EP2281298A1

EP2281298A1 - High-pressure discharge lamp

Info

Publication number: EP2281298A1
Application number: EP09757440A
Authority: EP
Inventors: Patrick Müller; Klaus Stockwald; Herbert Weiss
Original assignee: Osram GmbH
Current assignee: Osram GmbH
Priority date: 2008-06-03
Filing date: 2009-05-28
Publication date: 2011-02-09
Anticipated expiration: 2029-05-28
Also published as: WO2009147058A1; US8334652B2; DE102008026522A1; CN102057460A; EP2281298B1; US20110074286A1; JP2011523767A

Abstract

The high-pressure discharge lamp has a ceramic discharge vessel with an aspect ratio of at least 1.5. For operation with acoustic resonances, a wall loading of the outer surface of the subregion which extends between the tips of the electrodes is from 28 to 40 W/cm2 and at the same time ensures a specific rated power of the entire outer surface of the discharge vessel, with exclusion of capillaries or stoppers, of 17 to 22 W/cm2.

Description

Title: High pressure discharge lamp

Technical area

The invention is based on a high-pressure discharge lamp according to the preamble of claim 1. Such high-pressure discharge lamps are intended for operation with acoustic resonances and normally have a metal halide filling.

State of the art

WO 2005/088675 discloses a high-pressure discharge lamp with a ceramic discharge vessel, which has a metal halide filling, wherein in addition to Hg and Xe, the metal halides NaJ, TlJ, CaJ2 and SEJ3 are used. Above all, Ce, Nd and / or Pr are used as selenium earth metals SE. The wall load should be at least 30 W / cm ² , based on the range of the discharge length between the electrodes. This lamp is intended for automotive applications and is operated without acoustic resonance.

A similar high pressure discharge lamp is shown in EP 1 729 324. Here, the possibility of resonant operation with longitudinal acoustic resonance is described in detail.

Presentation of the invention

The object of the present invention is to provide a metal halide lamp which is suitable for use with acoustic resonance is provided, and which is characterized by high efficiency.

This object is achieved by the characterizing features of claim 1.

Particularly advantageous embodiments can be found in the dependent claims.

In principle, ceramic discharge vessels with metal halide filling are used for operation with acoustic resonances. In order to ensure a high efficiency, which can be in the range between 120 and 150 lm / W, it has been shown that the thermal conditions must be specifically improved. For different nominal powers, an acoustically induced convection must be specifically driven for this, which scales according to certain rules with the surface of the discharge vessel. As a result, novel thermal conditions can be enforced, which typically bring efficiency to heights of 140 to 150 lm / W.

The goal is to achieve stable multi-cell convection. This can then be maintained over a large rated power range. For this, it is crucial to define areas of specific surfaces and to observe guidelines for them. A suitable characteristic for this is the power density.

By describing the scaling laws for the ratios of surfaces with respect to the applied rated power, ceramic discharge vessels for different power classes and luminous flux classes can be configured. The invention specifically controls the convection flow in the operated with acoustic modes filling. This flow would result in an additional heat flow past the electrode tip towards the end of the discharge volume. This would require a heating of this end and also the cold-spot. To curb this heating, effective end cooling must be established so that the cold spot and the end of the discharge vessel are not overheated.

In order to operate a metal halide lamp in the longitudinal acoustic mode, the geometry of the discharge vessel should have a so-called aspect ratio AV of at least 1.5. It is preferably in the range from 3.5 to 6, in particular AV = 4.5 to 5; an aspect ratio AV of 4.6 to 4.8 is particularly suitable. The aspect ratio is the ratio between the inner length and the inner diameter of the discharge vessel. The discharge vessel has a longitudinal axis and is substantially cylindrical. It can also be slightly bulged in the middle. An operation for such lamps is disclosed, for example, in US 6,400,100.

Preferably, a discharge vessel which is cylindrical relative to the internal volume is used. It has an outer lateral surface as well as outer end surfaces or at least inclined surfaces, which extend up to the base points of tubular ends, often capillaries. The outer surface plus the outer diagonal and end surfaces define an entire outer surface OSUM, excluding capillaries or plugs. Placing the nominal power P in relation to this total outer surface OSUM, it turns out -A-

for high efficiency, the specific rated power PS = P / OSUM thus defined must reach a value of 17 to 22 W / cm ² , while at the same time the wall load must be kept high. It should reach at least 28 W / cm ² .

To understand the invention, it is necessary to divide the discharge vessel into three sections transversely to the longitudinal axis. The limit is in each case the tip of the electrode. The solder on the longitudinal axis intersecting the tips defines a hot arc section in which the discharge arc extends. He gets relatively hot during operation. The wall load in the region of this arc section should preferably be in the range 28 to 40 W / cm ² . This outer surface of the arc section is denoted by OH.

