EP2009668A1 - Discharge lamp socketed on one side - Google Patents

Abstract

The discharge lamp (10) has a blow pipe (40) and a socket (22) provided for mechanical and electrical connection of the lamp with a lamp holder. The blow pipe has a rolling seal (42) that defines a proximal area (11) of the lamp, where the rolling seal is tuned to the socket along a drawing axis (100). The socket forms a plane (E1) and another plane (E2) that is arranged perpendicular to the drawing axis. Contact pins (50, 51) are respectively arranged on the planes, so that the contact pins are arranged and set with respect to each other.

Description

The invention relates to a discharge lamp, in particular a discharge lamp capped on one side, comprising a burner and a base in which the burner is held, for mechanical and electrical connection of the discharge lamp to a socket, wherein the burner along a preferred axis facing the first, a first In the proximal region of the lamp defining pinch seal, a burner chamber and the first pinch seal with respect to the burner chamber opposite second, defining a distal portion of the lamp pinch seal, wherein each lead leads through the first pinch seal and the second pinch seal and wherein a first supply line in a first contact pin and a second lead terminates in a second contact pin on an outside of the lamp.

Such a lamp is for example from the DE 102 33 073 B3 known. Such discharge lamps do not start when they are warm. Particularly affected by the problem of not starting in the warm state (with the standard ballast) are metal halide lamps. After switching off these lamps require up to three minutes of cooling time before they can be re-ignited. By means of higher ignition voltages, however, the lamps can also be ignited in the warm state. At high ignition voltages but (about 10 kV instead of 3 to 5 kV metal halide lamps) can over the creepage paths, as are known in lamps according to the prior art, flashovers, ie electrical discharges occur. That is, lamps according to the prior art can be ignited in principle only in the cooled state.

The object of the present invention is therefore to propose an arrangement that brings the discharge lamps in the warm state immediately to ignite, with electrical flashovers are to be avoided by high ignition voltages.

This object is achieved by a discharge lamp according to claim 1. Advantageous developments are specified in the subclaims.

In particular, the object is achieved by a single-ended discharge lamp, comprising a burner and a base in which the burner is held, for the mechanical and electrical connection of the discharge lamp with a socket, wherein the burner along a preferred axis facing the base first, a proximal Area of the lamp-defining pinch seal, a burner chamber and one of the first pinch seal with respect to the burner chamber opposite second, defining a distal portion of the lamp pinch seal, wherein each lead through the first pinch seal and the second pinch seal, wherein a first supply line in a first contact pin and a second lead terminates in a second contact pin on an outer side of the lamp, wherein the base is formed supporting the contact pins and forms a substantially perpendicular to the preferred axis arranged first level and second level u nd wherein the first contact pin is arranged on the first level and the second contact pin on the second level, so that the contact pins are offset from one another.

An essential point of the invention is that by the staggered arrangement of the pins, to which the corresponding lines are connected to and away from the burner, and the consequent design of the lamp, moreover, the contacts are spaced apart such that flashovers do not occur can be used even if high ignition voltage is used. The normal distance between the contacts of a single-ended discharge lamp is approx. 5 mm. A prescribed creepage distance of 11 mm applies at 10 kV only at a voltage frequency of up to 30 kHz. At higher frequencies higher distances are required. At the new Socket or lamp base, however, the distance is more than 22 mm (the IEC 60598-1, 2003 edition, Table 11.3 prescribes a minimum creepage distance of 11 mm at a voltage of 10 kV). Thus, a warm start of the lamps according to the invention is possible.

In each case a supply line is connected to one of the contact pins, so that the leads are led out via the contact pins to the outside of the lamp. The one contact pin is connected to the first supply line, while the other contact pin is connected to the second supply line.

In a first embodiment, the lamp further comprises a reflector which is rotationally symmetrical about the preferred axis and preferably encloses the burner together with a cover and defines a lamp interior. Preferably, the reflector tapers at the proximal region opposite the cover to a neck region. The base described above is then designed such that it adjoins the neck region. Also reflector lamps without cover, d. H. z. B. without lens, can be provided here.

