HU201439B - Light source constructed from gas discharge tubes - Google Patents

Abstract

A light source composed of gas-discharge tubes and having a surface which reflects the light from these gas-discharge tubes consists of three closely mounted gas-discharge tubes of various colours (1R, 1G, 1B), preferably red, green and blue, whose length is not more than ten times their width. The gas-discharge tubes (1R, 1G, 1B) are surrounded by a common envelope (3) having a reflecting surface on its internal face, and each tube can be connected to a separate light intensity regulator. In one embodiment, the three gas-discharge tubes (1R, 1G, 1B) are arranged along the edges of a regular or approximately regular three-sided pyramid.

Description

BACKGROUND OF THE INVENTION The present invention relates to a light source constructed of gas discharge tubes which can be used both for general lighting purposes and as a lighting element for light information equipment.

Phase-cut control circuits which vary the average power per lamp are already widely used to continuously regulate the luminous intensity of incandescent lamps. Due to the thermal inertia of the incandescent lamp, the luminous intensity follows such a control only relatively slowly and therefore cannot be used to display moving images or very rapidly changing images on display panels. Impulse stress necessarily reduces the life of the filament.

Various embodiments of light-signaling devices with incandescent lamps are known, including, but not limited to, U.S. Patent Nos. 176,634, 177,273, 177,276 and 177,921.

It is known that gas discharge tubes, including fluorescent tubes, have very favorable luminous efficiency, but solutions for controlling their luminous intensity have not yet been found. The control of the luminous intensity of gas discharge tubes can be achieved by varying the ratio of the time of ignition to the total time when the tubes are continuously heated. This requires periodically applying a voltage sufficient to maintain the ignited state between the electrodes of the tube, which decreases to zero at each end of the period, and within each period a pulse of sufficient magnitude to ignite is superimposed on that voltage within each period.

If the brightness control of a gas discharge tube is considered to be solved, or at least can be achieved, there is a need to create more complex light sources containing such tubes.

In many light sources containing gas discharge tubes, especially fluorescent lamps, the oblong shape of the fluorescent lamp and its cylindrical symmetrical light result in relatively unfavorable light utilization. In conventional ceiling fixtures, for example, the upward light emitted by the horizontal tube is reflected by the painted base of the fixture only at a loss, and the reflection itself is inhibited by the body of the fluorescent lamp.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a light source constructed of gas discharge tubes that utilizes the benefits of the adjustable luminous intensity of the tubes, and also provides a light source that is useful as a base element for display panels.

The present invention therefore relates to a light source constructed of gas discharge tubes having a light reflecting surface of gas discharge tubes comprising three differently colored gas discharge tubes of different colors, preferably red, green and blue, having a longitudinal extension of at least twice their width and up to ten times their length. , the gas discharge tubes are surrounded by a common sidewall with a reflective surface and can be connected to a single brightness control unit. The pipes are of the same design and separate.

It is advantageous for the optical characteristics that the gas discharge tubes are formed in U-shape with two tubes arranged side by side and one cross member bridging them at their ends (opposite to the socket 2).

A favorable spatial color mixing and luminous efficiency is obtained when the three gas discharge tubes are arranged along the edges of the triangular pyramid and the planes defined by the double axes of the U-shapes are in the plane of the pyramid or perpendicular thereto.

Spatial color mixing is facilitated if the reflector housing has a cone-shaped sidewall with a cone angle of 90 ° or less.

In another embodiment, the gas discharge tubes are arranged in a star or delta configuration with a parallel axis.

For uniform beam distribution and proper orientation, it is advantageous to have a side-deflection section parallel to the optical axis and having a reflective (reflective) inner surface attached to the side opening mouth.

In the case of close use of the light source, it is advantageous to have a light distribution plate at or near the mouth opening.

When creating a light bulletin board, the resolution of the resolution can be increased by reducing the surface of the light source. This is most conveniently accomplished by having the side wall of the reflector housing consisting of a truncated cone surface and a rectangular beam deflecting section connected thereto, the gas discharge tubes passing through the apertures formed on the surface of the truncated cone.

