EP1834209A1

EP1834209A1 - Lamp module for projectors

Info

Publication number: EP1834209A1
Application number: EP05850189A
Authority: EP
Inventors: Richard Lang; Gerhard Löffler; Thomas Mehr; Dirk Rosenthal
Original assignee: Patent Treuhand Gesellschaft fuer Elektrische Gluehlampen mbH
Current assignee: Osram GmbH
Priority date: 2005-01-03
Filing date: 2005-12-20
Publication date: 2007-09-19
Also published as: US20080137344A1; CA2592841A1; JP2008527616A; TW200632516A; DE102005000713A1; KR20070112374A; WO2006072228A1

Abstract

Disclosed is a lamp module for projectors, in particular for digital cinema and video projectors, comprising a reflector system provided with at least two reflectors wherein a lamp is received.The reflector system is electrically connected to the lamp and supports said lamp such that the reflector system and the lamp can be inserted into the premounted unit in the projector and the mounting thereof is made significantly easier.

Description

Lamp module for projectors

Technical area

The invention relates to a lamp module for projectors according to the preamble of patent claim 1 and a method for positioning and electrical contacting of a lamp in such a lamp module according to the preamble of claim 25.

State of the art

The different projection technologies and performance characteristics of modern projection systems open up a wide range of applications in conventional and digital cinema as well as home cinema, but also place increasing demands on the quality of the light source and its mounting in the projectors.

In conventional cinema projectors, the lamp, for example a xenon short-arc high-pressure discharge lamp, is inserted into the reflectors already installed in the projector and removed and replaced at the end of its service life as a single component from the projector. Due to the necessary adjustment of the lamp in the projector, technically trained personnel is required in such systems for installing the lamp, which must wear suitable protective clothing due to the risk of explosion of the lamp under high pressure. For this reason, pre-assembled lamp modules, with reflectors used in a housing, are used in video projection technology in which the lamp is accommodated in the housing. The position of the lamp is already adjusted via an adjusting device arranged on the housing by the manufacturer, ie an adjustment by the user is no longer necessary. The preassembled lamp module is positioned over a rail arranged on the housing and with dowel pins on the projector and fixed via a flange. In this solution, the user is protected in the case of a "lamp burst" by the closed with a filter disc housing and the exact inclusion of the lamp module in the projector further adjustment and thus trained personnel unnecessary.

A disadvantage of the above-described solution that the lamp modules through the housing and the required mechanical adjustment devices have a high weight and are very expensive due to their complex design and manufacturing.

Presentation of the invention

The invention has for its object to provide a lamp module, in particular for digital cinema and video projectors, as well as a method for positioning and electrical contacting of a lamp in such a lamp module, in which over conventional solutions improved handling with reduced manufacturing cost is possible.

This object is achieved with regard to the lamp module by the features of claim 1 and with regard to the method for positioning and electrical contacting of a lamp in such a lamp module by the feature combination of claim 25. Particularly advantageous embodiments of the invention are described in the dependent claims. The lamp module according to the invention has a reflector system with at least two reflectors, in which a lamp is accommodated. According to the invention, the reflector system is electrically connected to the lamp and supports it, so that the reflector system and the lamp can be used as a preassembled unit in the projector.

The reflector system is preferably formed by two reflectors, wherein a first reflector with a light exit opening and a second reflector is formed with a reflector neck, wherein the lamp is mounted in the region of the reflector neck and the light exit opening.

Due to the arrangement of the lamp in the interior of the reflector system can be on a housing, as required in the prior art solution for safety reasons, be dispensed with. By using the reflector system as a mechanical and at the same time electrical connection element of the lamp to the projector, the production cost of the lamp module compared to the prior art substantially reduced. The current transport takes place via the reflector system of the lamp, wherein it must be noted that the reflector system with the lamp must be isolated from the other components of the projector.

According to a particularly preferred embodiment, the reflector system has a spherical reflector as the first reflector and an elliptical reflector as the second reflector.

It has proved to be particularly advantageous to connect the two reflectors along radially projecting planar surfaces which together form a flange along which the lamp module can be fastened to the projector. For mutual alignment of the two reflectors, an annular groove may be provided on the plane surface or at the transition from the plane surface to the reflector curvature of a reflector into which a feather key engages the other reflector. Preferably positioning elements, for example positioning pins are provided on the flange, which allow mounting of the lamp module to the projector in a predetermined relative position. Due to the defined positioning, no further adjustment of the lamp module is necessary and thus the insertion of the lamp module into the projector is simplified and possible without specialist knowledge.

