The present invention relates to a lamp and a method of manufacturing a lamp, in particular to a discharge lamp, and more specifically to a lamp for use in a vehicle headlight.
Electrical discharge lamps, in particular high intensity discharge (HID) lamps are widely used today, e. g. in vehicle headlights. While first generations of such automotive HID lamps comprised a lamp base only for mechanical mounting and electrical contacting of a burner, currently developed lamps include circuitry for operation and/or ignition of the burner integrated within the lamp base.
Some components, which may be used e. g. for delivering a high voltage for ignition of an arc discharge within the burner require special electrical insulation. For especially good electrical insulation, electrical components, in particular a transformer, have been “potted”, i. e. embedded within a surrounding insulation compound.
US 2010/0134010 A1 describes a gas discharge lamp with a burner fixed to a lamp base consisting of electrically conductive or metalized plastic, or by plastic enclosed in an electrically conductive casing, e. g. made from aluminum, magnesium or brass. The base is closed by a base plate consisting of a material well conductive thermally as well as electrically, such as aluminum or magnesium. In the interior of the base, ignition electronics including an ignition transformer and operation electronics are provided. An electrically conductive shielding surface is established between the ignition electronics and the operation electronics by a metallic sheet inserted between two circuit boards, connected to the electrically conductive casing. Remaining hollow chambers within the casing, in particular around the ignition transformer, are filled with a casting compound to prevent electrical flashover due to the high voltage created by the ignition transformer, and also for de-heating of the electronics and for providing a mechanically sturdy unit.
It may be considered an object to provide a lamp and a manufacturing method therefor allowing to easily provide good insulation without adverse effects during later operation of the lamp.
This object is solved by a lamp according to claim 1 and by a method for manufacturing a lamp according to claim 11. Dependent claims refer to preferred embodiments of the invention.
The present inventors have considered the practice of “potted” electrical components within the lamp base and have found that insulation compounds used may have detrimental effects during operation of the lamp if not handled properly. In particular, many insulating compounds comprise silicone, which may evaporate due to the high operation temperatures and intense radiation from the burner. Evaporated silicone entering the reflector may lead to whitening thereof, as well as to a reaction with anti-condensation coatings. The inventors have therefore found that it is essential to prevent the insulation compound from entering the front portion of the lamp base, oriented towards the reflector. This may be difficult to achieve, since many insulation compounds well suited for potting of components are provided in a very liquid state and are not easy to handle during the manufacturing process.
According to the invention, the lamp comprises a burner, in particular with a discharge vessel for generating an electrical arc discharge, fixed to a lamp base. The lamp base comprises a housing, with a top wall element oriented towards the burner, and at least one opening within the top wall element. Within the base, at least one insulation chamber is arranged, where an electrical component of an operating circuit, in particular a transformer, is embedded within an insulation compound.
In order to avoid, at the time of the production, leakage of insulation compound through the top wall and towards the burner, a raised retention wall is provided around the opening. Preferably, the raised retention wall extends from the top wall in the same direction as the insulation chamber, e. g. at least substantially rectangular.
In the manufacturing method according to the invention, the insulation chamber is filled at least partially with the insulation compound, thereby embedding the electrical component (e. g. transformer). In particular if the insulation chamber is oriented facing from the top wall in a direction away from the burner, and is filled in “upside down” orientation, i. e. with the burner oriented downwards (and the top wall beneath the insulation chamber), the raised retention wall provided around the opening in the top wall prevents insulation compound spilled from the chamber to leak through the opening.
Thus, the raised retention wall facilitates the manufacture of lamps with “potted” components. In the event of insulation compound spilled from the insulation chamber, the spilled insulation compound does not easily leak through the opening to enter the critical part of the lamp exposed to the burner, but is contained by the retention wall.
A retention wall has proven to be a simple measure, yet effective to prevent potential problems with insulation compound leaking towards the exposed front portion of the lamp.
One opening in the top wall, which is preferably surrounded by a raised retention wall, is an opening through which the burner protrudes from the lamp base. It is possible that more than one opening is provided in the top wall. For example, further openings in the top wall may be provided for a back contact (electrical conductor to the burner), or for an electrical ground contact. It is preferred to provide a raised retention wall for each of the openings provided within the top wall.
According to a preferred embodiment of the invention, the lamp base comprises a holder element, which is preferably made out of an electrically insulating material. The holder element may comprise the top wall and the opening, and may include—preferably in one piece with the holder element—the raised retention wall. Further, it is preferred that the holder element includes at least side walls for the insulation chamber. A corresponding holder element may easily be manufactured e. g. from a plastic material and include both the insulation chamber and the retention walls. It is further preferred that the holder element is arranged within an outer metal housing.