The surface of the underlying ends including inclined surfaces or end faces, which cause the cooling, is denoted by OK. Since the discharge vessel has two ends, the surface of both ends must be used. As a rule, both ends are symmetrical, so each cooling surface has half of OK.

Cooling is particularly effective if the arc section to which OH is assigned reaches the high wall load W of at least 28 w / cm ² during operation, while the entire surface OSUM, ie the sum of OH and OK, is significantly lower specific power rating of 17 to 22 W / cm ² . In other words, the surface OK in the area of the ends must be sufficiently large. Preferably, the ratio VH between OK and OH is 0.75 to 1.00. It is particularly preferably in the range VH = 0.85 to 0.90. Technical changes such as coating or enlarging the surface by means of ribs or fins in the range of OK can be used to modify VH.

Favorable for the thermal conditions is also when the capillaries do not take up too much space. A preferred value for the ratio VK between the entire surface OC of the two capillaries including end faces and the entire surface of the discharge vessel OSUM is VK = 0.15 to 0.35. A value of 0.22 to 0.25 is preferred.

The wall thickness of the discharge vessel should preferably be dimensioned such that the specific rated power WI of the entire inner wall surface, which delimits the discharge volume, is 30 to 42 W / cm ² . Preferred is a value for WI of 38 to 41 W / cm ² .

If such wall loads and specific nominal powers are maintained, a suitable longitudinal temperature gradient TE of 15.5 to 19 K / mm can be achieved in the region of the discharge volume. Thus, the temperature gradient between the center point M, which is located centrally between the two electrodes, and the respective end point S of the discharge volume, which is closed by an end face, means, wherein the temperature is measured on the outside of the discharge vessel. The distance along the axis projection between M and S is denoted by g.

Preferably, the capillary should be constructed so that the temperature gradient TK over the inner axial length L of the capillary 30 to 45 K / mm, in particular 34 to 40 K / mm. This value is higher than in today's lamps (der- time less than 30 K / mm). It is achieved by making the end structure as short as possible.

The following temperatures should be set with these dimensions. In the middle of the discharge vessel it should be no more than 1200 ⁰ C, but at the end it should have dropped to a maximum of 1080 ⁰ C at point S. Preferably, it should be in the range 1050 to 1070, most preferably a value below 1050 ⁰ C.

This consideration is independent of whether the end construction in integral construction, plug, etc. takes place.

A specific exemplary embodiment of the invention takes into account that in order to support the cooling effect on the cooling end surface, at least partially on the outer surface OK of the discharge vessel, a coating transparent in the visible spectral range with increased NIR emissivity is provided. By NIR is meant a range of 0.8 to 3 μm (near infrared). The typical NIR emissivity ε of ceramics such as A12O3 without coating is about 0.1. The coating may extend over the entire end region, or only a part thereof. The emissivity ε can reach values of up to 0.8 in the case of graphite.

The long-wave IR radiation between 3 and 8 μm, on the other hand, is partly reflected by the outer bulb and can not be used for local cooling of surface areas. In contrast, the radiation in the range up to 3 microns escape partially through the glass of the outer bulb. The emissivity for this area can therefore be targeted with a ner coating can be improved to support the cooling of the end region.

Any high-temperature-resistant layer which is transparent in the visible spectral range, in particular graphite, but also transparent conductive layers or multilayer layers (for example ZrO 2 / ITO (indium-tin oxide)) is suitable as a coating, the outermost layer representing a conductive layer. Conductive transparent high-temperature-resistant layers have the property of an emissivity corresponding to their internal electron-plasma frequency. When a part of the area to be cooled is coated, its emissivity increases. Therefore, the cooling surface can be reduced in the end, down to a value of 60% of the surface without coating.

Brief description of the drawings

In the following, the invention will be explained in more detail with reference to several embodiments. The figures show:

FIG. 1 shows a metal halide lamp with a ceramic discharge vessel;

Figure 2 shows the ceramic discharge vessel in section in

Detail; FIG. 3 shows a representation of the relevant parameters on

Discharge vessel; Figure 4 shows an alternative for the end region with coating. Preferred embodiment of the invention

An embodiment of a metal halide high-pressure discharge lamp 1 is shown in FIG. 1. It has a ceramic discharge vessel 2, which is closed on both sides. It is elongated and has two ends 3 with seals 6. In the interior of the discharge vessel, two electrodes 4 are located opposite each other. The seals 6 are designed as capillaries, in which an electrode system 16 is sealed by means of glass solder 19. From the capillary 6 in each case a supply line 5, which is connected to the associated electrode 4 in a known manner, projects. This is in each case connected via a frame 7 with a contact in the base 13.

