WO2006131202A1

WO2006131202A1 - Lamp device with an outer bulb in particular a high-pressure discharge lamp

Info

Publication number: WO2006131202A1
Application number: PCT/EP2006/004840
Authority: WO
Inventors: Ulrich Peuchert; Peter Brix; Thilo Zachau; Jörg Fechner; Franz Ott
Original assignee: Schott Ag
Priority date: 2005-06-09
Filing date: 2006-05-22
Publication date: 2006-12-14

Abstract

The invention relates to a lamp device, preferably a metal halide high-pressure discharge lamp, comprising 1.1. a first body comprising an illuminant, 1.2. a second body enclosing the first body, whereby 1.3. the second body is made from an Al-silicate glass and 1.4. the Al-silicate glass 1.4.1. has a T<SUB>g</SUB> > 600°C, preferably > 650°C, more preferably > 700°C, particularly > 750°C and 1.4.2. a thermal expansion coefficient a (20° - 300°C) > 0, preferably in the range 3 = a (20° - 300°C) = 6, in particularly 3.5 = a (20° - 300°C) = 5.5.

Description

Lighting device with an outer bulb, in particular high-pressure discharge lamp

The present application claims the benefit of US Patent Application 11 / 345,167 filed on 01.02.2006 according to Section 120 USC. The present application is a continuation application of US 11 / 345,167. The disclosure of US 11 / 345,167 is incorporated in full in the present application.

The present invention relates to a lighting device comprising at least a first body having a lamp and a second body enclosing the first body, in particular, the present invention relates to high-pressure discharge lamps and in particular compact metal halide high-pressure discharge lamps.

In high-pressure discharge lamps, a first body forms a gas-tight discharge space, which is filled with an ionizable filling. The discharge space is also referred to as a burner. The discharge space of high-pressure discharge lamps according to the prior art, as described for example in WO 2004/077490 or WO2005 / 033802, comprises one or more metal halides, mercury and rare earth halides. These are added at RT in liquid or solid form in the burner and are present after ignition due to the then prevailing high pressures and temperatures in gaseous form.

The second body, which surrounds the first body and is preferably in the form of a piston, is used for thermal encapsulation of the first body, which represents the actual light-emitting unit and / or for damage / explosion protection or for the protection of materials and the lamp user from harmful Radiation, especially against UV rays. The burners of high-pressure discharge lamps, made of silica glass or translucent ceramic (eg Al ₂ O ₃ , YAG ceramics) are operated at the highest possible operating temperatures up to 1000 ^° C. or more. The higher the operating temperatures, the higher the color rendering index and the effectiveness and the lower the differences in the quality of light from lamp to lamp.

The space between the first and second body is mostly or substantially evacuated for thermal insulation. The second body, also called envelope, is doped with UV-blocking components for UV blocking.

The temperature at the second body, ie at the outer bulb is at a high-pressure discharge lamp, a so-called HID lamp, 300 ⁰ C - 850 ⁰ C. This depends on a number of factors, including the distance of the hot spot of the burner from the piston , Accordingly, the

Passage area significantly colder than the burner directly adjacent piston volume. Depending on the output of the burner and at very small distances of the hot-spot of the piston inner wall may well be wall temperatures up to 800 ⁰ C or above prevail.

As described above, the outer bulb should preferably be characterized by a high UV blocking. In particular, the type of UV-C radiation (around 260 nm) and the UV-B radiation (around 310 nm) should be blocked by the bulb. Ideally, the UV-A radiation is blocked by 360 nm to the highest possible proportion. The areas between these more or less discrete Hg-UV lines should also be blocked as well as possible because mercury or metal halides under pressure have broad emission bands here.

In the high pressure discharge lamps are as material for the first body, ie the so-called discharge space, in addition to silica glass as a material also translucent alumina, which is loadable up to 1100 ⁰ C or above used.

As materials of the second body, i. of the outer bulb are currently used predominantly silica glass or multi-component glasses.

In WO 2004/077490 an HID lamp is described, wherein as materials for the outer bulb quartz glass, toughened glass or soft glass is specified. However, the toughened glass is not specified in more detail in WO 2004/077490.

On the material side, the use of silica glass as the material for the

Outer bulb the disadvantage of insufficient UV blocking effect. UV blocking can be realized in silica glass by doping CeO ₂ , preferably in contents <1% by weight. However, this has the disadvantage of a residual transmission in the hard UV-C radiation.

