DE3920649A1 - Method and device for equalising the temperature distribution of lamps for luminaires without electrodes - Google Patents

Abstract

The lamp of a luminare without electrodes is rotated about an axis which lies at a specific angle to the predominant direction of the electrical field. This causes the temperature distribution to be equalised over the lamp and a reduction in the formation of hot and cold spots.

Description

The present invention relates to a method and a device for equalizing the temperature distribution Lamps for electrodeless lights.

It is known that the lamps in electrodeless lamps become extremely hot and effectively cooled during operation Need to become. The heating of such lamps represents an upper limit for the power density of the electromagnetic energy that can be coupled with the lamps, and thus for the brightness of the light emitted by the lamps can be.

In U.S. Patent Nos. 44 85 332 and 46 95 757, their Assignee's assignee of the present invention  the thought is revealed, a relative rotation between the lamp of the lamp and flows of cooling fluid to be provided, which are applied to the lamp. This System saw a significant improvement over the booth the technology in which the lamp was held stationary and a cooling fluid was only directed at them. In the pending application No. 0 73 670 is a Ver drive to the high speed rotation of the lamp revealed that to a more even temperature distribution over the Lamp leads.

However, for some applications it is an even one Wall temperature load than according to the teaching of the above Pat. Nos. 44 85 332 and 46 95 757 required. e.g. evaporate some filler materials like the rare earth hali de (e.g. dysprosium iodide) only near the upper temp rature limits of the synthetic quartz lamp wall. The tempera turdifferenz on the lamp, which after the rotary cooling process The patented state of the art can be used as high be that these fillers are the coldest part of the lamp can condense, on the other hand, the high temperature of the hottest part of the lamp its lifespan.

With improved uniformity of the wall load, the hottest part of the lamp colder, and the coldest part of the The lamp is getting warmer. This allows the maintenance of higher ones Vapor pressures of the fill material, resulting in higher operational efficiency has the consequence.

In the systems described in the above patents are disclosed, the lamp is rotated about an axis which either perpendicular or parallel to the direction of the electri field in the microwave cavity. This resulted to hot spots or to a hot band around the equator the lamp and much colder areas at the poles.  

The inventor of the present application has discovered that the Temperature distribution around the lamp and the Condensation tendency of the temperature sensitive fill terials is reduced when the angle between the rotations axis of the lamp and the electric field not equal to 90 ° or 0 ° is set. According to the invention, this angle between about 30 ° and 70 ° or equivalent between about 110 ° and 150 ° and is preferably between about 40 ° and 60 ° or equivalent between about 120 ° and 140 °.

The present invention thus has a method for the temperature distribution of an electrodeless lamp Luminaire in a predetermined angular relationship to the direction of the to equalize electric field, as well as a Vorrich tion to carry out such a procedure.

In the attached drawings is

Fig. 1 is a pictorial representation of a rotating cooling system for a lamp according to the prior art,

FIG. 2 shows the direction of the electric field in the system from FIG. 1, FIG.

Fig. 3 is a representation of the hot and cold regions of the lamp 1 in the system of FIG.

Fig. 4 is an illustration of an exemplary embodiment of the present invention,

FIG. 5 shows an arrangement of cooling nozzles that can be used in connection with the exemplary embodiment from FIG. 4, FIG.

Fig. 6 shows the representation of a microwave lamp that uses a hollow cylindrical shape,

FIGS. 7 and 8 are each a diagram showing another imple mentation of the present invention, and

FIG. 9 shows a detail from FIG. 7, which shows the lamp holding arrangement.

FIG. 1, which shows the rotating cooling system according to the prior art, as disclosed in the above-mentioned US Pat. No. 4,485,332, shows that the lamp 4 is located in a microwave cavity, which consists of the spherical solid part 6 and the flat grid 3 . The microwave energy generated by the magnetron 10 is supplied through the waveguide 12 to the microwave cavity into which it enters through the coupling slot 14 .

The lamp 4 is held by the lamp arm 8 which is rotated by the motor 16 which is secured to the cavity by the holding arrangement 18 . The motor thus rotates the lamp 4 while flows of cooling fluid are applied to it to cool the lamp.

Fig. 2 shows the direction of the electric field in the lamp of Fig. 1, and it can be seen that the prevailing field direction on the lamp is perpendicular to the axis of rotation of the lamp.

If the lamp was not rotated in the arrangement shown in FIGS. 1 and 2, then two hot spots would result at the upper and lower center of the lamp, respectively, while there would also be relatively cool areas which are 90 ° around the spherical Lamp are moved. Figure 3 shows that the rotation of the prior art lamp causes the two hot "spots" to become a hot ribbon. Thus, if the area where the lamp arm meets the lamp and the area directly across the lamp are referred to as the poles, the lamp has a hot band around the equator and cold areas at the poles .

In this prior art cooling system, there were nozzles for the application of cooling fluid in the spherical cavity in a plane that is in the equator of the lamp, arranged, and the nozzles were on the hot band around the Equator directed.

Fig. 4 shows an embodiment of the present inven tion, in which it can be seen that the axis of rotation of the lamp is angularly shifted from its location in the prior art. This results in the formation of two separate hot bands instead of one, with the result that the entire surface of the lamp is heated more evenly. Parts of these respective tapes are marked in Fig. 4 with the letter A be.