Suitable filling for the discharge vessel are known metal halide fillings, in particular the discharge vessel contains a filling with metal halides which is selected from the group of the iodides of Na, Tl, Ca, rare earth metals (SE) alone or in combination. The system is particularly suitable for the following filling system: NaJ, TlJ, CaJ2 together with SEJ3, where SE is at least one of the elements Ce, Pr, Nd.

In Figure 2, the end portion is shown in detail. The capillary 6 is here attached integrally to the discharge volume. The end section begins at the tip of the electrode (dashed line, line a) and extends to the point where the capillary reaches its constant diameter (line b).

FIG. 3 shows an exemplary embodiment in which the discharge vessel is a cylindrical tube 20 with an aspect ratio of approximately 4.7. At the slightly tapered end of a plug 6 is inserted into the tube opening of the end and sealed with glass solder. The rated power is 70 W. The total wall load is 19.5 W / cm ² . The wall load in the area between the tips of the electrodes (between the two lines a) is 34 W / cm ² . The ratio between the cooled surface (behind the tip of the discharge vessel including the end face at line b) and the heated surface (between the two lines a) between the electrodes is about 85%. The ratio between the total surface area of the capillaries and that of the discharge vessel is 22 to 25%. The wall load on the inner surface 21 (total) is 39, 5 W / cm ² .

The gradient of the temperature (measured on the outside of the discharge vessel) between the center M of the discharge vessel (exactly between the two electrode tips) and the point S on the outside of the end face closing off the discharge vessel is 15.5 to 19 K / mm. Preferably, the highest possible value is between 17.5 and 18.5 K / mm. On the other hand, today's usual value is 12 to 15 K / mm. Similarly, for the temperature gradient TK along the capillary, a gradient of temperature 34 to 41 K / mm is achieved between the point TK1 at which the capillary starts (seen externally) and the end TK2 of the capillary. Preference is given to the highest possible value of 39 to 41 K / mm. In contrast, today's usual value is about 27 to 28 K / mm.

The ratio between the cooled and heated outer surface OK and OH of the discharge vessel should normally, ie uncoated, in the range 75 to 100%. When using an NIR emissive coating, the Area of the cooled end can be chosen correspondingly lower down to 60% of the value without coating.

Figure 4 shows an embodiment in which the surface of the end 3 is partially coated in the region of P.

The above conditions apply above all to A12O3 ceramics. However, similar conditions apply to other ceramics such as AlN or sapphire or mixed systems.

In the case of a coating, the value of the ratio OK to OH can be reduced by up to 20%. Overall, a value of 60 to 100% is recommended. If uncoated, a value of 75 to 100% should be kept if possible. Depending on the degree and extent of the coating and material, it can be lowered to 60%.

Claims

claims

A high-pressure discharge lamp with an elongated ceramic discharge vessel, at the ends of which an electrode system with an electrode tip pointing toward the discharge is held in a seal, wherein the seal is tubular and in particular comprises a capillary, wherein the discharge vessel has an aspect ratio AV of at least 1, 5, the discharge vessel having a metal halide filling and a wall load of more than 25 w / cm ² , characterized in that the lamp is suitable for operation with longitudinal acoustic modulation, wherein the specific rated power PS of the entire outer surface OSUM of the discharge vessel in the range between 17 and 22 W / cm ² , while at the same time the wall load in a partial region of the surface OH, which extends between the tips of the electrodes, in the range between 28 and 40 W / cm ² .

2. High-pressure discharge lamp according to claim 1, characterized in that a cooling of the ends effecting surface OK, which is outside of OH, between 60 and 100%, preferably 75 and 100%, of OH makes.

3. High-pressure discharge lamp according to claim 1, characterized in that the ratio between the O- surface OC of the two capillaries and the surface OSUM of the discharge vessel is between 15 and 35%.

4. High-pressure discharge lamp according to claim 1, characterized in that the specific rated power of the entire inner surface of the discharge vessel at 30 to 42 W / cm ² .

5. High-pressure discharge lamp according to claim 1, characterized in that the gradient TE of the temperature between the center of the discharge vessel and the point S at the level of the end face is 15.5 to 19 K / mm.

6. High-pressure discharge lamp according to claim 1, characterized in that the gradient TC of the temperature between the base of the capillary and the end point of the capillary is between 34 and 41 K / mm.

7. High-pressure discharge lamp according to claim 1, characterized in that at least part of the surface OK of the end region is coated with an NIR coating or provided with a surface-enlarging structure, in particular with fins or ribs.

8. High-pressure discharge lamp according to claim 1, character- ized in that the discharge vessel contains a filling with metal halides, which is selected from the group of iodides of Na, Tl, Ca, rare earth metals alone or in combination.