The use of soft glass is not a problem in this respect, but leads to limited design freedom and / or limitation in the power output of the lamp.

Another problem with prior art H I D lamps is the range of feedthroughs. If, as described above, the first (inner) and / or second (outer) lamp vessel is made of silica glass, then the passages, seen from outside to inside, are made of W or Mo wire, which is attached to a Mo film with a thickness <100 is welded, and another welding point to a W-wire or Nb-wire, the inside of the lamp, z. B. W discharge electrodes leads.

The use of a Mo foil with a thickness of <100 μm is necessary in the prior art in order to minimize stresses in the region of the glass / metal leadthrough. The actual hermetic closure takes place over a few mm ² contact surface of Mo foil to the surrounding glass and is thus very unreliable. This locking technology also sets limits to the maximum current flow (approx. 20-25 A).

The use of a Mo film has further disadvantages described below:

When the bushing melts, the Mo film tends to burn. In the prior art, therefore, the melting is carried out in a protective gas stream, in particular under argon.

The melted films tend to oxidize during operation. This can lead to leaks and failure of the lamp.

The thin film allows only insufficient energy transport into the lamp. The production, i. the multiple welding together of metal components is complicated and expensive, also due to the spatial extent of the implementation system, the overall length of the lamp is unfavorably very large.

In order to overcome these disadvantages and to increase the compactness and / or design freedom of luminaires with HID lamps as the light source, in WO 2004/077490, instead of fusing the outer envelope together with a feedthrough wire, the outer envelope is joined to a base plate containing the feedthrough wires Fritring described. Thus, the> 10 mm long fusion zone is reduced to a minimum, given by the thickness of the plate.

According to WO 2004/07740, the base plate can be made of glass, ceramic or glass ceramic, for the piston as described above "quartz glass, soft glass or hard glass." The frit ring matehal is not further specified previously described that the material of the outer bulb is not specified. The object of the invention is to overcome the disadvantages of the prior art in high-pressure discharge lamps.

In particular, a lighting device to be specified with a first inner body and a second, outer body, in which the second body

(Outer bulb) is preferably attached to a non-zero strain base plate via a frit, i. there is no contact of the piston with the lead-through wires per se. The material of the outer bulb should have a high temperature resistance and a non-zero thermal expansion. In particular, in the field of implementation only small

Stress occur and the disadvantages described above are avoided.

According to the invention the object is achieved by a device according to claim 1, that is, the second body consists of an Al-silicate glass, such as a toughened glass. The Al-silicate glass has a Tg> 600 ⁰ C ₁ preferably 650 ⁰ C, more preferably 700 ° C, ideally> 750 ° C, more preferably> 770 ° C, particularly preferably> 790 ⁰ C and a thermal expansion coefficient α 2 ₀ / ₃ 00> 0, preferably in the range 3 <α 20/300 ≤ 6, in particular preferably 3.5 ≤ α 20/300 ≤ 5.5.

In a most preferred embodiment, an aluminosilicate glass of the second body, i. the material of the outer bulb, a tempered glass.

The aluminosilicate glass composition preferably has almost 100% blocking in the UV-C range, ie all wavelengths around 260 nm, preferably up to and including 300 nm, are no longer allowed to pass through at RT as well as at operating temperatures through the piston of thickness 1 mm or higher , In operation, all wavelengths around the UV-B line (at 310 nm) are particularly preferably 100% blocked, particularly preferably even wavelengths up to 320 nm. The UV-C range is understood to mean UV radiation at 260 nm, UVB radiation at 310 nm and UVA at UV wavelengths around 365 nm.

In the lighting device according to the invention, the lamp is composed of a plate carrying the current feedthrough and a piston. In order to avoid stresses between the outer bulb and the base plate as well as in the region of the _{leadthrough wires} , the expansion coefficient α _{20/300 of} the base plate and the outer _{bulb is} preferably substantially equal to that of the metal of the feedthrough _wires . Accordingly, the material of the feedthrough wires is therefore one of the following metals or alloys:

Tungsten molybdenum niobium metal covar alloy and Molezdenwanov alloy.

According to the thermal expansion coefficient α _{20/300 of} these metals, the expansion coefficient of the base plate and the outer bulb is therefore preferably in the range of 3.5 <α _20/300 ≤ 5.5 _{according to the invention} . For this reason, the use of quartz glass is generally not possible. For a sufficient UV-C blocking is therefore particularly suitable a multi-component glass, ie an aluminosilicate glass, hereinafter also referred to as "Al-silicate glass".