The optimal angle of the axis of rotation offset can be in ver different microwave cavities, or when using different cooling nozzle geometries. The Angle can be between about 20 ° and about 60 ° preferably between about 30 ° and 50 °. Because the offset in everyone Direction from the axis according to the prior art the angle between the new axis of rotation and the predominant direction of the electric field of about 30 ° to 70 ° or from about 110 ° to about 150 °, and is preferably he between about 40 ° and 60 ° or between 120 ° and 140 °.

A possible cooling fluid configuration is shown in FIG. 5. Here, the cooling nozzles 24 , 26 , 28 , 32 are arranged around holes in the spherical cavity, which are located in a plane in the cavity, which is also in the plane of the lamp equator. However, the nozzles in the present embodiment would be offset so that they would be directed to the respective hot bands, in contrast to the prior art arrangement in which the nozzles were directed to the equator.

Fig. 6 shows an electrodeless lamp that uses a cylindrical cavity 40 , which is supplied through the slot 46 with microwave energy from the waveguide 48 . The lamp 42 is held in the cavity by the arm 44 which was rotated by a motor (not shown) in the prior art. It can be seen that the predominant direction of the electric field is perpendicular to the lamp arm.

FIGS. 7 through 9 of the front lying invention illustrates an embodiment that uses a cylindrical cavity in which the direction of the lamp arm winkelverscho is ben. It can be seen in these figures that the lamp 56 is held in the cavity 52 by the lamp arm 58 which is rotated by the motor 60 so that the lamp arm is at an angle to the normal to the direction of the electric field. As explained above, this angle is approximately between 20 ° and 60 ° and is preferably between approximately 30 ° and 50 °.

While the lamp 56 is being rotated, a cooling fluid is applied to the lamp from the nozzles 62 . These nozzles are mounted so that they are directed to the hot tapes on the lamp.

In the embodiment of FIGS . 7 to 9, microwave energy which is generated by the antenna 69 of the magnetron 68 is fed to a waveguide 70 , which supplies the energy through the slot 66 to the cavity 52 . The waveguide 70 is bent and consists of the waveguide sections 71 , 72 , 73 .

Of course, the invention is based on electrodeless lights reversible in which the lamp in a single microwave field is arranged, because this situation is too uneven Temperature distribution leads. In lamps, the multiple fields use as disclosed in U.S. Patent No. 47 49 915, tend to be those caused by the individual fields Temperature distributions to dislocation, so that a more uniform overall temperature is obtained.

The invention thus describes an improved method and a device for balancing the thermal charge of the Wall of a lamp in an electrodeless lamp. Others and differently designed lamps and cavities than those in the version Example shown can of course be used will.

Claims (19)

1. Method for equalizing the temperature distribution of the lamp wall in an electrodeless lamp, characterized by the steps,
to provide an electrodeless lamp with a lamp which contains a gaseous filling and which is arranged in only one electromagnetic field, the field having an electrical field component which is predominant in a first direction, and
rotating the lamp about an axis that is at an angle of between about 30 ° and about 70 ° or between about 110 ° and about 150 ° to the first direction. 2. The method according to claim 1, characterized in that the angle either between about 40 ° and about 60 ° or is between about 120 ° and about 140 °.   3. The method according to claim 2, characterized in that the electrodeless lamp also has a microwave cavity comprises, in which the lamp is arranged, and in which the electromagnetic field has a microwave field. 4. The method according to claim 3, characterized in that the electromagnetic field only through a single magnetron is produced. 5. The method according to claim 4, characterized in that the cavity has only a single coupling slot for coupling of microwave energy. 6. The method according to claim 2, characterized in that the lamp has a spherical shape. 7. The method according to claim 3, characterized in that the lamp has a spherical shape. 8. The method according to claim 3, characterized in that Cooling fluid is applied to the lamp when it is rotated becomes. 9. The method according to claim 3, characterized in that Cooling fluid is applied to the lamp when it is rotated becomes. 10. Electrodeless lamp, characterized by

• - a microwave cavity,
• a lamp which contains a gaseous medium and is arranged in the cavity,
• a device for generating microwave energy,
• - A device for coupling the microwave energy with the cavity, so that only an electric field is set up in the cavity, which is predominant in a first direction, and
• - A device for rotating the lamp about an axis which is at an angle of between about 30 ° and about 70 ° or between about 110 ° and 150 ° to the first direction.

11. Electrodeless lamp according to claim 10, characterized records that the device for generating microwaves energy has a single magnetron, and that the coupling device has a single coupling slot in the cavity. 12. Electrodeless lamp according to claim 11, characterized records that the angle is either between about 40 ° and about 60 ° or between about 120 ° and about 140 °. 13. Electrodeless lamp according to claim 12, characterized records that the device for rotating the lamp one Has motor, and an arm between the motor and the lamp is arranged. 14. Electrodeless lamp according to claim 13, characterized records that the cavity has a spherical shape. 15. Electrodeless lamp according to claim 12, characterized records that the cavity has a cylindrical shape points.   16. Electrodeless lamp according to claim 12, characterized records that the lamp has a spherical shape. 17. Electrodeless lamp according to claim 15, characterized records that the lamp has a spherical shape. 18. Electrodeless lamp according to claim 12, characterized records that they continue to be a facility for application the lamp with cooling fluid when rotated. 19. Electrodeless lamp according to claim 16, characterized records that they continue to be a facility for application the lamp with cooling fluid when rotated.