DE2546191C3 - Lighting device - Google Patents

Description

The invention relates to a lighting device with an elongated, box-shaped housing, a Cooling device on the rear wall of the housing, a trough-shaped reflector with an exhaust air opening in its area facing the rear wall of the housing and a tube arranged in the longitudinal direction of the housing shaped, elongated discharge lamp, with a power consumption of more than 90 watts per cm of arc length.

Tubular, elongated high-pressure lamps that are used as powerful light sources such as Light sources are used for Diazo wet copiers have been used in many fields so far, because of its broad spectral range, which goes from the ultraviolet to the visible range, have numerous advantages. Accordingly, attempts have been made to use high pressure mercury vapor lamps as typical artificial light source to be used in manufacturing processes or to prevent contamination.

However, such a light source is not used as it is but inserted into a lamp housing. In the case of a lighting device with a powerful light source, the interior of the lighting device is located Little space is available because it contains a cooling fan, a reflector, a shutter and others necessary parts are housed. In addition, smaller lighting fixtures will be more powerful Light source is required and the manufacturing process is desired for industrial use to speed up deployable items. For example, a smaller lighting device is for Drying UV-cured printing ink has been developed using a powerful light source shall be.

So far it has not yet succeeded for various reasons, a cheaper lighting device for Drying UV-cured printing ink to create. It has been found that in a lighting device with a tubular, elongated light source

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(κι with high power consumption, in particular with a tubular, elongated high-pressure mercury vapor lamp, which is under high heat load and which has an electrical power consumption of more than 90 watts per cm of arc length, the temperature distribution on the glass body wall is very uneven and that there is a risk that the Vitreous wall breaks at certain points due to high thermal stress

From the German utility model 73 18 SIl is already a lighting device of the type mentioned has become known in which the Housing rear wall facing area of the reflector one or more exhaust air openings are provided, behind each of which fans are provided to increase the air throughput. Still are on Heat exchange devices are provided on the side of the reflector facing away from the discharge lamp, through the z. B. industrial water can be directed. This known lighting device turned out however, it also has the disadvantage that it is relatively large over the circumference of the discharge lamp Result in temperature differences.

A lighting device has already become known from the German utility model 70 28 296, b.ei which has a tubular discharge lamp surrounded by an approximately parabolic reflector which is covered on its open side by a transparent cover. With this well-known Arrangement is the distance between the inside of the reflector and the one facing the reflector Outside of the discharge lamp is minimally equal to the radius of the discharge lamp. Special precautions however, there is no provision for cooling the discharge lamp.

The present invention is based on the object of providing a lighting device of the initially mentioned type mentioned to create in the case of the outside of the Charging lamp can be evenly cooled.

This object is achieved according to the invention on the basis of a lighting device of the type mentioned at the beginning solved in that the exhaust air opening is designed in the form of a slot, and that the Distance between the Fndc of the slot facing the discharge lamp and the discharge lamp is a maximum of one third of the outer diameter of the discharge lamp.

Such a lighting device has the advantage that essentially local stresses avoided in the glass body wall of the discharge lamp even when emitting high intensities can be. In particular, a small lighting device and in particular a lighting device with a mercury vapor discharge lamp be created that have an electrical input power of more than 90 watts per cm of arc length can absorb, and can serve, for example, for drying UV-cured printing ink. The smaller ones Dimensions of the lighting device are possible because the sections of the glass body wall on the with respect to the cooling flow upstream and downstream side evenly and effectively can be cooled even if the light source is strongly cooled from one direction, This prevents the I.ichtabgabe due to excessive cooling of the vitreous wall on the is reduced with respect to the cooling flow upstream side, and that local damage occurs the side located downstream with respect to the cooling flow

the vitreous wall occur.

In the following, the invention will be described in more detail with reference to preferred exemplary embodiments shown in the drawing explained. In the drawing shows

F i g. 1 is a front view of a conventional one Lighting device,

F i g. 2 shows a section according to H-II in FIG. 1,

F i g. 3 a schematic representation of the cooling flow in the conventional lighting device,

F i g. 4 shows the temperature distribution on the glass body wall of a light source in the conventional one Lighting device,

5 shows a section through a first embodiment a lighting device designed according to the invention, wherein the cutting line F i g. 2 is equivalent to,

6 shows a schematic representation of the cooling flow in the in F i g. 5 shown lighting device,

7 shows a diagram which shows the temperature of a section of the glass body wall with respect to the KühisiruiiiS SifüiViäb gclcgccii as a function of the ratio of the distance (t) of the discharge lamp from the end of the slot of the exhaust air opening facing the discharge lamp and the diameter (R) of the discharge lamp,

F i g. 8 shows the temperature distribution on the glass body wall of a light source according to FIG Invention trained lighting device,

9 shows a sectional view of a second embodiment a lighting device according to the invention, wherein the cutting line F i g. 2 corresponds and

10 is a perspective view showing the reflector and the air duct of the lighting device according to FIG. 8 shows.

