WO2007110318A1

WO2007110318A1 - Method for producing an electrically insulating cast body and a base for a lamp

Info

Publication number: WO2007110318A1
Application number: PCT/EP2007/052329
Authority: WO
Inventors: Manfred RÖHL
Original assignee: Osram Gesellschaft mit beschränkter Haftung
Priority date: 2006-03-28
Filing date: 2007-03-13
Publication date: 2007-10-04
Also published as: DE102006014695A1; EP1999773A1

Abstract

The invention discloses a method for producing an electrically insulating cast body in at least one casting area, in particular in an accommodating area for electrical components of a discharge lamp. According to the invention, at least one buffer zone is formed at a predetermined position of the cast body. Furthermore, the invention discloses a base for a lamp, in particular for a high-pressure discharge lamp, having at least one accommodating area for electrical components of the lamp, at least sections of which are embedded in an electrically insulating casting compound, which forms a cast body. According to the invention, a buffer zone is formed at at least one predetermined position of the cast body.

Description

description

Method for producing an electrically insulating potting body and a base for a lamp

Technical area

The invention relates to a method for producing an electrically insulating potting body in at least one potting space, in particular in a receiving space for electrical components of a discharge lamp and a base for a lamp, in particular for a high-pressure ^¬ discharge lamp, with at least one receiving space for e- lectric components of the lamp which are at least partially ^¬ embedded in an electrically insulating potting ^¬ embedded.

State of the art

The inventive method can in principle be used for the production of electrically insulating potting bodies for different applications. However, the main field of application of the method is likely to be the encapsulation of receiving spaces for electrical components in the base of a high-pressure discharge lamp.

Such high-pressure discharge lamp is at ^¬ game as known 1511130 Al by the applicant be ^¬ from EP. In these conventional lamps, a base with an ignition transformer arranged therein is used for generating the ignition voltage for the discharge lamp, in which an electrical contact element is arranged, which produces a voltage output of the ignition transformer with ei ^¬ ner socket side of the discharge vessel of the lamp. running power supply connects. In this solution, the contact element is to improve the electrical Isolie ^¬ tion in sections, in the base made of plastic is ^¬ embeds. The base has two chambers, wherein a first end of the electrical contact element extends into the first chamber and the second end of the contact element is accessible from the second chamber. The ignition transformer is arranged in the first chamber and its ignition voltage output connected to the first end of the Kontaktele- ment, while in the second chamber further electronic components of the ignition device of the discharge lamp are housed, the lower ^{Anforderun ¬} conditions to the voltage isolation as the ignition transformer. The second end of the contact element is accessible from the second chamber in order to be connected to the power supply led out of the discharge vessel near the base. For this purpose, the power supply is introduced into a bore of the second end of the contact element and welded thereto. This allows a separate spatial arrangement of the high voltage leading ignition transformer. In order to improve the high-voltage resistance of the lamp cap, the connection point lying in a receiving ^¬ space between the second end of the contact element and the end of the socket near power supply and the ignition transformer is embedded in an electrically insulating potting compound, which is introduced into the chambers and an electrical Insulation forms between the electrical components, in particular between the contact element and the primary winding of the ignition transformer. That the high-voltage strength in many cases the high Anforde ^¬ stanchions A disadvantage of such Vergusskörpern is not sufficient to the insulation reliability, as it fertil during the curing of the potting material caused by vibration or temperature change in the operation of the lamp to material stresses in the cast body and thereby a crack and cavitation may occur. Along such cracks or voids electrical insulation is impaired and short circuits between the electrical components can occur. Furthermore, it is disadvantageous that such a cast body due to the aufwändi ^¬ gen tuning of materials of construction, Vergussgeometrie and potting material are complicated and expensive to manufacture, since the dimensional changes of the comparison determines the cast body through calculations or preliminary experiments and must be taken into account.

Presentation of the invention

The invention has the object of providing a procedural ^¬ ren for producing an electrically insulating cast as well as a socket for a lamp, and in particular to provide for a discharge lamp in which ge ^¬ genüber conventional solutions provides improved electrical isolation with minimal expenditure on apparatuses ,

This object is achieved by a method for producing an electrically insulating potting lamp in at least a casting space, in particular in a receiving space for electrical components of a discharge ^¬, wherein at least one buffer zone to balance on ^¬ kicking volume changes in a predetermined positioning tion of the potting body is formed. Under the Beg ^¬ reef buffer zone is especially meant a in the Vergusskör ^¬ by trained cavity.

The object is further achieved by a base for a lamp, in particular for a Hochdruckentla ^¬ tion lamp, with at least one receiving space for electrical components of the lamp, which are at least partially embedded in an electrically insulating potting compound, wherein at least one predetermined position of the potting a buffer zone is designed to compensate occurring volume changes.

