EP2866249A1 - Light generation unit and electrode-free discharge lamp - Google Patents

Abstract

The present invention relates to a light generating unit (10) disposed inside an outer bulb (2) for an electrodeless discharge lamp (1) for ultraviolet ray generation and an electrodeless discharge lamp therefor. The light generating unit (10) has a discharge vessel (3) and a flat inductive coil arrangement (4), which is operatively coupled to the discharge vessel (3). In this case, the discharge vessel (3) is wider in a first expansion direction (X) and a second expansion direction (Y) than in a third expansion direction (Z). The discharge vessel (3) has at least one slot-shaped recess in which the coil arrangement (4) is arranged. In this case, the slot-shaped recess divides the discharge vessel (3) into a first chamber section and a second chamber section, a connection section remaining between the first chamber section and the second chamber section. The power supply (9) supplies the coil arrangement and the ballast (6) by means of an electrical conductor (7) with the voltage which is necessary for the operation of the discharge lamp (1).

Description

The invention relates to a light-generating unit and to an electrodeless discharge lamp having such a light-generating unit.

To produce technical ultraviolet radiation electrodeless discharge lamps are known, which have a largely homogeneous radiation in a flat design. For this purpose, transparent or translucent discharge vessels are provided which contain an ionizable gas mixture with a metal halide or another light emitting material in an ionizable state.

From the US Pat. No. 6,194,828 B1 a discharge lamp of two discharge vessels arranged adjacent to one another is known, wherein the discharge vessels are arranged on both longitudinal sides of an induction coil in an evacuated outer bulb constructed of glass lenses. This discharge lamp is used for flashing light - such as emergency lighting or highway lighting.

The US 5,500,574 discloses a discharge lamp for general lighting tasks, which has a discharge vessel with an induction coil to one side, wherein the discharge vessel for mercury-containing fillings is provided. Between coil and discharge vessel, a reflector is provided which reflects the light generated in the discharge vessel and allows increased illumination in one or two spatial directions.

Planar coils which are formed over the entire extent of the discharge vessel (for example in the longitudinal direction) have hitherto been used in the aforementioned prior art. The disadvantage here is that the distribution of the magnetic field for power input into the ionizable gas mixture which is filled in the discharge vessel can not be influenced. In the case of a double-sided arrangement, both discharges are in lead the separate discharge vessels independently, which means that the optimal setting of the discharge for each vessel must be made separately.

Based on this prior art, the present invention has the object to provide a light generating unit for an electrodeless discharge lamp for generating ultraviolet radiation, which allows a uniformly high optical radiation while flat construction

This object is achieved by a light generating unit having the features of independent claim 1.

The further object to provide an electrodeless discharge lamp, which allows a high optical radiation and modular design, is achieved by the discharge lamp having the features of independent claim 9.

Preferred embodiments of the light generating unit and the discharge lamp are described by the subclaims.

An embodiment of the light generating unit according to the invention has a discharge vessel and a flat inductive coil arrangement, which is operatively coupled to the discharge vessel. In this case, the discharge vessel is wider in a first expansion direction and a second expansion direction than in a third expansion direction. The discharge vessel has at least one slot-shaped recess in which the coil arrangement is arranged. In this case, the slot-shaped recess divides the discharge vessel into a first chamber section and a second chamber section, a connection section remaining between the first chamber section and the second chamber section.

Advantageous in the present electrodeless discharge lamp are two Side of the discharge vessels connected to each other, creating a common discharge. This has the advantage that the discharge can be brought to the optimum operating point with only one cold-spot temperature adjustment, which does not work with separate vessels, as known from the prior art. As a result, the entire discharge vessel can be made comparatively flat with respect to the discharge vessels known from the prior art.

The slot-shaped recess is also configured flat, wherein shallow means that the slot-shaped recess extends flat, so can extend substantially in the first and the second direction of expansion. The discharge vessel may be square or alternatively also rectangular, wherein the slot-shaped recess may also be square or rectangular.

However, other geometries, such as, for example, substantially triangular or rounded shapes are possible; then the shapes of the recess are adapted to this. It is provided that the spatial extent of the slot-shaped recess substantially corresponds to the spatial extent of the coil arrangement.