The spherical (first) reflector preferably has, on the light exit side, an approximately cone-shaped projection which merges into a fastening section for a filter holder which delimits the light exit opening and extends approximately in the manner of a cylinder jacket.

The lamps used in such a lamp module are high pressure discharge lamps. They are composed of a lamp bulb and two lamp shafts diametrically opposite the lamp bulb. In the lamp shafts, the electrodes are sealed with their electrode rods gas-tight and electrically connected to the contacts on the sockets, which are attached to the free ends of the lamp shafts.

For holding the one base of the lamp advantageously a centering ring is inserted into the cylinder jacket-shaped mounting portion of the reflector. The centering ring preferably has inwardly projecting struts, which are fastened to a centrally located in the centering metal sleeve. The metal sleeve serves to receive a conductive contact pin at the free end of the base.

The structure of the lamp module is further simplified if the centering ring also carries a filter holder for a filter, in particular a UV / IR filter.

Due to the heat development of the lamp and the associated lifetime limitation effective cooling is needed. For this purpose, for example, blown through a fan air in the reflector system or be sucked out of it, the resulting Cooling air flow surrounds the lamp body and effectively prevents the formation of a heat accumulation.

The cone-shaped projection of the first reflector preferably has a recess through which a flow of cooling air can enter or leave the reflector system.

It is particularly advantageous if the reflector neck of the elliptical (second) reflector has a receiving section on which spring tabs are formed, between which a cylindrical metal sleeve pushed onto the other lamp shaft can be received and secured. The cylindrical metal sleeve is underlaid with a graphite tape and held by a clamping ring.

Due to the difference in diameter between the reflector neck and attached to the free end of the lamp shaft ceramic base, the cooling air flow in the reflector neck on or emerge from this and the cooling of the lamp can be ensured by the resulting annulus.

In order to ensure the maintenance of the second reflector on the metal sleeve or on the lamp shaft while at the same time possible adjustment of the lamp in the refiektor neck, the spring tabs are preferably free-zest from the reflector neck and bent into the receiving portion inside. The spring tabs can also be milled out or made by electroforming.

The pushed onto the free end of the lamp shaft cylindrical base made of ceramic extends with its electrode end over the opposite end of the electrode of the cylindrical metal sleeve. The base is held by the cylindrical metal sleeve by out of the metal sleeve bent tab pairs. Of these pairs of tabs engages each one tab in a hole in the ceramic base, while the other tab supports the electrode-side end of the ceramic base. Preferably, the lamp used is a xenon short-arc high-pressure discharge lamp, since such lamps have particularly good color rendering properties as well as high luminance and luminous flux, which enable good image reproduction in optical projection systems.

In a preferred embodiment, the electrical contacting of the base takes place at the end of the first lamp shaft by welding or soldering the electrical contact of the base with the receiving reflector part. The electrical connection of the other electrode is made by means of a contact element at the free end of the leaking from the ceramic base strand, which in turn is connected to the electrode rod.

For the construction of the lamp module, the reflector system of electrically conductive material, for example. Aluminum or nickel or provided with an electrically conductive coating and has a reflective coating.

The inventive method for positioning and electrical contacting of a lamp in such a lamp module is carried out with the steps:

a) inserting the lamp with attached to the second lamp shaft metal sleeve in the reflector system wherein the contact pin of the first base is inserted into the metal sleeve on the first reflector;

b) gripping the second lamp shaft of the lamp with an adjusting device and adjusting the lamp in the x-, y- and z-direction with respect to the optical axis;

c) fixing the aligned lamp in the reflector system, in particular by welding or soldering the metal sleeve with the spring tabs on the second reflector and the contact pin of the first socket with the sleeve on the centering ring of the first reflector;

d) pushing on and fastening the ceramic base with strain relief on the second lamp shaft;

e) crimping the strain relief with the Stromzuführungslitze;

f) electrically connecting the free end of the Stromzuführungslitze on the second base of the lamp with the power supply of the lamp via a contact element, in particular a contact plug.