The socket design according to the invention can also be used in non-reflector lamps. Lamps without a reflector have around the preferred axis rotationally symmetrical outer bulb (glass bulb), which is designed such that it at least partially, preferably completely encloses a lamp interior. Also, electrodeless lamps (no inner electrode) can be equipped according to the invention.

In a further embodiment, the base is designed such that due to the mutually offset pins possible creepage paths of the current between the power supply lines (leads) and contacts in socket and socket to prevent flashovers are at least 22 mm, so that the discharge lamp at high voltages, especially at ignition voltages up to 10 kV and greater than 30 kHz, is operable. If the creepage distances are at least 11 mm, the lamp can also be operated with an ignition voltage of 10 kV and less than or equal to 30 kHz.

That is, by the displacement of the contact pins, the creepage distances are extended (compared to conventional lamps), so as to ensure the safe handling of the lamp. The creepage paths that are to be considered here are mainly between the contacts inside and on the outside of the socket.

In a further embodiment, the base comprises a base member having a first diameter from which protrudes an attachment element having a second diameter toward the proximal region, wherein the first diameter is greater than the second diameter and wherein the base member is the second plane and the Essay element forms the first level. Base element and attachment element are therefore preferably arranged one above the other as two cylindrical components with different diameters. Thus, the offset of the pins and the extension of creepage paths are ensured in a simple manner.

An embodiment provides that the base is rotationally symmetrical about the preferred axis, wherein the attachment element protrudes substantially centrally from the base element. The socket looks so z. B. as a two-stage tower over which the pins are easily positioned with the lines. The attachment element is designed such that it can be received in a recess of the corresponding socket together with the contact pin and serves as a guide element when fixing the lamp.

Preferably, the first contact pin is arranged aligned on the easy axis, wherein the preferential axis preferably forms a central axis of the lamp. At the first contact pin, the first supply line is connected to a first electrode in the burner chamber. Now, if the contact pin centrally aligned, the supply line also passes through the lamp centrally and is connected to the centrally located burner. In the arrangement of the burner in the discharge lamp is anyway to make sure that it is fixed as centrally as possible in the lamp. This is the only way to guarantee even and efficient radiation of the light through the reflector.

According to a preferred aspect of the present invention, the base has a receiving area into which the first pinch seal (base pinch seal) for Holding the burner in the socket is at least partially receivable. This special recording area, the z. B. may be formed as a bore, allows the stable storage of the burner assembly in the lamp due to the leadership function. If the receiving region is rotationally symmetrical about the preferred axis, this essentially ensures the centered arrangement of the burner in the lamp. The preferred axis would then correspond to a central axis of the lamp, so that the receiving area is actually centered in the lamp. A proximal end of the receiving area serves as a stop element for the burner assembly, so that the pinch seal can be accommodated in the receiving area in a defined manner and the burner can thus be arranged at the focal point of the reflector with acceptable tolerances.

In one embodiment, the receiving area is designed in such a way that it accommodates both a square-shaped and also a cross-sectionally circular (or even oval) pinch seal. In the Quetschdichtungen the power supply lines are pressed so that the burner chamber is sealed from the environment. The receiving area has various shapes which engage with each other such that different pinch seal shapes can be introduced into the receiving area. Preferably, the receiving area is designed such that the burner via at least one pinch seal in this against rotation and stable storage, so that the required centered arrangement of the burner is always maintained. That is, the receiving area is formed with an anti-rotation, that the burner in this at least one pinch seal against rotation and stable storable or stored.

Furthermore, the lamp has a tubular enclosure which at least partially surrounds the burner, as burst protection and for blocking UV radiation in order to avoid sodium loss. The tubular shield may for example be made of quartz or glass (toughened glass).

In one embodiment, the shield is connected to the burner via a spring clip, wherein the spring clip is designed to engage in the first and / or second pinch seal for holding the shield. The spring clip is z. B. circumferentially arranged in the interior of the shield and is supported against these from (is therefore in the shield strained). If the clip then engages in one of the pinch seals, the shield is securely positioned in the lamp interior. Preferably, the spring clip is disposed at a distal end of the shield and adapted to engage (in a groove or protrusion) in the second pinch seal (cover pinch seal).