It can be provided that the chamber sections of the discharge vessel can be rectangular in cross-section, rectangular with rounded corners or preferably oval. Especially in the case of an oval cross-section, the discharge vessel can be made quickly and easily from prefabricated glass tubes, which are flattened and folded accordingly.

Since the coil arrangement can, for example, have a width of 200 mm, a length of 200 mm and a depth of 10 mm, the slot-shaped recess is dimensioned slightly larger in each direction of expansion. The coil assembly can thus be easily inserted and held in the slot-shaped recess. Preferably, the dimensions can be closely matched to one another (eg difference between one another smaller than 1 mm) to allow a good passport holder. If the slot-shaped recess is dimensioned too broadly (eg, a difference greater than 1 mm), a simple exchange of the coil arrangement can take place, for example if one of the components has to be repaired or replaced.

According to the invention it can be provided that the connecting portion can extend along one or more side edge (s) of the discharge vessel. Alternatively, the connecting portion may extend along two or three side edges of the discharge vessel, so that a pocket-shaped recess for the coil assembly may be formed. Thus, a flat discharge vessel can be realized, which by the connected edges, d. H. the common connecting portion of the discharge vessel, also can deliver radiation sideways. The radiation alignment can thereby be significantly increased. When exciting the filled in the discharge vessel ionizable gas mixture can thus be a light emission in all three spatial directions.

According to yet another embodiment, the coil arrangement can be formed by a single coil whose extension corresponds to the extent of the coil arrangement itself. Alternatively, the coil assembly may be formed of a plurality of small coils. By dividing a single flat coil into many smaller coils, a more homogeneous discharge in the discharge vessel can be achieved. This can advantageously be preset in the discharge vessel depending on the discharge material used. Here, the flat lamp geometry, for example, can be produced inexpensively by a flat round tube.

For this purpose, it may also be advantageously provided that the small coils are connected in parallel to each other or alternatively in series. This can be done on the part of the ballast, an improved setting how much current can flow through the individual coils or should. This allows the system to be adapted to different supply voltages. According to a further embodiment, the single coil or one or more small coil (s) may be planar square or planar circular. Especially in the case of rectangular or square-shaped discharge vessels, an even more homogeneous discharge in the discharge vessel can be achieved by means of a square coil arrangement. Above all, in an angular vessel with square coils, the coupling surface can be better utilized because no free surfaces remain in the corner regions. The distribution of the magnetic field for power input can be controlled in a simple manner.

The coil assembly itself may be formed substantially planar so as to extend substantially in the first extension direction and the second extension direction.

In order to increase the radiation yield of the light generating unit even more, a reflector can be arranged in the slot-shaped recess between one or more inner walls of the discharge vessel and the coil arrangement, whereby the radiation yield can be substantially increased. The reflector may be constructed of layers of phosphorus and Al ₂ O ₃ or other suitable materials; The layers can be vapor-deposited on the inner wall of the discharge vessel. However, other variants are conceivable, such as flexible usable steamed platelets, which can be inserted depending on the application between the coil assembly and inner wall, possible. There are also reflectors conceivable that can be mounted in predetermined sections, so that the radiation can be directed in certain directions. It may be possible to obtain different illumination areas by the reflector is realized only to one side or in a certain section or has structural openings or patterns. In particular, this is a simple structure z. B. a simple sheet advantageous.

The discharge lamp may advantageously have a voltage supply, which is electrically connected to the coil assembly. The power supply can be equipped here for the light generating device as such with a ballast or operating device for control.

An electrodeless discharge lamp for ultraviolet radiation generation according to the invention has an outer bulb which is at least partially translucent and one or more light generation units (s) arranged in the outer bulb. The light generating unit is present in one of the aforementioned embodiments.

The discharge lamp can be operated as a mercury-containing or mercury-free lamp. The filling of the discharge vessel of the light generating unit can be filled with an ionizable gas mixture, the u. a. a vaporized metal or vaporized metal halide, nitrogen, and also a noble gas, preferably argon. Other suitable material mixtures may be filled into the discharge vessel, depending on the application and the lighting situation for which the discharge lamp is to be used.