It is particularly advantageous if the lamp for electrical contacting and / or adjustment in the lamp module projects, at least in sections, out of the reflector system. As a result, the lamp is easier to grasp by the adjusting device and can be contacted by the contact element in a simplified manner after the adjustment.

Short description of the drawing (s)

The invention will be explained in more detail below with reference to a preferred embodiment. Show it:

Figure 1 is a side view of a lamp module according to the invention;

Figure 2 is a three-dimensional view of the lamp module of Figure 1;

Figure 3 is a side view of a spherical reflector of the lamp module of Figure 1;

Figure 4 is a three-dimensional view of the spherical reflector of Figure 3;

Figure 5 is a detail view of a centering ring of Figure 2;

Figure 6 is a detail view of a filter holder of Figure 2; Figure 7 is a side view of an elliptical reflector of the lamp module of Figure 1;

Figure 8 is a plan view of the elliptical reflector of Figure 7 and

FIG. 9 shows a three-dimensional view of the elliptical reflector from FIG. 7.

10 shows a section through the neck of the elliptical reflector with inserted metal sleeve and attached ceramic base

Preferred embodiment of the invention

According to FIG. 1, the lamp module 1 according to the invention has a reflector system 6 formed by a first, spherical reflector 2 and a second, elliptical reflector 4, in which a lamp 8 is accommodated. The lamp 8 is carried by the reflector system 6 and forms with this a preassembled unit, which is electrically isolated on a wall 10 of a projector, such as a digital projector with LCD or DLP / DMD technology.

The spherical reflector 2 is formed with a light exit opening 12 and the elliptical reflector 4 with a reflector neck 14, wherein the lamp 8 is mounted according to the invention in the region of the reflector neck 14 and the light exit opening 12.

Due to the heat development of the lamp 8 and the associated lifetime limitation effective cooling is needed. For this purpose, air is blown into the reflector system 6 via an unillustrated blower, as indicated by arrows. The cooling air flow surrounds the lamp 8 and effectively prevents the formation of a heat build-up in the reflector system 6. In the illustrated embodiment, the lamp 8 is designed as a xenon short-arc high-pressure discharge lamp in a conventional construction. Such a short arc lamp consists essentially of an anode 16, a cathode 18, which are each mounted on an electrode rod 28 and a filled with high purity xenon lamp bulb 20. This lamp bulb 20 passes along an optical axis 22 on both sides in each case an approximately cylindrical lamp shaft 24, 26, in which the electrode rods 28 of the anode 16 and cathode 18 melt gas-tight and are electrically connected to a base system 32, 34 at the free end of the lamp necks 24, 26.

In the embodiment shown, the electrical contacting of the first base (anode base) 32 of the lamp 8 via the reflector system 6 and the second base (cathode base) 34 with strain relief 33 via a contact plug, not shown, at the free end of Stromzuführungslitze 35. For simplified adjustment and contacting the lamp 8 in the lamp module 1 is the lamp shaft 26 on the cathode side out of the reflector system. The lamp 8 is thereby better accessible by an adjusting device, not shown, and after the adjustment simplified via the base 34 and the Stromzuführungslitze 35 contacted. The reflector system 6 is made of electrically conductive material and is provided with a reflective coating. Due to the use of the reflector system 6 as a mechanical and electrical connection element of the lamp 8 to the projector 10, the production costs compared to the prior art substantially reduced.

The spherical reflector 2 and the elliptical reflector 4 are connected to one another via radially projecting plane surfaces 36, 38 (see FIG. 4 and FIG. 9), which together form a flange 40 along which the lamp module 1 is fastened in isolation to the projector 10.

On the flange 40 provided with an insertion bevel 42 positioning pins 44 are provided in receiving bores 46 of opposite the remaining housing electrically isolated mounted projector wall 10 are used and allow a defined position of the lamp module 1 on the projector without adjustment by the user.

FIG. 2 shows a three-dimensional view of the lamp module 1 viewed from the light exit opening 12. Accordingly, a centering ring 48 with a sleeve 76 for receiving the contact 30 of the anode base 32 of the lamp 8 is inserted into the spherical reflector 2. The centering ring 48 also carries a UV / IR filter 50, which is held by a filter holder 52 at the light exit opening 12.