In a preferred embodiment, an electronic operating circuit is arranged within the base to supply electrical power to the burner. The operating circuit may comprise an ignition circuit for providing a high ignition voltage to the burner, or a driver circuit for providing electrical power for operation of the burner, or, preferably, both.
According to a preferred embodiment of the invention, a metal shield element is provided within the lamp base to shield electrical components of the operating circuit. In particular the high voltage required for ignition of an arc discharge in the burner may create electromagnetic interference (EMI). The metal shield element serves to protect sensitive components, such as e. g. semiconductor components, from EMI. The metal shield element may preferably be provided between a transformer and/or a core component and other components of an electric operating circuit for the burner.
Further, the housing may comprise a plug/socket connector electrically connected to contact path elements extending within the housing. A metal shield may be arranged to at least partly cover the plug/socket connector and/or the contact path element, in order to prevent EMI from spreading via the electrical connection.
In manufacturing the lamp according to the invention, it is preferred to provide the insulation compound, preferably a silicone-containing insulation compound, in a fluid state. The insulation compound may be filled into the insulation chamber in the fluid state, thereby allowing easy handling and ensuring that the “potted” component will be fully embedded. In case of amounts of spillage, the fluid compound will be retained by the retention wall. In a later curing treatment, the liquid compound is cured, e. g. by heating, to adopt a firm state. This applies to the compound within the insulation chamber as well as to any potential spillage retained by the retention wall. After the curing treatment, due to the now firm state of the insulation compound, there is no further risk of compound leaking to the exposed front parts of the lamp, irrespective of the later orientation of the lamp during operation.
These and other aspects of the invention will be apparent from and elucidated with reference to the embodiments hereinafter.
In the drawings,
As visible in particular from the cross-sectional view of
The burner 14 is mechanically held relative to the lamp cap housing 12 by a holding ring structure 32 provided around the burner 14, fixed to a collar of the burner 14 by spot-welded spring tongues.
The lamp base 12 comprises a metal outer housing 40, an inner housing holder element 30, and a bottom plate 44. All of the outer housing wall elements 40, 44 are made out of aluminum as a metal material of good heat conduction properties. The inner holder element 30 is made out of a plastic material.
Within the lamp base 12, electrical components of a lamp operating circuit 50 are arranged. The lamp operating circuit 50 is supplied with electrical power from an electrical plug/socket connector 52 opening to the side of the lamp base 12. For use in a motor vehicle headlamp, the lamp 10 is electrically connected to onboard electrical power and to ground via the connector 52. The lamp operating circuit 50 integrated within the lamp base 12 provides all circuitry required to adapt the voltage supplied at connector 52 to the type of electrical driving voltage and current required for the operation of the burner 14 during ignition, following run-up and steady-state operation. The lamp operating circuit 50 comprises on a printed circuit board 58 and connected thereto circuitry and electrical components for ignition and operation of the lamp 10 as well as a microcontroller for controlling operation of to the burner 14.
As visible from the exploded view shown in
As visible in particular from the cross-sectional view of
As the burner 14 is thus installed to protrude into the lamp cap housing 12, the electrical contact leads from the burner 14, namely the central contact lead 22 and return contact lead 24, also extend into the lamp cap housing 12. In operation of the lamp 10, and in particular during ignition, insulation needs to be provided to prevent flashover between the electrical contact leads 22, 24 as well as from any of the contact leads 22, 24 to components or contact leads of the lamp operating circuit 50 or parts of the lamp cap housing 12. In order to provide this insulation, a plastic cap 60 is provided, covering the central contact lead 22 and the return contact lead 24 axially. The cap 60 serves to provide electrical insulation, in particular between the central contact lead 22 and return contact lead 24, but also between the contact leads 22, 24 and the metal bottom plate 44.
Components of the lamp operating circuit 50 are arranged on a printed circuit board 58 provided within the lamp base 12, holding and electrically interconnecting the electrical circuit components provided thereon. The printed circuit board (PCB) 58 with electrical components mounted on a top surface is arranged directly on the bottom plate 44. Thus, there is close thermal contact between the lamp operating circuit 50 and the bottom plate 44, so that the bottom plate 44 serves as heat sink.
The operating circuit 50 arranged within the base 12 comprises all necessary circuitry, such that the lamp 10 for all modes of operation requires only connection to the onboard voltage of a motor vehicle, which may be supplied at the plug/socket connector 52. The operating circuit 50 includes an ignitor for supplying a high voltage to the burner 14 for igniting an arc discharge within the discharge vessel 18. The operating circuit further comprises a driver circuit for generating an alternating current for operation of the burner 14 in a run-up period after ignition and in subsequent steady-state operation. The operating circuit 50 comprises a micro-controller for control of the operation of the components of operating circuit 50 and of the burner 14.