1 and 2, a conventional lighting device is shown. Such a lighting device normally comprises a housing 1, a fan 4 on the rear wall of the housing Ii, a wamien-shaped reflector which is divided into two segments 2a and 2b , and a light source 3 carried by sockets Sa and 85 in the housing 1, for example a tubular one , elongated high pressure mercury vapor lamp. The two segments 2a and 2b of the reflector are attached to the inside of the housing 1 with the aid of screws 5a, 5b, Sc and Sc /. The light source 3 is cooled in that a cooling flow is conducted around the center of the light source 3, which flow only strikes at right angles to the axis of the light source 3. The cooling flow is generated with the aid of a fan 4 fastened to the rear of the housing 1 with the aid of screws 6a and 6b. Like F i g. 3 shows, the cooling effect is accordingly high in an area 3a of the glass body wall which is upstream with respect to the cooling flow, whereas it is low in an area 3b which is downstream with respect to the cooling flow. This is due to the fact that the angle Θ, which detects how far the cooling flow is around the glass body wall, is approximately 20 ° regardless of the cooling flow velocity and that vortices 10 are therefore generated in the region of section 3b. Investigations have shown that the temperature distribution on the glass body wall of a light source 3, which is a tubular, elongated high-pressure mercury vapor lamp which is supplied in excess of 90 watts per cm of arc length, is very uneven in the conventional lighting device shown in FIG this F i g. 4 shows.

When a powerful light source is made smaller, the burden of the

> Vitreous wall of the light source so that the Heat load on the glass body wall becomes high and a stronger cooling flow is required. If the Cooling flow is stronger, however, the area 3a is cooled too much, so that the desired high

ίο Luminous efficiency cannot be achieved because the mercury in the light source is no longer completely evaporated. On the other hand, the section 3b is not completely cooled because of the small angle of flow around it, so that there is a risk that the glass body wall will break at certain points due to strong thermal stresses

The lighting device shown in Fig. 5 comprises a trough-shaped reflector which is divided into two segments 2a and 2b , which are parallel to one

> O elongated, tubular light source 3, which is, for example, a high-pressure mercury vapor lamp, are arranged in an elongated, box-shaped housing 1 in the longitudinal direction thereof. A cooling flow X , which cools the wall of the glass body of the light source 3, which is located close to the slot, is passed through a slot formed from the segments 2a and 2b on the bottom 2a ', 2ΰ of the reflector. Thus, two parts of the cooling sirome, which flow along the surface of the vitreous wall and the reflector, meet in the vicinity of a section 36 of the vitreous wall so that a vortex 10 does not form (see FIG. 6). If necessary, there is a channel 7 on the rear of the housing, which connects the slot 9 with the fan 4.

F i g. 7 shows a diagram in which the temperature of section 3b of the glass body wall of the high-pressure mercury vapor lamp is shown as a function of a variable tIR. With t the distance between the slit 9 and the downstream in flow around by the cooling flow located portion is referred to 3d of the glass body wall, and R is the outside diameter of the lamp. The data were determined for a lamp with an outer diameter of 25 mm and an arc length of 1105 mm and for electrical input powers of 200 watts or 160 watts per cm arc length, while the cooling flow had a throughput of 80 liters per minute. From the data reproduced in the diagram it can be seen that the section 3b of the vitreous body wall on the downstream

v> located side is effectively cooled in the area up to ÜR = 2I3 and that the best cooling effect occurs in the area up to tiR = 1/3. Like Fi g. 8 shows the temperature distribution on the glass body wall of the lamp described above with an energy supply of 200 watts each

S5 cm arc length and for tiR = 1/3 noticeably even. 9 shows a further embodiment of the invention. This embodiment has an air duct II on the bottom 2a ', 2ti of the reflector with the segments 2a and 26, and the mouth 9' of the

the air duct is arranged in such a way that a value t'IR of up to 1/3 results. Here is ('the distance between the mouth 9' and the downstream section 3b of the glass body wall when the cooling flow flows around it. The air duct 11 is then important,

». · If the desired light distribution on the surface of an object can only be achieved if the light source 3 is in an area with t / R greater than 1/3.

The air duct 11 is preferably joined to the reflector 2a, 2b in the manner shown in FIG. 10. A small groove made of two segments 11a and 11b is provided which surrounds the light source in such a way that the cooling current is simply guided around the glass body wall of the light source 3.

For this purpose 3 sheets of drawings

Claims (2)

Patent claims: 1.Lighting device with an elongated, box-shaped housing, a cooling device on the rear wall of the housing, a trough-shaped reflector with an exhaust air opening in its area facing the rear wall of the housing and a tubular, elongated discharge lamp arranged in the longitudinal direction of the housing, with a power consumption of more than 90 watts per cm arc length, characterized in that the exhaust air opening (9, 9 ') is designed in the form of a slot, and that the distance (t, t') between the end of the slot facing the discharge lamp (3) and the discharge lamp is at most a Third of the outer diameter (R) of the discharge lamp 2. Lighting device according to claim 1, characterized in that uas the discharge lamp (3) facing end (9 ') of the slot is formed by an air duct (II) which extends beyond the reflector surface (2a, 2b) against the discharge lamp (3) protrudes.