In order to eliminate glare from sunlight, it is advantageous to have at the end of the deflector section a grid having shielding plates parallel to the optical axis and having a mirrored surface visible from the light source observation point, preferably opposed to a matte black surface.

In the case of light sources used for high-pitched boards, it is advantageous to be fixed in a position with an optical axis inclined at an angle to the horizontal.

The light source according to the invention will now be described in more detail with reference to the drawings, in which: The drawing shows:

Figure 1 is a plan view of a first embodiment of a light source according to the invention, a

Figure 2 is a longitudinal sectional view of the embodiment of Figure 1, a

Figure 3 is a plan view of another embodiment, a

Figure 4 is a longitudinal sectional view of this embodiment, FIG

Figure 5 is a plan view of a star-shaped tube arrangement, a

Figure 6 is a longitudinal sectional view of the arrangement of Figure 5, a

Figure 7 is a plan view of a delta tube arrangement, a

Figure 8 is a front view of the reflector housing of a further embodiment of the light source of the invention, a

Figure 9 is a side view, partly in section, of the reflector housing of Figure 8, a

FIG. Figs. a schematic sectional view of a light source having the reflector housing shown in Figs

Figure 11 is a side view of the corner portion of the grid 23, and

Figure 12 is a front view of the corner portion of the grid 23.

A first embodiment of a light source according to the invention is shown in Figures 1 and 2. The light source consists of three IR, 1G and IB gas discharge tubes of the same type but of different colors, which are designated as 21

EN 201439 Β are red, green and blue in color, size and performance.

The IR, 1G and 1B gas discharge tubes are preferably U-shaped, having a power of 5-10 W, a longitudinal extension of 170 mm and a width of 32 mm. Examples include the American General Electric F7TT / SPX24 twin tube 7W gas discharge tube, the Dutch Philips company PL 9W gas discharge tube and the TUNGSRAM FD 7W gas discharge tube suitable for this purpose.

The tubes referred to have a two-cathode system and have become known in the art as a "compact fluorescent lamp". The IR, 1G, and 1B gas discharge tubes for use with the light source of the present invention differ from the commercially available designs of the tubes referred to in that their electrodes are terminated through a socket that does not contain an ignition circuit, although the socket The setting of a controlled mode with adjustable brightness and fast pulses is prevented by the ignition circuit mounted in the socket. The manufacturer will also be able to supply compact gas discharge tubes without ignition circuit when properly ordered.

The drawing shows that the axis of the three IR, 1G and 1B gas discharge tubes is aligned with the edges of a regular triangular pyramid. The tubes are housed in a reflector housing 2 with a rotationally symmetrical reflective surface, which has a side surface 3 with a mirror surface. The sidewall 3 expands by a cone angle of about 60 °. The attachment and outlet of the individual gas discharge tubes was solved through the openings formed on the rear surface 4 of the reflector housing 2, this structure being not sketched in order to keep the drawing clear.

It is a primary object of the light source of the present invention to provide a light beam of variable color and luminous intensity that produces a uniform optical impression, thereby being used as a base element for color display panels. To accomplish this goal, appropriate spatial mixing of the light from each of the IR, 1G, and 1B gas discharge tubes is required. The tripartite pyramid arrangement is very advantageous in this respect because the light emitted from any tube towards the inside of the shape passes smoothly through the opening formed between the other two tubes to the inner housing wall which acts as a mirror and is reflected. The conical sidewall 3 reflects light both forward and laterally. When viewed from the front, i.e. from the projection direction of Figure 1, it is seen that light emitted from the inner surface of the gas discharge tube 1G is obliquely rearward and lateral through the apertures formed between the other two gas discharge tubes IR and 1B. One consequence of this is that from the front we see not three, but six fluorescent lamps, where the colors are clockwise R, B *, G, R *, where * denotes the reflected image of the corresponding fluorescent lamp. Due to the double density in the correct order, the entire surface is illuminated and the light mixing is improved. If we look at the structure from an average observation distance, we get a uniform optical impression. Optical mixing is facilitated if the back surface 4 is also concave.