In a particularly preferred first embodiment, the Al-silicate glass contains the following composition (% by weight based on oxide):

SiO ₂ 50-66

B ₂ O ₃ 0-5.5

Al ₂ O ₃ 10 - 25 CaO 0-14

SrO 0-8

BaO 0-18

P ₂ O ₅ 0-2

ZrO ₂ 0-3

TiO ₂ 0-5

CeO ₂ 0-5

MoO ₃ 0-5

Fe ₂ O ₃ 0-5

WO ₃ 0-5

Bi ₂ O ₃ 0-5

Iterhin preferred Al-silicate glass contains the following components:

SiO ₂ 50-66

B ₂ O ₃ 0-5.5

Al ₂ O ₃ 13-25

MgO 0-7

CaO 5-14

SrO 0-8

BaO 6-18

P ₂ O ₅ 0-2

ZrO ₂ 0-3

TiO ₂ 0-5

CeO ₂ 0-5

MoO ₃ 0-5

Fe ₂ O ₃ 0-5

WO ₃ 0-5

Bi ₂ O ₃ 0-5 Yet another Al-silicate glass of the invention contains the following components:

SiO ₂ 50-66

B ₂ O ₃ 0- <0.5

Al ₂ O ₃ 14-25

MgO 0-7

CaO 5-14

SrO 0-8

BaO 6-18

P ₂ O ₅ 0-2

ZrO ₂ 0-3

Also preferred is an inventive Al-silicate glass containing the following components:

SiO ₂ 58-62

B ₂ O ₃ 0-5.5

Al ₂ O ₃ 13.5-17.5

MgO 0-7

CaO 5.5-14

SrO 0-8

BaO 6-10

ZrO ₂ 0-2

The above-mentioned Al-silicate glasses are substantially alkali-free. However, alkali-containing Al-silicate glasses can be used in just as suitable form. These are based, for example, on the following glass compositions in% by weight:

SiO ₂ 50-70 Al ₂ O ₃ 17-27

Li ₂ O> 0-5

Na ₂ O 0-5

K ₂ O 0-5

MgO 0-5

ZnO 0-5

TiO ₂ 0-5

ZrO ₂ 0-5

Ta ₂ O ₅ 0-8

BaO 0-5

SrO 0-5

P ₂ O ₅ 0-10

Fe ₂ O ₃ 0-5

CeO ₂ 0-5

Bi ₂ O ₃ 0-3

WO ₃ 0-3

MoO ₃ 0-3

and customary refining agents such as SnO ₂ , CeO ₂ , SO ₄ , Cl, As ₂ O ₃ Sb ₂ O ₃ in amounts of 0-4 wt .-%.

Another suitable alkali-free glass is based on the following glass compositions in wt .-%:

SiO ₂ 35-70, in particular 35-60

Al ₂ O ₃ 14-40, in particular 16.5-40

MgO O-20, preferably 4-20, in particular 6-20

ZnO 0-15, preferably 0-9, in particular 0-4

TiO ₂ 0-10, preferably 1-10 ZrO ₂ 0-10, preferably 1-10

Ta ₂ O ₅ 0-8, preferably 0 - 2

BaO 0-10, preferably 0-8 CaO 0 - <8, preferably 0 - 5, in particular <0.1

SrO 0 - 5, 1 preferably 0 - 4

B ₂ O ₃ 0-10, preferably:> 4-10

P ₂ O ₅ 0-10, preferably - <Λ

Fe ₂ O ₃ 0 - 5

CeO ₂ 0 - 5

Bi ₂ O ₃ 0 - 3

WO ₃ 0-3

MoO ₃ 0 - 3

and customary refining agents such as SnO ₂ , CeO ₂ , SO ₄ , Cl, As ₂ O ₃ Sb ₂ O ₃ in amounts of 0 - 4 wt .-%.

The glass compositions of the invention are characterized in particular by the fact that the UV edge can be adjusted in a targeted manner by adding suitable UV blockers. Thereby it is e.g. It is also possible to adjust the transmission in the wavelength range around 400 nm in a targeted manner in such a way that the bluish cast, which can occur in the emission of the HID lamps according to the prior art, is reduced.

In the Al-silicate glasses according to the invention, in particular hard glasses, it is possible, by addition of oxides, such as Fe ₂ O ₃ or TiO ₂ or other classic UV blockers, such as Mo, Nb and / or Ce oxide, first to adjust the UV edge similar to that of UV silica glass. Accordingly, the Al-silicate glass according to the invention preferably contains at least one metal oxide selected from the group consisting of TiO ₂ , CeO ₂ , Fe ₂ O ₃ , WoO ₃ , ZrO ₂ , MoO ₃ , Bi ₂ O ₃ , Nb ₂ O ₅ and / or Ta ₂ O ₅ .