As can be seen in particular from FIG. 3, which shows a side view of the spherical reflector 2, the spherical reflector 2 has, on the light exit side, an approximately cone-shaped projection 54, which merges into an approximately cylinder jacket-shaped fastening section 56 delimiting the light exit opening 12. The mounting portion 56 is provided with evenly distributed over the circumference of holes 58, in the fastening elements, not shown, for example. Screws or rivets, for fastening of centering ring 48 and filter holder 52 are used. The cone-shaped projection 54 has a punched, approximately rectangular recess 60, through which the cooling air flow can leave the reflector system 6 in the direction indicated by arrows (see Figure 1).

Figure 4 shows a three-dimensional representation of the spherical reflector 2, wherein on the front side radially projecting plane surface 36, three symmetrically distributed knob-like Positionierhebungen 62 are arranged, which can be brought into engagement with positioning recesses 64 of the planar surface 38 of the elliptical reflector (see Figure 9) and the position of the two reflectors 2, 4 to each other with respect to the optical axis 22 define. Furthermore, three through-holes 66 for receiving the positioning pins 44 and three through-holes 68 for fixing with the elliptical reflector 4 are formed on the plane surface 36. The fixation of two reflectors 2, 4, for example, by not shown, inserted into the holes 68 screws or rivets.

According to FIG. 5, three inwardly projecting struts 70, 72, 74 are approximately star-shaped on the centering ring 48, which carry a sleeve 76 arranged centrally in the centering ring 48 for receiving the connection contact 30 (see FIG. 1) of the base 32 of the lamp 8 the centering ring 48 on one of the light exit side opposite inner edge has a chamfer, which is engaged behind by the struts 70, 72, 74 in order to prevent shading. The sleeve 76 is offset along the optical axis 22 with respect to the light exit side to the rear, into the reflector. The centering ring 48 is connected via evenly distributed around the circumference of holes 80 by means not shown fasteners with the mounting portion 56 of the spherical reflector 2 and has an end-side annular recess 82 for receiving the filter disk 50th

FIG. 6 shows a three-dimensional representation of the filter holder 52 which can be pushed onto the attachment section 56 of the spherical reflector 2 for receiving the UV / IR filter 50 (see FIG. 2). The filter holder 52 has an approximately L-shaped cross-section, wherein the shorter leg 84 can be brought into contact with the filter 50 on the front side, surrounds it and thus secures it to the lamp module 1. The filter holder 52 is connected via circumferentially arranged holes 86 via fastening elements, not shown, with the attachment portion 56 of the spherical reflector 2 connectable.

As can be seen in particular from FIG. 7, which shows a side view of the elliptical reflector 4, the elliptical reflector 4 has a shell-shaped surface 88, which merges into the reflector neck 14, which has an approximately cylindrical jacket-shaped receiving section 90 on which three spring clips 92, 94 , 96 are formed, between which the lamp neck 26 can be received with a metal sleeve 106 pushed over it and can be fixed (see Figure 10). The spring tabs 92, 94, 96 are punched out of the reflector neck 14 and bent into the receiving portion 90 so that they rest at least partially resiliently when inserting the lamp 8 at a peripheral surface of the metal sleeve 106 to a secure hold of the lamp shaft 26 to reach and at the same time to allow adjustment of the lamp 8 in the reflector neck 14. The spring tabs 92, 94, 96 are welded or soldered after the adjustment of the lamp 8 in the reflector system 6 with the pushed onto the lamp shaft 26 sleeve 106. Due to the difference in diameter between reflector neck 14 and lamp shaft 26, the cooling of the lamp can be further improved by the resulting annular space 100.

FIG. 9 shows a three-dimensional representation of the elliptical reflector 4, wherein three symmetrically distributed positioning recesses 64 are arranged on the end face radially projecting planar surface 64, which can be brought into engagement with the positioning elevations 62 of the planar surface 36 of the spherical reflector 2 (see FIG Location of the two reflectors 2, 4 with respect to the optical axis 22 define. On the flat surface 38 further three through holes 102 for receiving the positioning pins 44 and three through holes 104 are formed for fixing with the spherical reflector 2.