An embodiment provides that the spring clip is designed such that it holds the shield, in particular under bias to a particular circular projection on a pointing in the lamp interior bottom portion of the base of the discharge lamp. In this case, the projection is formed such that the shield is centered in the lamp interior to the preferred axis can be accommodated. That is, the projection takes over the centering of the shield and guides it, so that the shield is locked or locked in a suitable position. The height of the protrusion influences the creepage distance.

The spring clip has z. B. two feet, which are used as projections in the respective, ie z. B. can engage in the second pinch seal to allow the secure hold of shield and burner. In addition, the clip is formed with a defined height, with which he z the shield. B. enveloped from the inside. In this respect, the shield is aligned with the preferred axis of the lamp and coaxially aligned around them. The spring clip is preferably formed of metal, in particular of spring steel.

Instead of spring mounting, the shield can also be fixed in the interior of the lamp via cement or silicone. When using a spring clip, cement is only needed to connect the base to the reflector.

A development according to the invention provides that the reflector or the outer bulb and the base are formed integrally with one another (eg completely made of glass). Cementing between base and reflector or outer bulb is then no longer necessary.

It is also possible for the reflector or outer bulb and the base to be hermetically connected to one another. The attachment of the base on the reflector or on the outer bulb is then carried out with a connecting material with high electrical resistance, z. As cement, cement, glass frit, etc., so that the two components are hermetically connected or sintered. Alternatively, it is possible to provide a reflector or outer bulb together with base in one piece of glass.

The shield can be formed shortened in the region of the base due to the new design of the lamp, which has no negative effects in connection with the sodium loss described above. Reducing the length of the shield allows the extension of the creepage paths between the contacts on the inside and the outside of the socket without increasing the absolute length of the lamp. So it is u. a. also possible to provide the staggered arrangement of the contact pins.

- Fig. 1

eine Ausführungsform der erfindungsgemäßen Entladungslampe im Schnitt;

- Fig. 2

die Entladungslampe gemäß Fig. 1 in einer Seitenansicht;

- Fig. 3

die Entladungslampe gemäß Fig. 2 im Schnitt entlang der Linie III-III aus Fig. 2;

- Fig. 4

die Entladungslampe gemäß Fig. 1 in einer weiteren Seitenansicht;

- Fig. 5

die Entladungslampe gemäß Fig. 4 im Schnitt entlang der Linie V-V aus Fig. 4;

- Fig. 6

eine weitere Ausführungsform der erfindungsgemäßen Entladungslampe;

- Fig. 7

eine weitere Ausführungsform der erfindungsgemäßen Entladungslampe;

- Fig. 8

die Darstellung eines Sockels für die erfindungsgemäße Entladungslampe;

- Fig. 9

die Innenansicht des Sockels gemäß Fig. 8;

- Fig. 10

eine Entladungslampe nach dem Stand der Technik.

The invention will be described with reference to embodiments, which are explained in more detail with reference to the figures. Hereby show:

- Fig. 1

an embodiment of the discharge lamp according to the invention in section;

- Fig. 2

the discharge lamp according to Fig. 1 in a side view;

- Fig. 3

the discharge lamp according to Fig. 2 in section along the line III-III Fig. 2 ;

- Fig. 4

the discharge lamp according to Fig. 1 in a further side view;

- Fig. 5

the discharge lamp according to Fig. 4 in section along the line VV Fig. 4 ;

- Fig. 6

a further embodiment of the discharge lamp according to the invention;

- Fig. 7

a further embodiment of the discharge lamp according to the invention;

- Fig. 8

the representation of a base for the discharge lamp according to the invention;

- Fig. 9

the inside view of the base according to Fig. 8 ;

- Fig. 10

a discharge lamp according to the prior art.

In the following description, the same reference numerals are used for the same and like parts.