Preference can thus - if necessary - targeted influence on the quality of the white light are taken. So, provided that the emission spectrum of the

Discharge body has too much blue shares, on the steepness of the UV edge also targeted a yellow intrinsic color adjustable. This filters too big Blue shares off. The self-yellowing of the blue cast of the burner of the HID lamp is compensated and achieved compared to conventional HID lamp improved white impression.

The effect becomes all the more advantageous if additionally temperature effects are considered. Temperatures between 600 ⁰ C and 850 ⁰ C or more are formed on the inner wall near the burner of an HID lamp, is shifted whereby the UV edge to smaller energies.

According to an advantageous embodiment of the invention, the Al-silicate glass in the range of RT to 700 ⁰ C light, the wavelengths less than or equal to 290 nm substantially completely block. "Substantially complete block" in the context of the invention, that the transmittance of <0.01. Even more advantageously, an Al-Siliaktglas are used, the wavelength nm less than or equal 300 at temperatures of about 600 ⁰ C light, preferably less than or equal 310 nm essentially completely blocked, ie the transmittance is <0.01. In particular, the Al-silicate glass may have a transmittance in the range 0.5-0.91 at about 400 nm.

According to a further embodiment of the invention, the Al-silicate glass is selected such that this at about 400 nm at 600 ⁰ C, a transmittance less than 86% and a Fe ₂ O ₃ content> 10 ppm, preferably> 100 ppm, in particular> 300 ppm having.

By suitable variation of proportions of the UV-blocking component and taking into account the temperature shift, the UV edge can be set arbitrarily. In this way, suitable transmissions at 400 nm can be generated, which positively influence the value depending on the value, the reproduction index CRI and / or the color temperature of a lamp.

The rendering index of a lamp is the so-called Color Rendering Index (CRI). The Color Rendering Index (CRI) describes the white impression of a illuminated area. Depending on how many parts of an optimal emission spectrum, which is characterized by an equal intensity for wavelengths between 380 and 780 nm, are missing or the more inhomogeneous the spectrum is, the objectively worse is the white. The surface then appears more or less gray.

A CRI index of 100 describes a lamp with an optimal emission spectrum, i. an optimal white impression.

As described above, even with the best optimization of fillers of the prior art, the light of high intensity discharge (HID) lamps can still be quite blue-heavy. Currently, lamps with CRI of mostly no more than. 90 distributed. Through the use of the glasses according to the invention the Blaulastigkeit can be reduced by a suitable doping with high temperature resistance, thermal expansion CI2 _{_0/300>} 0 and sufficient UV blocking or be completely compensated for, so that HID lamps having a CRI index> 90, preferably> 95, are obtained.

The invention also provides the use of an al-silicate glass for a lighting device, in particular a metal halide

High-pressure discharge lamp, as has already been described, wherein the Al-silicate glass has one of the compositions described above.

The invention will be described by way of example with reference to figures and exemplary embodiments. Show it:

Figure 1 a, b: an HID lamp with a second body, which forms the outer bulb of the HID lamp; Figure 2: transmission curves for the embodiments A1, A2, A3

(doped alkali-free Al-Silikaltgläser), and Comparative Examples V1 (Ce-doped silica glass) and V2 (undoped Al-silicate glass) at

Room temperature; Figure 3: transmission curves for the embodiments A1, A2, A3, and Comparative Examples V1 and V2 at 600 ° C; Figure 4: transmission curves for the embodiments A4 and A5

(doped alkaline Al-silicate glasses), and Comparative Example V1

(Ce-doped silica glass) each at room temperature and 600 ⁰ C; FIG. 5a, b: transmission data of the glass A2 from FIG. 1 and FIG. 2 in FIG

Compared to the data of a glass with the same base composition A2b at RT (5a) and 600 ⁰ C (5b), wherein the differences in Fβ ₂ θ ₃ content are (A2: ppm 330 A2b: 10 ppm Fe) and Figure 6: Position of the color of a lamp in the ClELab color chart below

Use of pistons a) of the comparative example V1 and b) of the embodiment A2 in each case at 600 ^° C.

FIG. 1 a shows schematically an HID lamp and in FIG. 1 b an alternative embodiment with an feedthrough component, as described, for example, in WO 2004/077490.