In Figure 10, the neck 14 of the elliptical reflector 4 is shown in section. In the neck 14, a cylindrical metal sleeve 106 is inserted, which is pushed over the lamp shaft 26, not shown here (see Figure 1). The cylindrical metal sleeve 106 has at its end facing the cathode a plurality of extending in the axial direction of the lamp slots 108. These allow the attachment of the metal sleeve 106 on the lamp shaft 26 by means of a clamping ring 110, which is pushed over the electrode-side end of the metal sleeve 106. To protect the lamp neck while the metal sleeve is still of a graphite tape, not shown here highlighted. On the other end of the metal sleeve 106 is pushed with its one end a ceramic base 34. The ceramic base 34 is held by the metal sleeve 106 freely stamped and bent-up tabs 114, which engage on the one hand in holes 112 in the ceramic base 34 and on the other hand support the electrode-side end of the ceramic base 34. The ceramic base 34 further has a strain relief 33 in the form of a sleeve at the end facing away from the cathode. By this, the power supply wire 35 connected to the rod of the electrode (cathode) is pushed and crimped after assembly.

The positioning and electrical contacting of the lamp 8 in the lamp module 1 takes place substantially in six steps. In a first operation, the lamp 8 is introduced into the reflector system 6 with metal sleeve 106 fastened on the second lamp shaft 26, the contact pin 30 of the first socket 32 being inserted into the metal sleeve 76 of the centering ring 48 on the first reflector 2. Subsequently, the second lamp shaft 26 of the lamp 8 is gripped with an adjusting device, not shown, and the lamp 8 in the x-, y- and z-direction with respect to the optical axis 22 adjusted, the terminal contact 30 is movable in the sleeve 76 and the adjustment facilitated. In a further operation, the metal sleeve 106 is welded or soldered to the spring tabs 94, 96, 98 on the second reflector 4 and the contact pin 30 of the first base 32 with the sleeve 76 on the centering ring 48 of the first reflector 2, so that the reflector system 6 electrically the lamp 8 is connected. Then, the ceramic socket 34 is pushed and secured with the strain relief 33 on the second lamp shaft 26 and the strain relief 33 with the Stromzuführungslitze 35 verkrimmt. The final connection of the second electrode (cathode) to the network is made by connecting the free end of the power supply strand 35 to the power supply of the lamp 8 via a contact element, in particular a contact plug. The object according to the invention is not limited to the xenon short-arc high-pressure discharge lamp described, but any projector lamp known from the prior art can be used.

Disclosed is a lamp module 1 for projectors 10, with a reflector system 6, which has at least two reflectors 2, 4, in which a lamp 8 is accommodated. The reflector system 6 is electrically connected to the lamp 8 and carries it, so that the reflector system 6 and lamp 8 can be used as a preassembled unit in the projector 10 and simplifies the assembly considerably.

Claims

claims

1. Lamp module (1) for projectors, in particular for digital cinema and video projectors, with a reflector system (6) with at least two reflectors (2, 4), in which a lamp (8) with a piston (20) and two shafts ( 24, 26), which have an electrode system (16, 18) and pedestals (32, 34) at the ends of the shanks, is accommodated, characterized in that the reflector system (6) is electrically connected to the lamp (8) and these carries, so that the reflector system (6) and lamp (8) can be used as a preassembled unit in the projector (10).

2. Lamp module for projectors according to claim 1, wherein the reflector system (6) consists of two reflectors (2, 4), the first reflector (2) with a light exit opening (12) and the second reflector is formed with a reflector neck (14), and the lamp (8) is mounted in the region of the reflector neck (14) and the light exit opening (12).

3. lamp module for projectors according to claim 1 or 2, wherein the two reflectors (2, 4) along radially projecting planar surfaces (36, 38) are connected, which together form a flange (40), along which the lamp module (1) on a Projector (10) can be fastened.

4. Lamp module for projectors according to claim 1 or 2, wherein a reflector has an annular groove on the flat surface or at the transition from the planar surface to the reflector curvature, in which engages an annular key on the other reflector.

5. lamp module for projectors according to claim 3, wherein on the flange (40) positioning elements (44) are provided which allow a defined mounting of the lamp module (1) on the projector (10).

6. Lamp module for projectors according to claim 2, wherein the first reflector (2) is a spherical reflector and the second reflector (4) is an elliptical reflector.

7. lamp module for projectors according to claim 6, wherein the reflector neck (14) of the second reflector (4) has a receiving portion

(90), are formed on the spring tabs (92, 94, 96), between which the second lamp shaft (26) of the lamp (8) is receivable and fixable.