A further important advantage of the pyramidal arrangement is the utilization of the entire radiating surface of each of the three tubes (i.e., both the outer and inner peripheral surfaces), thereby providing a high luminous flux through the mouth of the reflector housing 2.

Of course, the three IR, 1B and 1G gas discharge tubes can be arranged not only as illustrated in Figure 1, but also rotated 90 °. The plane connecting the axes of the twin pipes is then not perpendicular to the opposite plane of the sheet but perpendicular to it.

In the embodiment shown in Figures 3 and 4, the longitudinal axis of the three gas discharge tubes is parallel to the optical axis of the reflector housing 2 and the tubes are in the shape of a star. The sidewall 3 expands at a cone angle of about 90 ° larger than in the previous embodiment, the rear surface 4 has a smaller diameter, corresponding to the size of the star shape. The height of the sidewall 3 is slightly greater than that of the tubes. In this embodiment, too, it is a condition that the light emitted through the sidewall of the tubes is utilized because the tubes do not (or only barely) cover each other. A disadvantage of this solution, however, is that the diameter of the orifice is significantly larger than the diameter of the circle around the tubes. This solution is advantageous for individual luminaires but not as an element of a display system. Here, the resolution of the image and the point size are inversely proportional, because of the large point size, the resulting formula resolution is not fine enough. By reducing the cone angle and mouth opening, this problem is also reduced. If the mouth opening is greatly reduced, the reflection loss of light emitted from the side edges of the tubes will be very high and the luminance measured from the front will be reduced.

In the embodiment shown in Figures 5 and 6, the gas discharge tubes IR, 1G and 1B are again arranged in star shape and have a parallel axis. The sidewall 3 has a curved reflective surface similar to a parabola, the diameter of its orifice being substantially smaller than that of the previous embodiment. Accordingly, the display panel constructed from the structure has a higher resolution. Connected to the sidewall 3 is now a cylindrical section 5 which serves to aid optical mixing of the projected light and to enhance the directing effect.

Figure 7 illustrates the delta configuration of the IR, 1G, and 1B gas discharge tubes. The reflector housing shown in Figures 4 and 6 can also be used with such a tube arrangement. In the delta arrangement, the light emitted from the inner peripheral surface of the tubes is substantially lost as the tubes overlap.

When the device according to the invention is used for individual lighting and its distance from the eye is small, the exit light is more uniformly impressed when the mouth opening is covered with a diffuser light diffuser 6 such as frosted glass or plastic. When using the light distribution board 6, the observer close to the light source also sees a homogeneous solid color surface. The presence of the light distribution plate 6 is a kind of damping, and it should be considered in case of long-distance display panels, since from this point of view the mouth opening is seen as monochrome.

Red, blue, and green gas discharge tubes installed in a common house to control individual luminous intensity3

EN 201439 Β we obtain a light source whose color can be practically varied and the luminous intensity can be freely adjusted within a given range. Controls can have a shorter time constant than eye inertia, and this advantage can also be used to create color image display panels.

It has been mentioned that the primary purpose of such tables is to reduce the surface area of the element corresponding to one pixel, since the fineness of the image resolution is limited by the pixel size. The pixel size is basically determined by the size and type of light source used. When the IR, 1B and 1G gas discharge tubes are made of a particular type of element, such as the compact fluorescent lamps suggested in the examples above, the minimum size is influenced not only by the width of the fluorescent lamps but also by the fact that broadcast. The optical solution used must ensure that the luminous efficacy is effectively exited axially through the front opening of the structure, that the color mix is adequate, and that the adjacent light sources fill the available surface evenly so that no "dark hole" is created in the illuminated surface . This latter condition, for example, is not met by selecting the circular outlet described above. If we further analyze the requirements for information boards, the problem of daytime operation also arises. Obviously, a solution that can be seen in daylight is only possible if the luminous efficacy is sufficiently high. Even with the availability of the required power, there are serious problems with the fact that sunlight is reflected from the surface of the table towards the viewer (at least for most of the daytime period), which dazzles the viewer and makes it impossible to observe the table. For daytime operation, therefore, optical shielding must be provided which protects against direct sunlight and allows light from the light source to pass freely.