In Fig. 1 is an embodiment of a discharge lamp 10 according to the invention, here a reflector lamp, represented by a sectional view. The discharge lamp 10 initially comprises a rotationally symmetrical reflector 20 which, together with a cover 27, which may be formed, for example, as a lens, encloses a lamp interior 30 at a distal region 12 of the lamp 10 (which is hermetically sealed). The lens 27 may, for. B. with an aluminum ring 28 which is guided on the outside of the reflector 20, be secured (see. Fig. 3 ). At its end facing away from the cover 27, a proximal region 11 of the lamp 10, the reflector 20 tapers and forms a neck region 21. On the neck portion 21, a base 22 is placed or placed, are guided by the leads 52, 53 a, 53 b. The leads 52, 53a, 53b are recessed outside of the socket 22 in contact pins 50, 51, a first contact pin 50 and a second contact pin 51. The socket 22 allows a mechanical and electrical connection of the discharge lamp 10 with a corresponding socket.

The contact pins are shown here by way of example. It can also be used cylindrical pins. The pins are made of a variety of metals ausbildbar, also alloyed or tempered pins can be provided.

The reflector may have a smooth surface in the interior or - as shown here - be formed with facets for a specific light / color mixture. A coating with wavelength-selective reflection layer can be provided, possibly IRtransparent. The reflector may also have a metal coating, for. As aluminum, silver or gold.

In the lamp interior 30, a burner 40 is arranged on a preferred axis 100 of the lamp 10, which runs here as a central axis of the lamp. The burner 40 has two pinch seals at the end (base pinch seal 42 at the proximal region of the lamp and cover pinch seal 43 at the distal region of the lamp) and a burner chamber 41 between them. Burner 40 and pinch seals 42, 43 form z. B. from an arc tube.

Arranged around the burner 40 is a tubular shield 60 which encloses the burner 40 in such a way that it protrudes beyond the envelope-shaped shielding 60 at its end only via its pinch seals 42, 43. The tubular shield is in the neck region 21 of the reflector 20 via a pointing into the lamp interior projection (dome) 26 at a bottom portion 25 of the base 22, wherein the projection 26 z. B. circular and coaxial about the easy axis 100 is formed running. The tubular shield 60 may for example be formed of quartz or glass and serves on the one hand as burst protection and to avoid sodium loss. The attachment of the shield will be described below in more detail.

The first lead 52 leads from the first contact pin 50, the push contact pin, at the proximal region 11 of the lamp through the proximal pinch seal 42 to an electrode in the burner chamber 41 (the electrode is not shown). Via a likewise arranged in the burner chamber 41 second electrode (not shown) performs the second lead 53a further on the distal pinch seal 43 from the pinch seal out and is guided as a bent wire to the second lead 53b. The second lead 53b is guided in a shielding tube 70 and finally terminates in the other, the second contact pin, the side contact pin 51. The shielding tube 70 with the second lead 53b is led outside the shield 60 for the torch 40. The two second leads 53a, 53b are connected together at their contact point, z. B. crimped, soldered or welded. Incidentally, the leads 52, 53b are also crimped, soldered or welded to the contact pins or connected in a similar manner.

The base 22 is here stepped and rotationally symmetrical about the preferred axis 100 is formed. Tiered means that the base 22 in the neck region 21 of the reflector 20 has a base element 23, from which an attachment element 24 projects in the direction of the proximal region 11 of the lamp 10. As a result, the base 22 is formed with two planes E1, E2 arranged substantially perpendicular to the preferred axis, one of the contact pins in each case being arranged on each of the planes. The feed lines connected to the contact pins 50, 51 then run through the lamp 10, starting from the contact pins, as described above.

To insert the lamp 10 into a socket, the socket 22 is inserted with the contacts 50, 51 in grooves or the like recesses of the socket and rotated so that both the mechanical and the electrical connection is generated via the contact pins 50, 51. The contact pins 50, 51 are thus z. B. similar to a bayonet closure connected to the socket.