In Figure 1a, in addition to the outer bulb 1 and the burner system 2, which may be formed as Al ₂ θ ₃ burner, also shown. The burner system 2 is attached to a nipple 4. The burner system comprises a so-called first body, which forms the discharge space of the burner. The nipple 4 results when the exhaust tube is melted after applying the vacuum, which prevails in the outer bulb. The so-called former fusion point then functions as the upper fixed point of the burner system 2, which has a significantly greater mass in comparison to, for example, a W coil in the case of a halogen lamp, so that a fixation in the outer bulb is advantageous. Furthermore, the feed wires 6 and discharge wires 8 are shown. Although the feed and discharge wires 6, 8 are stiff enough to hold the burner, greater safety and reproducibility in the positioning of the burner but is obtained when an extension 10 of the discharge wire 8 has an anchor at the top of the nipple 4 above.

According to the invention, the outer bulb 1 is formed from an Al-silicate glass. Possible compositions of the Al silicate glass are given in the following tables.

After the outer bulb 1 has been equipped with a burner system, the metal feeders are attached thereto.

The metal leads are included in a feedthrough component, a so-called base plate 50.

Instead of a direct fusion of the outer bulb with a feedthrough wire, the outer bulb is in this case added to the feedthrough wires 68-containing base plate 50 via a frit ring. Thus, the fusion zone is reduced to a minimum, which is predetermined by the thickness of the base plate 50.

In order to avoid stresses between the outer bulb and the base plate as well as in the area of the feedthrough wires, the expansion coefficient α 20/300 of the base plate and the outer bulb is substantially equal to that of the metal of the feedthrough wires. Preferably, the material of the feedthrough wires 6, 8 is one of the following metals or alloys:

tungsten

molybdenum

Niobium metal a kovar alloy and a Molezdenwanov alloy. According to the thermal expansion coefficient α _{20/300 of} these metals, the expansion coefficient of the base plate and the outer bulb is in the range 3.5 <α 20/300 ≤ 5.5. For this reason, the use of quartz glass is not possible. Similarly, the inadequate UV-C blocking is in favor of a multicomponent glass, eg an Al-silicate glass.

The glasses shown in Figs. 2 and 3 have the following compositions and properties:

Table 1 : In Figures 2 and 3, the transmission curves for the embodiment 1, the embodiment 2 and the embodiment 3 and the comparative examples V1 and V2 at room temperature or 600 ⁰ C are given. The samples all have a thickness of 1 mm.

V1 corresponds to Ce-doped silica glass, which can not be used in the new HID lamp concept according to the invention because of the lack of adaptation in the expansion coefficient. The UV edge is favorable (highest wavelength value at which the glass is only up to 1, 0% transmissive: 324 nm), but V1 is still transmissive at 260 nm.

V2 corresponds to a non-UV-blocked Al-silicate glass. Due to the lack of UV blocker (the edge position occurs only through the impurities introduced via the raw materials), V1 is still transmissive at RT as well as at 600 ^° C. at 290 nm.

The embodiments A1, A2 and A3 are significantly better in comparison. At RT, the Ti-leading glasses A1 and A2 are no longer transmissive to 295 or 305 nm. The Ce variant A3 is optically dense even up to 328 nm. At 600 ° C, the glasses A1-A3 are even up to max. 310 nm or even more impermeable. At 260 nm, all variants according to the invention are impermeable to the very harmful UV-C radiation (260 nm).

The glasses A1, A2 and A3 have a comparable or slightly reduced transmission at 400 nm compared to V1. As stated above, however, this can be used selectively if the emission of the burner unit is too blue-heavy. By adding UV-blocking substances to the Al-silicate glass, a transmission in the range from 50 to 91% can therefore be set variably with respect to silica glass at a wavelength of 400 nm.

Transmittances smaller than 50%, however, require too much yellow inherent coloration and thus too large a filter effect. On the other hand, by carefully selecting the raw materials, transmissions at 400 nm can also be generated better than in the prior art (UV-blocked SiO ₂ ). Figures 5a and 5b illustrate the transmission data of the glass A2 of Figure 2 the data of a glass with the same

Basic composition A2b versus. The differences are in the Fe ₂ O ₃ content (A2: 330 ppm Fe ₂ O ₃ , A2b: 10 ppm Fe ₂ O ₃ ). As a result, the edge is steeper compared to the Fe-rich variant at both RT and 600 ° C. There is a higher transmission at 400 nm, but the cut-off or UV edge has remained roughly the same.