As shown in
The contact path elements 70 are flat, elongate metal strips or webs. Corresponding to the three contacts 62 of the plug/socket connector 52, there are three contact path elements 70 arranged in parallel within the base 12, extending from the connector 52 to the PCB 58. The contact path elements 70 are bent roughly L-shaped, as shown in
As visible from
The contact path elements 70 are bent at an angle of about 90° to continue as a second section 70b towards the PCB 58, i. e. substantially in parallel to the longitudinal axis X of the lamp 10. The second section 70b of the contact path elements 70 is held and guided by the holder 30, but not fixed thereto. The holder 30 provides an elongate opening, through which the second section 70b of the contact path elements 70a protrudes, such that each of the metal webs is surrounded by the plastic material of the holder 30 in traverse directions. Thus, the second section 70b of the contact path elements 70 is slidably received within the opening of the holder 30, such that it is movable in longitudinal direction while being guided in traverse direction by the enclosing plastic material.
During assembly of the lamp 10, the assembled PCB 58 is connected to the holder 30 as shown in the exploded view of
In order to be able to establish a reliable solder connection, the holder 30 and the contact path elements 70 are pre-assembled with the length of the second section 70b designed for an interference fit, i. e. longer than necessary for an exact 90° bend between the first section 70a and second section 70b of the contact path elements 70. Thus, before assembly, the contact flaps 71b extend out of the holder 30 to protrude a small distance below. As the PCB 58 is fitted, a force acts longitudinally on the second section 70b of a contact path element 70, such that this section of the contact path elements 70 slides longitudinal within the guiding fit of the holder 30. Within the base 12, the holder 30 leaves a spring space 74 free, into which a third section 70c of the contact path elements is received as it is deflected by the force exerted on the second section 70b of the contact path elements 70.
By providing the mentioned oversize, slidable reception and spring space 74, a clamping fit of the contact flaps 71b on the contact surfaces 72 of the PCB 58 is achieved, where a spring force of the deflected third section 70c of the contact path elements 70 achieves a pressing force, pressing the contact flaps 71b onto the contact surfaces 72. Subsequently, the solder connection is made.
The holder 30 comprises an opening 45 which allows access to the contact flaps 71b and contact surfaces 72 for soldering.
As already mentioned, one of the contacts 62 provided at the connector 52 is an electrical ground contact, connected to electrical ground of the motor vehicle. As shown in
The holder 30 includes an opening 78 provided within the top wall 38. The contact spring 76 is fixed to the holder 30 and extends through the opening 78 up to the metal housing 40.
As shown in the partial views of
The burner holding ring 32 includes a flange 33 extending downwardly up to the top surface 80. The burner holding ring 32 is fixed to the base 12 by means of a crimping connection of the top surface 80 of the metal housing 40 with the flange 33. As shown in
As shown in
As already explained, the operating circuit 50 comprises an ignitor for igniting an electrical arc discharge within the discharge vessel 18. The ignitor includes an ignition transformer 54 as shown in
The insulation compound 43 is a silicone insulation compound, which is filled into the insulation chamber 42 in upside-down orientation, as e.g. shown in
During filling of the insulation chamber 42 in the upside-down orientation as shown in
The central opening 28 in the top wall 38 of the holder 30, through which the burner 14 protrudes, is connected with a further opening in the top wall 38, through which the return contact 24 enters the base 12. The retention wall 46 is arranged to surround both openings. Further, the top wall 38 of the holder 30 includes, as already explained, an opening 78 for the ground contact spring 76. The opening 78, as shown in
As shown in the figures, in particular
While the invention has been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered illustrative or exemplary and not restrictive; the invention is not limited to the disclosed embodiments.
Variations of the disclosed embodiment can be understood and effected by those skilled in the art in practicing the claimed invention, from a study of the drawings, the disclosure and the appended claims. In the claims, the word “comprising” or “including” does not exclude other elements, and the indefinite article “a” or “an” does not exclude a plurality. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage. Any reference signs in the claims should not be construed as limiting the scope.
This application is the U.S. National Phase application under 35 U.S.C. §371 of International Application No. PCT/IB2013/052929, filed on Apr. 12, 2013, which claims the benefit of U.S. Provisional Patent Application No. 61/639,113, filed on Apr. 27, 2012. These applications are hereby incorporated by reference herein.
Filing Document | Filing Date | Country | Kind |
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PCT/IB2013/052929 | 4/12/2013 | WO | 00 |
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WO2013/160794 | 10/31/2013 | WO | A |
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