Particularly advantageous embodiments of the invention are described in the dependent claims.

Enables the inventively constructed buffer zone an improved high-voltage strength light of the Ver ^¬ cast body, also high demands on the isolati ^¬ onssicherheit sufficient since the ratureinflüsse on at a defined Positi ^¬ in potting formed buffer zone has a volume ^¬ change of the cast body by shrinkage or temperature allowed. In other words, the potting body ^¬ occurring volume changes is able to compensate by positive changes in the buffer zone. As a result, the tensile stresses occurring in the potting body, for example during curing of the potting compound or in the event of temperature changes, are minimized, so that no undefined cracks, voids or wall detachments and thus no dangerous crack bridges arise between the electrical components to be insulated. Short circuits between the electrical components are thereby effectively prevented. The wide can ren due to the stress-reducing buffer zone on a complex coordination of the construction material ^¬ lien, Vergussgeometrie and potting compound, such as are 1511130 Al required for egg ^¬ ner solution according to the EP, largely dispensed with, with the production of the cast body or the lamp base at verringer ^¬ th manufacturing costs further simplified. Despite the buffer zone, the high-voltage safety of the electrical components is given, since the remaining wall thicknesses in the potting body are large enough and free of cracks or voids, in order to effect a sufficient electrical insulation between the electrical components.

According to a particularly preferred embodiment of the invention, at least one molded part is introduced into the casting space in a first working step. In ei ^¬ nem further operation, an electrically insulating potting compound is poured into the Vergussraum, wherein the potting compound after curing of the potting body at least partially detached from the molding, so that the buffer zone is formed.

The molded part is preferably formed of a material selected from ^¬ which has up a reduced adhesion to the potting material over the embedded electrical components and over the circumferential wall of Vergussraumes. Due to the poor adhesion of the potting compound to the molded part and to the peripheral wall of the potting space, potting dissolves from the molded part at higher material tensions before the material stress leads to uncontrolled crack formation in the potting body with the mentioned risk of short circuit between the electronic components to be insulated. By a suitable molding advertising and positioning of the molded part in the cast body, the type and location of the buffer zone influenced ^¬ to.

It has proven to be particularly advantageous if the molded part is made of polyethylene (PE) or polytetrafluoroethylene (PTFE), since these materials have a relatively low adhesion to the casting compound.

The potting compound is preferably a silicone, for example a two-component silicone system using fertil. These are due to their breakdown and creep ^¬ current resistance and high elongation at break particularly suitable for high-voltage proof encapsulation of electronic components in the lamp technology.

The molded part preferably has a rounded shape at least in sections. In conjunction with the low adhesion of the molding on the molding material, it depends on ^¬ due to the rounded shape to the buffer zone ausbil ^¬ Denden detachment of the casting that are not sharp and not continue in the form of cracks in the cast body are limited ie locally. For example, the molded part is spherical, cylindrical or barrel-shaped and formed without undercuts.

In a preferred embodiment, the molding is a ball or cylinder body having a diameter in the range of about 3 to 10 mm, preferably about 5.5 mm.

As manufacturing technology particularly simple solution, it has been proven when the molding completely in the Potting compound is embedded and remains after curing in the potting.

In a variant according to the invention, the molded part is removed after the curing of the potting body. For this purpose, the molding is for example only portion ^¬ embedded in the casting compound so that a simp ^¬ ches remove possible after curing is.

According to one embodiment of the invention, the molded part has a reduced density relative to the potting compound, so that the molded article floats in the potting compound before curing. The floating on the surface on ^¬ form part can be removed or remain in the cast body after curing of the potting mass ^¬. For example, in this variant, the molded part is made of a material with a density reduced in relation to the density of the potting ^compound or as a hollow body.

The molded part is arranged in an inventive embodiment of the base in the space provided for electrical components receiving space, the Verguss ^¬ mass after curing is at least partially detached from the molded part, so that the buffer zone is formed.

In the receiving space of the base, for example, a transformer is arranged, which is connected to a Kontaktele ^¬ ment, wherein the molded part is preferably introduced in the connection region of the transformer with the Kontaktele ^¬ ment in the potting compound. Brief description of the drawings

The invention will be explained in more detail with reference to a ^{Favor ¬} th embodiment. Show it:

1 shows a schematic representation of a preferred embodiment of the socket according to the invention with the discharge lamp and

Figure 2 is a plan view of the base of Figure 1 prior to assembly of the lid.