Is the upper contact pin, so the push contact 50, on the easy axis 100 is central, d. H. arranged centrally, this (possibly together with the attachment element) serves as a guide when screwing the lamp into the socket. The attachment element 24 is therefore designed such that it can be received in a recess of the socket together with the first contact pin. The side contact 51 is preferably designed such that it z. B. can engage in a longitudinal groove of the socket and is connected by the rotation of the lamp so with the socket that the lamp 10 is fixed in the socket, as soon as the side contact pin 51 reaches an end portion of the longitudinal groove.

The attachment element 24 of the base 22 does not necessarily have to be arranged rotationally symmetrically on the base element 23. An eccentric arrangement would be possible. Then in the version two longitudinal grooves for the two contact pins (or for the attachment element) should be provided so that both pins come by twisting after passing through the longitudinal grooves in an end region with the socket in such a way that the lamp in the socket is fixed. If necessary, then a centering pin could be arranged on the base and for engaging in the socket as Be guide formed, that the insertion of the lamp and its fixation in the socket can be facilitated.

The base 22 has, in this embodiment, likewise rotationally symmetrical about the preferred axis 100, a receiving area 29, which is designed for at least partially receiving the proximal pinch seal 42. The receiving area 29 is here z. B. formed as a bore and allows centered with respect to the reflector 20 storage of the burner 40 with the pinch seals. This is necessary to achieve the most efficient light emission with the likewise rotationally symmetrical reflector 20.

The shield 60 is secured in the embodiment shown by means of a spring clip 80 to the distal pinch seal 43. By means of the spring clip 80 burner 40 and tubular shield 60 are set against each other. The spring clip 80 is arranged here at a distal end of the shield and has z. B. several fastening tabs, which are provided for abutment with the tubular shield 60. The fastening tabs rest on the tubular shielding under predetermined pretensioning and engage in the distal pinch seal 43 via feet. The fastening tabs thus have a dual function, namely to align the tubular shield 60 parallel to the preferred axis 100 and to lock the tubular shield on the pinch seal 43.

The projection 26 serves - as already explained above - the centering of the shield 60, since the shield surrounds the projection, it engages around. This allows guidance and stabilization of the shield in the lamp 10.

Socket and shielding tubes are z. B. of steatite ceramic (MgO.SiO ₂ ), while the tubular shield can be formed of quartz or toughened glass. The base may also be formed of glass.

The lamp 10 according to the invention is intended for a warm start at about 10 kV, that is, the lamp should also be able to be ignited in the warm state, for which the high ignition voltage is necessary. In the area of creeks of the stream could especially at these high ignition voltages unwanted discharges, ie arcing occur. Therefore, the creepage distances must be as long as possible. However, the lamp itself should not be made larger in size.

The inventive design of the lamp 10 with the stepped base 22 allows the reduction of the length of the tubular shield 60. The stepped base 22 and the very small dimensions of the pinch seals 42, 43 allow the staggered arrangement of the contact pins 50, 51. The push contact pin ( first contact pin) 50 is disposed on the cap member 24, while the side contact pin (second contact pin) 51 is disposed on the base member 23. The axial distance f between the levels of the two planes E1, E2 of the base 22 and thus between the contact pins corresponds in this embodiment, the length reduction of the tubular shield 60. Due to this axial distance, the length of the second lead 53b can also be reduced. The radial distance r between the contact pins is determined by the lamp / torch dimensions. The outer bulb, so the shield is decisive. The distance between the two planes must be increased as the distance between the contact pins is reduced to reach the minimum creepage distance of 22 mm.

The reduction of the length of the tubular shield has no influence on the sodium loss. Due to the socket design and mounting structure of the tubular shield, the UV radiation emitted by the arc tube is prevented from reaching the socket-side leads.

The base member 23 of the base 22 has a diameter such that a connection between the neck portion 21 of the reflector 20 and the base 22 is possible. The attachment of the base 22 on the neck portion 21 is made with a high electrical resistance bonding material, e.g. As cement, cement, glass frit, etc., so that the two components are hermetically connected or sintered. Alternatively, it is possible to provide a reflector with base in one piece of glass.

