can be spread outward within its edge areas, and the length of the longer side of the light beam having a rectangular cross-section, that is, the width of the light beam can be adjusted to some extent by the selection of the above-mentioned acute angle. This acute angle is preferably about 6°.

In order to be able to direct the light beam in the illuminator according to the invention with respect to the horizontal plane more simply than pre- viously, the reflector is supported pivotally to the illuminator body. It is also to be preferred that the illuminator body comprises a levelling means which is arranged to indicate the position in which the illuminator body is positioned substantially hori- zontally, and the reflector comprises a scale plate which can be adjusted positionally with respect to the illuminator body and which indicates the angle of tilt of the reflector with respect to the illuminator body. In this way it can be ensured as early as at the assembly stage of the illuminator that the scale plate attached to the illuminator body is in an appropriate position in view of the vertical position of the reflector; at the installation site, the reflector thus only has to be tilted at a desired angle of tilt by means of the marks of the scale plate. Of course, it is thereby assumed that the illuminator body can be positioned on a horizontal supporting surface, which, on the other hand, can also be checked by means of the levelling means provided in the illuminator body.

In the following, the illuminator according to the invention will be described in more detail with reference to the attached drawings, in which

Figure 1 is a front view of an illuminator according to the invention, that is, as viewed in the direction of the light beam;

Figure 2 is a cross-sectional view of the illuminator of Figure 1 substantially at right angles to the light beam, Figure 3 is a front view of a refraction plate contained in the reflector of the illuminator;

Figure 4 is a side view of the refraction plate of Figure 3; and

Figure 5 shows an arrangement comprised in the illuminator according to the invention for adjusting the angle of tilt of the reflector.

The illuminator according to the invention shown in Figure 1 comprises an outermost water-proof casing 7 the front surface of which is transparent and which encloses the reflector means of the illuminator, and, if required, also the electronic means controlling the illuminator. This is possible as the illuminator casing can be positioned steadily on the underlying surface and need not be tilted for directing the light beam. The illuminator itself com¬ prises an illuminator body 1 having a base portion and column-like portions projecting upwardly from the base portion, a reflector and an associated light source being supported on the column-like portions. The reflector comprises a generally cup-like rear reflector 2 which is fitted behind the light source and an ellipsoidal counter reflector 3 fitted in front of the light source. The main axis of the counter reflector is vertical, that is, parallel to the shorter side of the light beam, and the counter reflector further comprises a central opening 8 for allowing the passage of light emitted from the light source straight in the right direction. The rear reflector 2 is formed of a blank having the shape of a paraboloid generated by rotation and divided into three vertical sections 2A, 2B and 2C. The division is carried out in such a way that light beams originating from the light source and reflected from the two outermost sections 2A and 2C are directed sidewardly, thus forming a smallish acute angle with respect to light beams reflected from the middle section 2B. This smallish acute angle may be e.g. about 6°. Furthermore, two prismatic refraction plates 4 of transparent material are supported to the rear reflector 2, substantially in the plane of its mouth, in such a way that they cover the mouth of the rear reflector 2 with the exception of a substantial¬ ly centrally positioned area of uniform width. The width of this area is a and its longitudinal axis is parallel to the longer side of the rectangular light beam of the illuminator. The distance a should be adjustable. By way of example, Figure 1 shows a simple arrangement in which the refraction plates 4 are supported to the rear reflector 2 by means of screws 9 in such a way that the screws penetrate the refraction plates through elliptical openings 10. In this way the distance between the refraction plates 4 can be adjusted sufficiently.

As already mentioned above, the entity formed by the rear reflector, the counter reflector and the refraction plates is supported on the columns of the illuminator body 1 by means of joints 11 provided in the columns, the joints being attached to the rear reflector substantially at the ends of its horizontal axis.

Figures 3 and 4 show the refraction plate 4 in more detail. As appears from the figures, the prisms of the refraction plate have a directional angle which is about 2.5° in Figure 3. This directional angle preferably ranges between about 2 and 5°. In Figure 4, in turn, the angle of refraction of the refraction plates is about 15°. These given angle values are not critical but they can be adjusted to some extent in compliance with the specifications imposed on the light beam of the illuminator in each particular case.

Figure 5 shows an arrangement comprised in the illuminator according to the invention, which enables the angle of tilt of the illuminator to be set in advance before the installation of the illuminator on a light support or other similar supporting surface. The arrangement shown in Figure 5 comprises a levelling means attached to the illuminator body 1, such as a water level 5 which enables the illuminator body 1 to be positioned horizontally. In this posi- tion, the reflector structure, in turn, will be posi¬ tioned vertically, that is, the light beam reflected from it will be horizontal. In this position, a scale plate 6 attached to the reflector is locked in a po- sition 0° by means of screws 12, as shown in Figure 5. Thereafter the light beam of the illuminator can be directed at a desired angle by tilting the re¬ flector so that the scale plate 6 will indicate this desired angle value at the edge of the illuminator body 1. Thereafter the reflector can be locked in this tilted position by means of a screw 13 bearing against the illuminator body 1. In this way the re¬ flector can be tilted reliably in advance at the desired angle of tilt. This arrangement avoids the use of separate, external directing devices difficult in use in the installation of the illuminator. After the installation, the direction can always be checked by means of the water level 5. This is because the water level 5 indicates if the installation surface of the illuminator is horizontal, whereby the angle of tilt of the reflector is the angle indicated by the scale 6. By means of the scale shown in Figure 5, the reflector can be tilted 3 to 10° upward from the vertical plane, that is, the light beam can be lifted through a corresponding angle upward from the horizontal plane.

The illuminator according to the invention, especially a runway approach flashlight, is described above only by means of one exemplifying structural embodiment, and it is to be understood that the principles according to the invention can be realized by means of other similar structural arrangements without, however, deviating from the scope of protec¬ tion defined in the attached claims.

Claims

Claims :

1. An illuminator, especially a runway approach flashlight, for forming a directable, generally rect- angular light beam, comprising a light source, such as a xenon lamp, an illuminator body (1), and a reflector supported to it and comprising a generally cup-like rear reflector (2) fitted behind the light source, c h a r a c t e r i z e d in that the re- flector further comprises an ellipsoidal counter re¬ flector (3) fitted in front of the light source, the main axis of the counter reflector being substantial¬ ly parallel to the shorter side of the light beam.

2. An illuminator according to claim 1, c h a r a c t e r i z e d in that two prismatic refraction plates (4) of transparent material are supported to the rear reflector (2), substantially in the plane of its mouth, in such a way that they cover the mouth of the rear reflector (2) with the excep- tion of a substantially centrally positioned area of uniform width.

3. An illuminator according to claim 2, c h a r a c t e r i z e d in that the refracting angle of the refraction plates (4) is about 15° and their directional angle ranges from about 2° to about 5°.

4. An illuminator according to claim 2 or 3, c h a r a c t e r i z e d in that the refraction plates (4) are supported to the rear reflector (2) so as to be adjustable, enabling the width (a) of said area of uniform width to be varied.

5. An illuminator according to any of claims 1 to 4, c h a r a c t e r i z e d in that the rear reflector (2) is divided into three sections (2A, 2B, 2C) substantially parallel to the shorter side of the light beam in such a way that light beams originating from the light source and reflected from the two outermost sections (2A, 2C) are directed sidewardly, thus forming an acute angle with respect to light beams reflected from the middle section (2B).

6. An illuminator according to claim 5, c h a r a c t e r i z e d in that said acute angle is about 6°.