8-12. Figures 1 to 5 show a suitable embodiment of the light source according to the invention for such purposes.

Figures 8 and 9 are front and side views of the reflector housing 12, respectively. The reflection body 12 is made, for example, by injection molding of a plastic material, and its inner surface is mirrored with aluminum vapor deposited on aluminum or other suitable metal. The inner sidewall 13 of the reflector housing 12 can be divided into two main parts, i.e., a truncated cone surface 14 and a light guide section 15 connected thereto.

Three openings 16, 17, 18 are formed at the rear of the truncated cone surface at an angle of 120 ° each, the width of which corresponds to the tube diameter of the compact fluorescent lamp of the selected type, slightly larger and the depth of the fluorescent tube. Thus, through the apertures 16, 17, 18 in the shape of a star, the three gas discharge tubes IR, 1B and 1G can be introduced. Figure 10 shows that the bottom of the gas discharge tube 1B reaches the bottom of the frustoconical surface 14 and that most of its illuminating surface is within the reflector housing 12. In Fig. 10, for the sake of illustration, the other two fluorescent lamps are not sketched, they are arranged through the other two apertures in the same way. The longitudinal axes of the fluorescent tubes have an acute angle with the axis 4 of the surface of the truncated cone 14, so that the axis of the three fluorescent tubes forms the edges of a triangular pyramid. In this respect, the arrangement corresponds to that shown in Figures 1 and 2, except that the three gas discharge tubes IR, 1B and 1G assume a 90 ° rotation. The utilization and mixing of the light emitted from the fluorescent lamps in the lateral direction is as favorable as in the case illustrated in Figures 1 and 2.

The front part of the reflector housing 12 is a square-shaped block whose corners are rounded, the rounded parts forming sections of a common cylindrical surface. The lines of penetration at the connection between the cone and the square block and the cylinder surface are shown in Figs.

10. The light deflecting section 15 is thus formed by the square-shaped column surface 19 and the cylinder surface portions 20 formed at the corners. The front cross member of the three IR, 1B and 1G gas discharge tubes is located just before the mouth opening of the truncated cone surface 14 at the rear of the baffle section 15. The dimensions were chosen so that the majority of the light emitted laterally from the compact fluorescent lamps falls on the cone surface, from where it bounces in the direction of the reflector housing 12.

An advantage of the arrangement chosen is, inter alia, that the width of the column surface 19 is slightly larger than that required for the placement of compact fluorescent lamps. Figure 10 shows a distance of less than 2 mm between the outer edge of the socket 21 of the gas discharge tube 1B and the wall extending along the block surface 19. Despite its small size, the laterally radiated light output is projected forward by the reflective interior surface of the reflector housing 12, so that a uniform, high intensity light is emitted through the mouth of the light source, whereby color mixing is advantageous.

By choosing a square column, the same light source can be placed directly next to each other and their light fills the available surface virtually without loss.

8-12. In addition to the above properties, the structural arrangement illustrated in Figures 1 to 4 also provides protection against the dazzling effect of sunlight. In front of the reflector housing 12 is a grid 23 containing shielding plates 22 having a surface parallel to the optical axis. A corner portion of the grid 23 is shown in Figures 11 and 12. The shielding plates 22 of the grid 23 are parallel to the lower and upper edges 24 and 25 of the reflector housing 12. The lower surfaces 26 of the shielding plates 22 have a reflective reflective coating, whereas the upper surface 27, along with all other surfaces of the grid 23, is matte black.

Information boards constructed of light sources according to the invention are usually placed on top of buildings at a height of 10-30 m. The viewer is therefore looking at the table from an angle of 15 ° to 35 ° to the horizontal. For optimum luminous efficacy and optimum shading, it is preferable that the light source 28 has an optical axis of about 28 degrees. It is inclined at an angle of 15 °. This oblique position is achieved by providing mounting surfaces at an obliquely inclined plane with respect to the optical axis 28 on the outside of the reflector housing 12. In the embodiment illustrated in Fig. 10, outside the truncated cone surface 14, there are blocking protrusions protruding from the plastic body forming the reflector housing 12, and

EN 201439 közül of these, Fig. 10 shows the fixing piece 29. The surface of the anchors defines the plane of attachment, which is vertical in the example.