The height of the axial distance between the two levels is important to a minimum length for any creepage path of the flow between an inside and outside to get the socket. This is the only way to avoid unwanted discharges, ie rollovers.

The neck portion 21 of the reflector 20 also has a reduced height, whereby the overall height of the lamps according to the prior art can be maintained.

Kriechweg 1:

zwischen dem Push-Kontakt und dem Seitenkontakt auf der Außenseite des Sockels (e + f),

Kriechweg 2:

zwischen dem Push-Kontakt und dem Seitenkontakt im Inneren des Sockels (e + g + h),

mit

e =

radialer Abstand zwischen den Kontaktstiften, ausgehend von den jeweiligen einander zugewandten Seiten,

r =

radialer Abstand zwischen den Kontaktstiften, ausgehend von deren zentralen Achsen,

f =

axialer Abstand zwischen der ersten Ebene des Aufsatz-Elements und der zweiten Ebene des Basiselements,

g =

axiale Länge (Höhe) des kreisförmigen Vorsprungs bzw. der kreisförmigen Aufnahme für den Hüllkolben bzw. der Abschirmung am Sockelboden,

h =

axialer Abstand vom distalen Ende der proximalen Quetschdichtung und der Höhe der kreisförmigen Aufnahme für den Hüllkolben am Sockelboden.

Essentially, two critical paths appear in or on the lamp as leakage paths for the current:

Creepage 1:

between the push contact and the side contact on the outside of the base (e + f),

Creepage 2:

between the push contact and the side contact inside the socket (e + g + h),

With

e =

radial distance between the contact pins, starting from the respective sides facing each other,

r =

radial distance between the pins, starting from their central axes,

f =

axial distance between the first plane of the attachment element and the second plane of the base element,

g =

axial length (height) of the circular projection or the circular receptacle for the outer bulb or the shield on the base base,

h =

axial distance from the distal end of the proximal pinch seal and the height of the circular receptacle for the outer bulb at the base of the socket.

Here, in particular, the sizes f and h are very important to meet the Kriechwegerfordernisse greater than or equal to 22 mm, d. H. e + f ≥ 22mm and also e + g + h ≥ 22mm.

Fig. 2 shows the discharge lamp 10 according to the invention Fig. 1 in a side view, but rotated by 90 °. With Fig. 3 is the discharge lamp 10 in section along from the line III-III Fig. 2 shown. The discharge lamp essentially corresponds to the one in Fig. 1 shown, however, the lens 27 here with the above-described aluminum ring 28, which is guided on the outside of the reflector 20, be attached.

Fig. 4 shows the discharge lamp according to Fig. 1 in another view, rotated 180 °. Fig. 5 shows the discharge lamp according to Fig. 4 in section along the line VV Fig. 4 , In Fig. 5 Therefore, the side contact pin 51 is not visible.

Fig. 6 shows a further embodiment of the discharge lamp according to the invention, wherein instead of a reflector, an outer bulb 19 is provided. The warm-start discharge lamp is designed here with a ceramic burner (eg PCA burner) without shielding (enveloping pistons).

With Fig. 7 a quartz burner with the necessary shielding 60 is shown.

Both lamps have a placed on the outer bulb base 22, which - as described with the other embodiments - is formed in two stages and the two levels E1 and E2 has. At the discharge lamps after Fig. 6 or. Fig. 7 outer bulb 19 and base 22 are hermetically connected. The pinch seals are designed similar to the other embodiments, wherein the proximal pinch seal is mounted in a receiving region 29. Incidentally, the courses of the supply lines 52, 53a, 53b are provided substantially in accordance with the other embodiments.

With Fig. 8 a socket 22 for the discharge lamp 10 according to the invention is shown. The inside view of the base according to Fig. 8 (ie view from the base member 23 inwards) is with Fig. 9 shown.

As already with Fig. 1 described, the base 22 is formed here as a rotationally symmetrical part and has two recesses to receive the contact pins 50, 51 and to lead the leads 52, 53a in the lamp interior. The push contact pin (first contact pin) 50 is placed on the cap member 24 while the side contact pin (second contact pin) 51 is positioned on the base member 23.