Preferred embodiment of the invention

The invention will be explained below with reference to a single-ended high-pressure discharge lamp for a driving ^¬ zeugscheinwerfer. As already mentioned, the inventive method for producing a potting body and the base are not limited to such lamp ^¬ types.

1 shows a schematic representation of a he ^¬ inventive base 1 with an inserted into this high-pressure discharge lamp 2. This has a dis- charges tube 4 made of quartz glass having an inner space 6 and two diametrically arranged, sealed end portions 8, 10, in each of which a current supply 12 , 14 is arranged. In the interior 6 of the discharge vessel 4 protrude two diametrically arranged electrodes 16, 18 which are each connected via a molybdenum foil 20 with one of the power supply lines 12, 14 and between which forms a gas discharge during lamp operation. In the inner ^¬ space 6 of the discharge vessel 4 is an ionizable filling including, for example, high purity xenon gas and multiple metal halides. The Ent ^¬ discharge vessel 4 is surrounded by an outer bulb 22 made of quartz glass absorbing ultraviolet radiation is provided Do- animal materials. The base 1 consists Wesent ^¬ union is not of a base outer part 24 in which a ^¬ posed base inner part is inserted in which the Ent ^¬ discharge vessel 4 and the outer piston are fixed 22nd The socket outer part 24 is formed as a plastic injection molded part and has a receiving portion 26 on the lamp side for receiving the base inner part. The base 1 can be closed on the bottom side via a cover 28 and has a connection socket 30 for electrical contacting.

As shown in Figure 2 reveals that the ckelaußenteils 24 shows a plan view of the side facing away from the discharge vessel 4 side So ^¬ of Figure 1 prior to assembly of the lid 28, the base outer part 24 has a chen in Wesentli ^¬ square base body 32 via a Side wall 34 defines an interior 36. This is divided by a partition 38 into two chambers 40, 42 of different sizes. In the first chamber 40 (Transformator ^¬ torraum) a rod core transformer 44 is arranged (dashed lines in Figure 2), which serves as an ignition transformer for accommodated in the base 1 pulse ignition device (not shown) of the high pressure discharge lamp 2. The rod core transformer 44 has a ferrite core on which a secondary winding is wound (not shown). The ferrite core and the secondary coil disposed thereon are almost entirely of the rod-core transformer 44 joined by the plastic sawn stationary housing 46 about ^¬. On the outer peripheral surface of the housing 46 is a primary winding 48 with three turns 50 consisting of a metal band arranged. The second chamber 42 forms a receiving space for further components (not shown) of the pulse ignition device. In the solar ckelaußenteil 24, an approximately L-shaped bent electrical ^¬ is embedded ULTRASONIC contact element 52 made of stainless steel. The contact element 52 has already been integrated in the production of the base outer part 24 by injection molding in the Kuntstoffspritzgussverfahren so that it is partially surrounded by the plastic of the base outer part 24 and only two ends 54, 56 of the contact element 52 are accessible for electrical contacting. The first end 54 of the contact element 52 extends into the transformer space 40 and will lead after the assembly of the rod core transformer 44 with a high voltage ^¬ connected to the secondary winding ignition voltage output 58 of the rod core transformer 44 by means of laser beam welding ^¬ welded. The second end 56 of the con ^¬ tact element 52 is partially expanded radially and provided with a through hole 60 for receiving the inner socket near power supply 14 of the discharge lamp 2 (see Figure 1). In order to mount the socket inner part in the base outer part 24, the power supply 14 of the discharge lamp 2 close to the socket is inserted into the through hole 60 of the second end 56 of the contact element 52 formed as an embossed mounting. The threaded through the passage ^¬ bore 60 end of the power supply 14 is welded to the second end 56 of the contact element 52 ^{¬ by} laser beam welding. The power supply 12 of the remote from the base end portion 8 of the Entladungsgefä ^¬ SLI 4 is a surrounded by an insulating sleeve 62 current return 64 (see Figure 1) by a hollow web 66 of the base outer part 24 is guided into the receiving space 42 and connected to a mounting plate, not shown elekt ^¬ risch whose shape corresponds approximately to the cross section of the receiving space 42. On the mounting plate of the starting capacitor of the pulse and other electronic components are, for example, the discharge lamp 2 arranged ^¬. The mounting board is on Durchbrü ^¬ che, in the holding elements 68 of the base outer part 24 a ^¬ grab fixed in the receiving space 40, wherein the mounting plate is inserted into the base outer part 24 such that mounted on the mounting plate Bauele ^¬ ments in the receiving space 42nd protrude the base outer part 24. In the side wall 34 of the transformer space 40 and the partition wall 38, three guides 70 for receiving appropriate projections on the housing of the rod core ^¬ transformer 44 are formed so that the position of the rod core transformer 44 is fixed in the transformer space 40. In addition to the guides 70 of the transformer room 40 is a knob-shaped pre-crack 72 is formed on the Bo ^¬ which defines together with the first end 54 of the contact element 52, the installation depth of the rod core ^¬ transformer 44 in the transformer room 40th The rod core transformer 44 is after insertion into the transformer space 40 and the contacting of the high-voltage leading Zündspannungsausgangs 58 with the con ^¬ tact element 52 in an electrically insulating Vergussmas ^¬ se 74, for example silicone, embedded. The Verbin ^¬-making region of the contact element 52 with the power supply line 14 is also tet eingebet- in the potting compound 74th In a method according to the invention for producing an electrically insulating potting body 76 in the receiving space 40 (transformer space) of the discharge lamp 2, at least one buffer zone 78 is formed at a predetermined position of the potting body 76. For this purpose, in a first step, a mold part 80, wherein ^¬ play, of a not shown mold part dispenser in the casting space, ie the space transformer 40 is introduced. In the illustrated embodiment of the invention, the molded part 80 is introduced in the connection region of the ignition voltage output 58 of the rod core transformer 44 with the contact element 52 in the transformer chamber 40 and is located on the ignition voltage output 58. In one embodiment, not shown, a further molded part 80 is introduced in the connection region of the contact element 52 with the power supply 14. In a further operation, the electrically insulating potting compound 74 is filled into the potting space 40, wherein the potting body 76 detaches from the molding 80 during curing of the potting compound 74, so that the buffer zone 78 is formed. The entste to the mold part 80 ^¬ rising, the buffer zone 78 forming cavity in the encapsulation ^¬ body 76 compensates volume changes of the potting body 76 by shrinkage or temperature influences, so that the material stresses are minimized and cracks, cavities, as well as wall separations can be effectively prevented in the potting 76th The potting body 76 is thus able to compensate occurring volume changes by changes in shape in the region of the buffer zone 78. Thus, the tensile stresses in the cast body 76, for example in the Aushär ^¬ processing of the potting compound 74 or occurring with temperature changes can be reduced so that no un- defined cracks, voids or wall detachments and thus no dangerous crack bridges between the electrical components to be isolated, in particular between the contact element 52 and the primary winding 48, arise. May further due to the stress-reducing buffer zone 78 to an extensive adjustment of the Konstrukti ^¬ onsmaterialien, Vergussgeometrie and potting compound ver ^¬ be dispensed with, the production of the casting ^¬ body 76 and the lamp base 1 at reduced manufacturing costs further simplified. Despite the buffer zone 78, the high-voltage safety of electrical components is ^¬ given, since the remaining wall thicknesses in Vergusskörper 76 are large enough and free of cracks or voids to cause sufficient electrical insulation between the contact element 52 and the primary winding 48.