Fig. 10 is a cross-sectional view of the retaining plate 30 secured to bolts 29 by screws. The truncated conical end of the reflector housing 12 behind the support plate 30 is surrounded by a central opening formed on the support plate 30, which also allows unhindered mounting and removal.

The light source according to the invention thus occupies the slightly inclined position illustrated in Figure 10. Figure 10 shows that the sun rays coming from the direction of the arrow 31 are absorbed by the black surfaces of the shielding plates 22 or reflected in an oblique upward direction which lies outside the potential field of view. The main field of view of the board is the space angle represented by the double arrows 32 and from this direction the light of the light source can be seen directly or by reflection from the mirrored lower surfaces 26 of the shielding plates 22.

Claims (13)

PATENT CLAIMS A gas-discharge tube light source having a light-reflecting surface for gas discharge tubes, characterized in that they comprise, in close proximity to each other, separate gas discharge tubes (IR, 1G, 1B) of different colors, preferably red, green and blue. having a longitudinal extension of not less than twice their width and not more than ten times their circumference, the gas discharge tubes (IR, 1G, 1B) are surrounded by a common sidewall (3) having a reflecting surface and can be connected to an individual brightness control unit. (Priority: 6/6/1988) Light source according to claim 1, characterized in that it has gas discharge tubes (IR, 1G, 1B) consisting of two tubes arranged side by side in a U-shape and a cross member bridging the ends opposite to the housing. (Priority: 6/6/1988) Light source according to claim 2, characterized in that the three gas discharge tubes (IR, 1G, 1B) are arranged along the edges of the tripartite pyramid. (Priority: 6/6/1988) Light source according to claim 3, characterized in that the plane defined by the axes of the double tube lies in the plane of the pyramid. (Priority: 6/6/1988) Light source according to Claim 3, characterized in that the plane defined by the axes of the double tube lies in a plane perpendicular to the plane of the pyramid. (Priority: May 15, 1990) 6. A light source according to any one of claims 1 to 3, characterized in that the gas discharge tubes (IR, 1G, 1B) are surrounded by a reflector housing (2) and have a side surface (3) with a cup surface which has a cone angle of less than 90 °. (Priority: 6/6/1988) Light source according to claim 2, characterized in that the gas discharge tubes (IR, 1G, 1B) are arranged in a star shape with a parallel axis. (Priority: 6/6/1988) The light source according to claim 2, characterized in that the gas discharge tubes (IR, 1G, 1B) are arranged in a delta shape with a parallel axis. (Priority: 6/6/1988) 9. A light source according to any one of claims 1 to 3, characterized in that a light deflecting section having a reflective inner surface parallel to the optical axis is connected to the mouth opening of the sidewall (3). (Priority: 6/6/1988) 10. Light source according to one of claims 1 to 3, characterized in that a light distribution plate (6) is formed at or near the mouth opening. (Priority: 6/6/1988) The light source according to claim 2 or 3 or 5, characterized in that the reflector housing (12) surrounding the gas discharge tubes (IR, 1G, 1B) has a side wall (13) of a truncated conical surface (14) and a rectangular column connected thereto. consisting of a deflector section (15), the gas discharge tubes (IR, 1G, 1B) are guided through openings (16, 17, 18) on the truncated cone surface (14). (Priority: May 15, 1990) 12. Light source according to claim 11, characterized in that a grid (23) is connected to the end of the light deflecting section (15), which has shielding plates (22) parallel to the optical axis (28). it has a mirrored surface that is visible from where it is observed, and its opposed surface is preferably matte black. (Priority: May 15, 1990) The light source according to claim 12, characterized in that it is fixed in a position with an optical axis (28) inclined downwardly with respect to the horizontal.