An equally favorable UV-edge and so that the transmission curve has both at room temperature as well as at 600 ⁰ C found for subsequent alkaline Al silicate glasses (in wt .-% on oxide) (Working Examples A4 and A5; see also Figure 4). The glass was melted with Fe-poor raw materials, the Fe ₂ O ₃ content is approximately <10 ppm

Table 2: Glass composition for embodiment A 4 in% by weight

SiO ₂ 65.45

Al ₂ O ₃ 21, 97

Na ₂ O 0.51

Li ₂ O 3.72

MgO 0.47

BaO 2.02

ZnO 1, 70

TiO ₂ 2.39

ZrO ₂ 1, 76 alpha 20/300 4.0 ppm / K Tg 690 ⁰ C

Table 3: Glass composition for embodiment A 5 in% by weight SiO ₂ 64.45

Al ₂ O ₃ 21, 97

Na ₂ O 0.51

Li ₂ O 3.72

MgO 0.47

BaO 2.02

ZnO 1, 70

TiO ₂ 3,4

ZrO ₂ 1, 76 alpha 20/300 4.05 ppm / K Tg 685 ° C

The steepness of the transmission curve of embodiment A4 is at 600 ⁰ C approximately comparable to the transmission curve of the embodiment V1. The transmission curve of A5 is even approximately congruent with V1 at 600 ^° C. In comparison with V1, both embodiments additionally have the great advantage of completely blocking the harmful UV-C radiation at 260 nm as well as the thermal expansion matched to lead-through metals.

However, the temperature stability of the compositions according to embodiments 4 and 5 is reduced compared to the compositions according to embodiment 1 to 3. However, the Tg of 690 ⁰ C is still sufficient for the addressed application.

The effect of the transmission of the outer bulb glass on the Farbcharakterisik the entire lamp at an exemplary operating temperature of 600 ⁰ C illustrates Figure 6. The lamp color results from folding the primary emission of the burner with the filter function of the outer bulb. In the so-called ClELab color diagram, differences between the UV-blocked SiO ₂ (comparative example V1) and the exemplary embodiment A3 can be recognized. The embodiment A3 is advantageous in that it shifts the color layer more in the direction of the ideal white point. Expressed in terms of the size of the CIE system (COMMISSION INTERNATIONAL DE L ¹ ECLAIRAGE, see www.cie.co.at/cie), the parameter C (chroma, colourfulness) is reduced by one unit. Advantageously, the CRI (Color rendering index) is hardly changed, but advantageously the color temperature CCT is reduced. All in all, the blue cast of the lamp is reduced by the yellow filter effect of the outer bulb material.

Table 4: CIE color characteristics of bulbs with external bulb V1 or A3. Data acc. CIE standard 13.3-1995

Advantageous embodiments and developments of the invention will become apparent from the dependent claims and from the described embodiments. The examples and attached figures illustrate the present invention without being limited thereto. The above description describes a variety of variations and suggests a number of modification possibilities which will be readily apparent to those skilled in the art without departing from the scope of the appended claims.

Claims

Patent claims:

1. Lighting device - preferably comprising a metal halide high-pressure discharge lamp

1.1. a first body that has a light source,

1.2. a second body enclosing the first body, wherein

1.3. the second body consists of an Al silicate glass, and where

1.4. the Al silicate glass 1.4.1. a T ₉ > 600 ⁰ C, preferably > 650 ⁰ C, very preferred

>700°C, particularly preferably >750 ^° C and 1.4.2. a thermal expansion coefficient α (20 ° - 300 ° C) > 0, preferably in the range 3 < α (20 ° - 300 ° C) < 6, particularly preferably 3.5 < α (20 ° - ^{300 °} C) < 5, 5 has.

2. Lighting device according to claim 1, wherein the lamp is composed of a plate containing the power feedthrough and a piston.