Looking into the socket interior ( Fig. 9 ), the recording for the shield can be seen. Socket 22 and reflector 20 are hermetically connected. In particular, here the receiving area 29 is formed as a bore and allows centered with respect to the reflector 20 storage of the burner 40 by means of Quetschdichtungen (at least with the aid of the proximal pinch seal). This is necessary to achieve the most efficient light emission. Further, an anti-rotation 90 is provided, so that the base remains on the reflector or the outer bulb in its position.

The receiving region 29 is designed such that both pinch seals with a round, in particular oval or circular cross section and with a rectangular or square cross section can be accommodated.

Fig. 10 shows a discharge lamp 10 'as known in the art. Shown here are the side by side on a plane with respect to the easy axis arranged contact pins 50 ', 51'. Further, the tubular cover 60 'extending through the entire length of the lamp is shown. In this embodiment, the creepage paths are designed unfavorable for the current.

It should be noted that with the lamp according to the invention and the offset of the contact pins it is possible to design creepage paths in the discharge lamp for the current such that unwanted discharges do not occur along the critical regions, even if high ignition voltages are applied. With these high ignition voltages, the lamps can be ignited even when warm.

LIST OF REFERENCE NUMBERS

10

discharge lamp

11

Proximal area

12

Distal area

19

outer envelope

20

reflector

21

neck

22

base

23

base element

24

Top mounting element

25

Pedestal floor, floor area

26

head Start

27

cover

28

aluminum ring

29

reception area

30

Lamp interior

40

burner

41

burner chamber

42

First or proximal pinch seal

43

Second or distal pinch seal

50

First contact pin, push contact (pen)

51

Second contact pin, side contact (pin)

52

First supply line

53a, 53b

Second supply line

60

Sheath-shaped shielding

70

shielding tube

80

spring clip

90

Anti-twist device (base)

100

Central axis

f, g, h

Axial distances

e, r

Radial distances

E1, E2

levels

10 '

Reflector lamp (prior art)

50 '

First contact pin (prior art)

51 '

Second contact pin (prior art)

60 '

Sheath-shaped shielding (prior art)

Claims (22)