8. lamp module for projectors according to claim 7, wherein the spring tabs (92, 94, 96) from the reflector neck (14) punched free and bent into the receiving portion (90).

9. Lamp module for projectors according to claim 7, wherein the spring tabs (92, 94, 96) are milled out of the reflector neck (14).

10. lamp module for projectors according to claim 7, wherein the spring tabs (92, 94, 96) from the reflector neck (14) are made by electroforming.

1 1. Lamp module for projectors according to claim 1, wherein the second lamp shaft at least in the region of the spring tabs (92, 94, 96) carries a cylindrical metal sleeve (106).

12. Lamp module for projectors according to claim 1 1, wherein between the cylindrical metal sleeve (106) and the lamp shaft (26) is a graphite strip.

13. lamp module for projectors according to claim 11, wherein the cylindrical metal sleeve (106) with a clamping ring (1 10) on the second

Lamp shaft (26) is held.

14. Lamp module for projectors according to claim 11, wherein on the free end of the lamp shaft (26) and the end facing away from the electrode of the cylindrical metal sleeve (106), a cylindrical base (34) made of ceramic is pushed.

The lamp module for projectors according to claim 14, wherein the cylindrical pedestal (34) is held by the cylindrical metal sleeve (106) by tab pairs (114) bent out of the metal sleeve (106).

16. Lamp module for projectors according to claim 6, wherein the first reflector (2) on the light exit side has an approximately cone-shaped projection

(54) which merges into an approximately cylinder jacket-shaped fastening section (56) delimiting the light exit opening (12).

17. Lamp module for projectors according to claim 16, wherein in the cylinder jacket-shaped mounting portion (56) has a centering ring (48) for receiving the base (32) of the first lamp shaft (24) of the

Lamp (8) is inserted.

18. lamp module for projectors according to claim 17, wherein the centering ring (48) inwardly projecting struts (70, 72, 74) which at a centrally in the centering ring (48) arranged sleeve (76) for receiving a terminal contact (30) on Base (32) of the first

Lamp shaft (24) of the lamp (8) are attached.

19. Lamp module for projectors according to claim 17 or 18, wherein the centering ring (48) carries a filter holder (52) for a filter (50), in particular a UV / IR filter.

20. Lamp module for projectors according to claim 16, wherein the cone-shaped projection (54) has at least one recess (60) through which a flow of cooling air can enter or leave the reflector system (6).

21. Lamp module for projectors according to one of the preceding claims, wherein the lamp (8) is a xenon high-pressure discharge lamp.

22. Lamp module for projectors according to one of the preceding claims, wherein the electrical contacting of the base (32) on the first lamp shaft (24) of the lamp (8) via the reflector (2) and the base (34) on the second lamp shaft (24) via a contact element at the free end of the Stromzuführungslitze (35) takes place.

23. Lamp module for projectors according to one of the preceding claims, wherein the reflector system (6) of electrically conductive

Material, in particular aluminum or nickel or is provided with an electrically conductive coating and has a reflective coating.

24 lamp module for projectors according to one of the preceding claims, wherein at least one end portion of the lamp (8) for electrical contacting and / or adjusting in the lamp module (1) at least partially protruding from the reflector system (6).

25. A method for positioning and electrical contacting of a lamp (8) in a reflector system (6) of a lamp module (1), in particular according to one of claims 1 to 24, with the steps:

a) inserting the lamp (8) with metal sleeve (106) fastened on the second lamp shaft (26) into the reflector system (6), the contact pin (30) of the first socket (32) being inserted into the metal sleeve (76) on the first reflector (2 ) is used;

b) gripping the second lamp shaft (26) of the lamp (8) with a

Adjusting device and adjustment of the lamp (8) in the x-, y- and z-direction with respect to the optical axis; c) fixing the aligned lamp (8) in the reflector system (6), in particular by welding or soldering the metal sleeve (106) with the spring tabs (94, 96, 98) on the second reflector (4) and the contact pin (30) of the first base (32) with the sleeve (76) on the centering ring of the first reflector (2);

d) pushing on and fastening the ceramic base (34) with strain relief (33) on the second lamp shaft (26);

e) crimping the strain relief (33) with the power supply strand (35);

f) electrically connecting the free end of the power supply strand

(35) on the second base (34) of the lamp (8) with the power supply of the lamp via a contact element, in particular a contact plug.