3. Lighting device according to one of claims 1 or 2, wherein the Al-silicate glass has the following composition (% by weight based on oxide):

_SiO2 50 - 66

_B2O30-5.5 _{_}

AI ₂ O ₃ 10 - 25

MgO 0 - 7

CaO 0 - 14

SrO 0 - 8

BaO 0 - 18

_P2O50-2 _{_}

ZrO ₂ 0 - 3 _TiO2 0-5

_CeO2 0-5

MoO ₃ 0-5

_Fe2O30-5 _{_}

WO ₃ 0-5

_Bi2O30-5 _{_}

4. Lighting device according to one of claims 1 or 2, wherein the aluminum

Silicate glass has the following components:

_SiO2 50-66

_B2O3 _0-5.5

AI ₂ O ₃ 13-25

MgO 0-7

CaO 5-14

SrO 0-8

BaO 6-18

_P2O50-2 _{_}

_ZrO2 0-3

_TiO2 0-5

_CeO2 0-5

MoO ₃ 0-5

_Fe2O30-5 _{_}

WO ₃ 0-5

_Bi2O30-5 _{_}

5. Lighting device according to one of claims 1 or 2, wherein the Al-silicate glass has the following components:

_SiO2 50 - 66

B ₂ O ₃ 0 - <0.5

AI ₂ O ₃ 14-25 MgO 0-7

CaO 5-14

SrO 0-8

BaO 6-18

_P2O50-2 _{_}

_ZrO2 0-3

6. Lighting device according to one of claims 1 or 2, wherein the aluminum

Silicate glass has the following components:

_SiO2 58-62

_B2O3 _0-5.5

AI ₂ O ₃ 13.5-17.5

MgO 0-7

CaO 5.5-14

SrO 0-8

BaO 6-10

_ZrO2 0-2

7. Lighting device according to one of claims 1 or 2, wherein the second body is based on an Al-silicate glass which contains the following components in% by weight:

_SiO2 50-70

AI ₂ O ₃ 17-27

_Li2O0-5

Na ₂ O 0-5

_K2O0-5

MgO 0-5

ZnO 0-5

_TiO2 0-5

_ZrO2 0-5 Ta ₂ O ₅ 0-5

BaO 0-5

SrO 0-5

_P2O50-5 _{_}

_Fe2O30-5 _{_}

_CeO2 0-5

_Bi2O30-5 _{_}

WO ₃ 0-5

MoO ₃ 0-5

as well as common refining agents, for example SnO ₂ , CeO ₂ , SO ₄ , Cl, As ₂ O ₃ Sb ₂ O ₃ in amounts of 0-4% by weight.

8. Lighting device according to one of claims 1 or 2, wherein the second body is based on an Al-silicate glass, which has the following

Components in wt.% contains:

SiO ₂ 35 - 70, especially 35 - 60

Al ₂ O ₃ 14-40, especially 16.5 - 40 MgO 0 - 20, preferably 4 - 20, especially 6-20

ZnO 0-15, preferably 0-9, especially 0-4

TiO ₂ 0-10, preferably 1 -10

ZrO ₂ 0-10, preferably 1 -10

Ta ₂ O ₅ 0 - 8, preferably 0-2 BaO 0-10, preferably 0-8

CaO 0 - <8, preferably 0-5, especially <0.1

SrO 0-5, preferably 0-4

B ₂ O ₃ 0-10, preferably > 4 - 10

P ₂ O ₅ 0-10, preferably <4 Fe ₂ O ₃ 0-5

_CeO2 0-5

_Bi2O30-3 _{_} MoO ₃ 0 - 3

as well as common refining agents, for example SnO ₂ , CeO ₂ , SO ₄ , Cl, As ₂ O ₃ Sb ₂ O ₃ in amounts of 0 - 4% by weight.

9. Lighting device according to at least one of the preceding claims 1 to 8, wherein the Al-silicate glass is at least one metal oxide selected from the group consisting of TiO ₂ , CeO ₂ , Fe ₂ O ₃ , WO _3, ZrO ₂ , MoO ₃ , Bi ₂ O ₃ , Nb ₂ O ₅ and/or Ta ₂ O ₅ .

10. Lighting device according to claim 9, wherein at least one metal oxide is contained in an amount of >0 to 8% by weight, preferably >0 to 6% by weight, particularly preferably with a maximum of 5% by weight.

11. Lighting device according to at least one of the preceding claims 1 to 10, wherein the Al-silicate glass contains at least 0.5% by weight of TiO ₂ CeO ₂ , Fe ₂ O ₃ , WO ₃ , ZrO ₂ , MoO ₃ , Bi ₂ O ₃ , Nb ₂ O ₅ and/or Ta ₂ O ₅ contains.

12. Lighting device according to at least one of the preceding

Claims 1 to 11, wherein the Al-silicate glass contains Sb ₂ O ₃ and As ₂ O ₃ in an amount of at most 1% by weight.

13. Lighting device according to at least one of the preceding claims 1 to 12, wherein the Al silicate glass O -1 wt .-% Cl and / or 0-3

Weight % SO ₃ contains.