Advantageously, with the discharge lamp according to the invention, technical UV radiation with homogeneous, surface radiation without electrodes integrated in the discharge vessel can be produced; at the same time flat construction of the same.

The partial translucence of the outer bulb can be realized by a transparent or translucent material (eg, a borosilicate glass), depending on the application requirement. Accordingly, the discharge vessel may be made of a transparent or translucent material, preferably a glass such as quartz glass or other temperature and pressure resistant glasses. Also, translucent ceramic materials can be used, for example, from Al ₂ O ₃ .

Fig. 1

einen schematischen Aufbau einer erfindungsgemäßen Entladungslempe;

Fig. 2a bis 2c

schematische Ansichten einer Ausführungsform einer erfindungsgemäßen Lichterzeugungseinheit;

Fig. 3a bis 3c

schematische Ansichten einer alternativen Ausführungsform der erfindungsgemäßen Lichterzeugungseinheit;

Fig. 4

eine weitere alternative Ausführungsform der erfindungsgemäßen Lichterzeugungseinheit; und

Fig. 5 bis 8

alternative Spulenamordnungen für die erfindungsgemäße Lichterzeugungseinheit.

Other embodiments, as well as some of the advantages associated with these and further embodiments are made clearer and easier to understand by the following detailed description. Supporting here is the reference to the figures in the description. Items or parts thereof that are substantially the same or very similar may be given the same reference numerals. Show it:

Fig. 1

a schematic structure of a discharge according to the invention;

Fig. 2a to 2c

schematic views of an embodiment of a light generating unit according to the invention;

Fig. 3a to 3c

schematic views of an alternative embodiment of the light generating unit according to the invention;

Fig. 4

a further alternative embodiment of the light generating unit according to the invention; and

Fig. 5 to 8

alternative coil arrangements for the light generating unit according to the invention.

In Fig. 1 a discharge lamp 1 according to the invention is shown, which has an outer bulb 2 and a light generating unit 10 arranged inside the outer bulb 2. The light-generating unit 10 also has next to the discharge vessel. 3, which is filled with an ionizable gas mixture, a coil assembly 4, which serves to couple high-frequency power in the ionizable gas mixture. A ballast 6 for providing the high-frequency power is electrically connected to the coil arrangement 4 and consequently to the light-generating unit 10. The power supply 9 supplies the coil arrangement and the ballast 6 by means of an electrical conductor 7 with the voltage which is necessary for the operation of the discharge lamp 1.

The Fig. 2a to 2c show an embodiment of the discharge vessel 3, wherein for better orientation, the respective expansion directions X, Y and Z are designated. The Fig. 2a shows the discharge vessel 3 in a front view, Fig. 2b in a side view and Fig. 2c in a sectional view along the section AA Fig. 2a ,

The discharge vessel 3 is a glass vessel 3, which encloses a chamber which has an ionizable gas mixture (possibly with an ionized state of light-emitting metal, for example mercury) in a first chamber section 3a and a second chamber section 3b.

The first chamber portion 3a and the second chamber portion 3b are connected to each other via the connecting portion 3c as a common vessel portion, whereby a continuous discharge chamber is formed and the ionizable gas mixture can be ignited there as well. In the side view in Fig. 2b is the discharge chamber composed of the chamber sections 3a, 3b and the connecting section 3c U-shaped. The connecting portion 3c extends at a lower side edge of the discharge vessel 3 in the X direction and along two side edges extending in the Y direction.

The inner wall 3d of the discharge vessel 3, which delimits the chamber sections 3a, 3b and the connecting section 3c, thereby also delimits the slot-shaped recess 5. The discharge vessel 3 is in Fig. 2a shown square, so that the slot-shaped recess 5 is also square. In the sectional view in Fig. 2c It is clear that the slot-shaped recess 5 delimited by the inner wall 3d of the discharge vessel 3 is formed flat rectangular.

To increase the radiation yield, a reflector 8 is arranged between inner wall 3d and coil arrangement 4. In this embodiment, the reflector 8 is completely against the inner wall 3d of the discharge vessel.

The coil assembly 4 is inserted into the slot-shaped recess 5. A dimensioning of the slot-shaped recess 5 is matched to the dimensions of the coil assembly 4. Thus, a uniform excitation of the ionizable gas mixture in the discharge vessel 3 take place.