Single ended discharge lamp comprising
a burner (40) and a base (22) in which the burner (40) is held, for mechanical and electrical connection of the discharge lamp (10) with a socket, wherein the burner (40) along a preferred axis (100) one of Socket (22) facing first, a proximal portion (11) of the lamp defining pinch seal (42), a burner chamber (41) and one of the first pinch seal with respect to the burner chamber (41) opposite second, a distal portion (12) of the lamp having a defining pinch seal (43),
wherein in each case feed lines (52, 53a, 53b) are guided through the first pinch seal (42) and through the second pinch seal (43),
wherein a first lead (52) in a first contact pin (50) and a second lead (53a, 53b) in a second contact pin (51) terminate on an outside of the lamp,
the base (22) being designed to bear the contact pins and to form a first plane (E1) and a second plane (E2) arranged substantially perpendicular to the preferred axis (100),
wherein the first contact pin (50) on the first plane (E1) and the second contact pin (51) on the second plane (E2) is arranged so that the contact pins are offset from one another. Single-ended discharge lamp according to claim 1,
characterized in that
the lamp furthermore comprises a reflector which is rotationally symmetrical about the preferred axis (100) and preferably together with a cover (27) surrounds the burner (40) and defines a lamp interior (30). Single-ended discharge lamp according to claim 1 or 2,
characterized in that
the reflector (20) on the cover (27) opposite the proximal region (11) tapers to a neck region (21). Single-ended discharge lamp according to one of the preceding claims, in particular according to claim 1,
characterized in that
the lamp comprises an outer bulb (19) which is preferably rotationally symmetrical about the preferred axis (100) and which is designed such that it encloses a lamp interior (30) at least partially, preferably completely. Single-ended discharge lamp according to one of the preceding claims,
characterized in that
the base (22) is designed in such a way that owing to the contact pins (50, 51) arranged offset from one another, leakage paths of the current between the leads and contacts in the socket (22) and socket to prevent flashovers are at least 22 mm, so that the discharge lamp ( 10) at high voltages, in particular at an ignition voltage of 10 kV and greater than 30 kHz, is operable. Single-ended discharge lamp according to one of the preceding claims, in particular according to one of claims 1 to 4,
characterized in that
the base (22) is designed such that due to the mutually offset contact pins (50, 51) creepage paths of the current between the leads and contacts in socket (22) and socket to avoid Flashovers at least 11 mm, so that the discharge lamp (10) at high voltages, in particular at an ignition voltage of 10 kV and less than or equal to 30 kHz, operable. Single-ended discharge lamp according to one of the preceding claims,
characterized in that
the pedestal (22) has a base element (23) with a first diameter, from which protrudes an attachment element (24) with a second diameter in the direction of the proximal region (11),
wherein the first diameter is greater than the second diameter and
wherein the base member (23) forms the second plane (E2) and the attachment member (24) forms the first plane (E1). Single-ended discharge lamp according to one of the preceding claims, in particular according to claim 7,
characterized in that
the base (22) is rotationally symmetrical about the preferred axis (100),
wherein the attachment member (24) protrudes substantially centrally from the base member (23). Single-ended discharge lamp according to one of the preceding claims,
characterized in that
the first contact pin (50) is arranged aligned on the easy axis (100). Single-ended discharge lamp according to one of the preceding claims,
characterized in that
the base (22) has a receiving region (29), in which the first pinch seal (42) for holding the burner in the base is at least partially receivable. Single-ended discharge lamp according to one of the preceding claims, in particular according to claim 10,
characterized in that
the receiving region (29) around the preferred axis (100) is rotationally symmetrical. Single-ended discharge lamp according to one of the preceding claims, in particular according to one of claims 10 or 11,
characterized in that
the receiving region (29) is designed such that both a cross-sectionally rectangular and a circular cross-section, in particular oval or circular pinch seal, can be accommodated therein. Single-ended discharge lamp according to one of the preceding claims, in particular according to one of claims 10 to 12,
characterized in that
the base (22) and / or the receiving area (29) are formed with an anti-rotation device in such a way that the burner (40) can be stored in a rotationally stable and stable manner via at least one pinch seal. Single-ended discharge lamp according to one of the preceding claims,
characterized in that
Furthermore, the burner (40) at least partially enclosing, tubular shield (60) is provided as burst protection and to avoid sodium loss. Single-ended discharge lamp according to one of the preceding claims, in particular according to claim 14,
characterized in that
the shield (60) is connected to the burner (40) via a spring clip (80),
wherein the spring clip (80) is adapted to engage the first or second pinch seal for supporting the shield (60). Single-ended discharge lamp according to one of the preceding claims, in particular according to claim 15,
characterized in that
the spring clip (80) is disposed at a distal end of the shield (60) and adapted to engage the distal second pinch seal. Single-ended discharge lamp according to one of the preceding claims, in particular according to claim 15 or 16,
characterized in that
the spring clip (80) is designed in such a way that it holds the shield (60) under prestress against a particular circular projection (26) on a floor area in the lamp interior on the base (22) of the discharge lamp (10). Single-ended discharge lamp according to one of the preceding claims, in particular according to claim 17,
characterized in that
the projection (26) is formed such that the shield (60) centered in the lamp interior about the easy axis (100) can be accommodated. Single-ended discharge lamp according to one of the preceding claims, in particular according to one of claims 15 to 18,
characterized in that
the spring clip (80) made of metal, in particular spring steel is formed. Single-ended discharge lamp according to one of the preceding claims, in particular according to claim 14 or 18,
characterized in that
the shield (60) is designed such that it can be locked in the base (22) with cement, adhesive or silicone. Single-ended discharge lamp according to one of the preceding claims,
characterized in that
the reflector (20) and the base (22) are formed integrally with each other. Single-ended discharge lamp according to one of the preceding claims,
characterized in that
the reflector (20) and the base (22) are hermetically connected to each other.

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