14. Lighting device according to at least one of the preceding claims 3 to 6, wherein the Al-silicate glass has an alkaline earth content of 11.6 to 29.0% by weight.

15. Lighting device according to claim 5, wherein the Al-silicate glass contains more than 10% by weight of BaO.

16. Lighting device according to claim 5, wherein the Al-silicate glass contains at least 0.5% by weight of MgO.

17. Lighting device according to at least one of the preceding claims 1 to 16, wherein the Al-silicate glass contains at least 0.005% by weight of CeO ₂ .

18. Lighting device according to at least one of the preceding claims 1 to 17, wherein the first body consists of silica glass or translucent ceramic.

19. Lighting device according to at least one of the preceding

Claims 1 to 18, wherein the second body represents an outer bulb of a metal halide high-intensity discharge lamp.

20. Lighting device according to at least one of the preceding claims 1 to 19, wherein the second body is an explosion shroud

Metal halide high pressure discharge lamp.

21. Lighting device according to at least one of the preceding claims 1 to 19, wherein the lighting device comprises a power supply made of a metal.

22. Lighting device according to claim 21, wherein the metal comprises one or more of the following materials:

Tungsten Molybdenum

Niobium metal a Kovar alloy or a Molekdenwanar alloy.

23. Lighting device according to at least one of the preceding claims 1 to 22, wherein the lighting device comprises a feedthrough component which is attached, in particular attached, to the second body and through which a power supply for the lighting device is passed.

24. Lighting device according to claim 23, wherein the feedthrough component has the shape of a plate.

25. Lighting device according to claim 23 or 24, wherein the lead-through component has at least one area through which at least one power supply, in particular in the form of a metal part, is passed and the lead-through component at least in the

Area in which the metal part is passed has a material with a thermal expansion coefficient that essentially corresponds to the thermal expansion coefficient of the metal part.

26. Lighting device according to claim 25, wherein the metal part comprises one or more of the following materials:

tungsten

molybdenum

Niobium metal a Kovar alloy or a Molekdenwanar alloy.

27. Lighting device according to at least one of the preceding

Claims 1 to 26, wherein the first body represents a discharge space and the discharge space of a meterable filling, in particular

Discharge substances, such as mercury and/or rare earth ions and/or halogens and/or xenon, are filled.

28. Lighting device according to claim 26 or 27, wherein the discharge space comprises a filling gas and the filling gas is under a pressure of up to 200 bar or more than 200 bar.

29. Lighting device according to at least one of the preceding claims 1 to 28, wherein the Al-silicate glass essentially completely blocks light in the range from RT to 700 ⁰ C with a wavelength of less than or equal to 290 nm (transmittance <0.01).

30. Lighting device according to at least one of the preceding claims 1 to 29, wherein the Al-silica glass at temperatures around 600 ⁰ C essentially completely blocks light with a wavelength of less than or equal to 300 nm, preferably less than or equal to 310 nm (transmittance <0.01).

31. Lighting device according to at least one of the preceding claims 1 to 30, wherein the Al-silicate glass has a transmittance in the range 0.5 - 0.91 at approximately 400 nm.

32. Lighting device according to at least one of the preceding

Claims 1 to 31, wherein the Al silicate glass has a transmittance of approximately 400 nm at 600 ⁰ C of less than 86% and an Fβ ₂ θ ₃ content > 10 ppm, preferably > 100 ppm, in particular > 300 ppm.

33. Use of an Al-silicate glass for a lighting device, in particular a metal halide high-pressure discharge lamp, the Al-silicate glass having a composition according to one of claims 3 to 17.

34. Use of an Al-silicate glass according to claim 33, characterized in that the lighting device comprises: 1.1. a first body that has a light source,

1.2. a second body enclosing the first body, wherein

1.3. the second body is made of Al-silicate glass.

35. Use of an Al-silicate glass according to claim 33 or 34, characterized in that the Al-silicate glass has a T ₉ > 600 ° C, preferably >

650 ⁰ C, very preferably > 700 ⁰ C, particularly preferably > 750 ° C and a thermal expansion coefficient α (20 ° - 300 ⁰ C) > 0, preferably in the range 3 < α (20 ° - 300 ° C) < 6, particularly preferably 3.5 <α (20° - 300 ⁰ C) <5.5.

36. Use of an Al-silicate glass according to one of claims 33 to 35 for a lighting device according to one of claims 2 or 18 to 32.