In the Fig. 3a to 3c a further embodiment of the discharge vessel 3 is shown, wherein the connecting portion 3c is formed only along one side edge, here the lower side edge in the first extension direction X. Again, a continuous discharge chamber is formed, the gas filling can ignite and radiate uniformly. In the sectional view of Fig. 3b the discharge vessel 3 is also U-shaped.

In the Fig. 4 an alternative discharge vessel is shown in cross section, the basic shape is not rectangular, but oval. This form is particularly easy to produce, since also easy to produce glass tubes can be easily flattened and an oval cross-section of self-adjusting.

In the Fig. 5 to 5 possible configurations of the coil assembly 4 are shown, wherein in Fig. 5 the coil assembly 4 is a quadratic single coil 4a. The to the example. In Fig. 1 shown round single coil, the square single coil cover the corner regions of the discharge vessel 3 more effectively and penetrate with applied voltage with magnetic field. The excitation of the emitting material is thereby made possible in the entire discharge vessel and the radiation is improved.

The other figures each show a large number of small coils 4b, which differ in shape and interconnection. In Fig. 6 nine small coils 4b are shown, which are connected square and parallel to each other. In Fig. 7 Sixteen round small coils 4b are connected in series with each other and in Fig. 8 nine square small coils 4 b are shown, which are also interconnected in series. Due to the different size and number of small coils 4b a correspondingly uniform excitation of the ionizable gas mixture is possible depending on the filling of the discharge vessel. LIST OF REFERENCE NUMBERS 1 discharge lamp 2 outer envelope 3 discharge vessel 3a First chamber section 3b Second Chamber Section 3c connecting portion 3d Inner wall discharge vessel 4 coil assembly 4a Single coil 4b small coil 5 Slot-shaped recess 6 power supply 7 Electrical conductor 8th reflector 9 Ballast discharge lamp 10 Light generating unit X First direction of expansion Y Second expansion direction Z Third expansion direction

Claims (9)

A light generating unit (10) for an electrodeless discharge lamp (1) for ultraviolet radiation generation, comprising a discharge vessel (3) and a flat inductive coil arrangement (4) operatively coupled to the discharge vessel (3), the discharge vessel (3) being in a first Extending direction (X) and a second extension direction (Y) is wider than in a third expansion direction (Z).
characterized in that
the discharge vessel (3) has at least one slot-shaped recess (5) in which the coil arrangement (4) is arranged, the slot-shaped recess (5) dividing the discharge vessel (3) into a first chamber section (3a) and a second chamber section (3b) divided, wherein between the first chamber portion (3a) and the second chamber portion (3b) a connecting portion (3c) remains. Light generating unit (10) according to claim 1,
characterized in that
the slot-shaped recess (5) extends substantially in the first extension direction (X) and the second extension direction (Y). Light generating unit (10) according to claim 1 or 2,
characterized in that
the connecting portion (3c) extends along at least one side edge of the discharge vessel (3). Light generating unit (10) according to at least one of claims 1 to 3,
characterized in that
the coil assembly (4) by a single coil (4a) or from a
Velzahl is formed on small coils (4b). Light generating unit (10) according to claim 4,
characterized in that
the small coils (4b) are connected to each other in parallel or in series. Light generating unit (10) according to claim 4 or 5,
characterized in that
the individual coil (4a) or at least one small coil (4b) of the multiplicity of small coils (4b) is of planar square or planar circular design. Light generating unit (10) according to at least one of claims 1 to 6,
characterized in that
in the slot-shaped recess (6) between at least one inner wall (3d) of the discharge vessel (3) and the coil assembly (4) a reflector (8) is arranged. Light generating unit (10) according to at least one of claims 1 to 7,
characterized in that
the discharge lamp (1) has a voltage supply (6) which is electrically connected to the coil arrangement (4). Electrodeless discharge lamp (1) for ultraviolet radiation generation, wherein the discharge lamp (1) has an outer bulb (2) which is at least partially translucent and a light generation unit arranged in the outer bulb (2),
characterized in that
the light generating unit is a light generating unit (10) according to at least one of claims 1 to 8.

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