The molded part 80 is in the illustrated embodiment of a material, for example polyethylene (PE) or polytetrafluoroethylene (PTFE), formed out, compared to the einzubettenden Stabkerntrans ^¬ formator 44 and the peripheral wall 34 of the Vergussraumes 40 a reduced adhesion the Vergussmas ^¬ se 74 has. Due to the poor adhesion of the Ver ^¬ casting compound 74 on the mold member 80, the potting 76 replaces in material stresses from the molded part 80 before the material stress to uncontrolled cracking in the cast body 76 with said risk of short circuit between the contact element 52 and the primary winding 48 of the rod-core transformer 44 or leads to a wall detachment. Through a suitable shaping and positioning of the mold part 80 in the potting body 76, the type and Po ^¬ can sition of the buffer zone 78 forming detachment be influenced. According to the illustrated embodiment of the invention, the molded part 80 is formed as a ball of polytetrafluoroethylene having a diameter D of about 5.5 mm, which is completely embedded in the potting compound 74 and remains in the potting body 76 after curing. In a variant of the invention, not shown, the molded part 80 is cylindrical, barrel-shaped or formed with another rounded shape at least in sections. In connection with the material-related low adhesion of the molding 80 on Verguss ^¬ material occurs due to the rounded shape to the buffer zone 78 forming replacements of the potting body 76, which are not sharp-edged and not continue in the form of cracks in the potting 76, ie limited locally are.

In a variant not shown, the mold part is ent 80 after curing of the potting 76 ^¬ removed. For this purpose, the molded part 80 is embedded, for example, only from ^¬ cut in the potting compound 74, so that a simple removal after curing is possible. For this purpose, the molding 80 may have an opposite of the sealing compound 74 reduced density, so that the mold ^¬ part 80 before curing in the potting material 78 floats on ^¬. The embedded on the surface molding 80 can be removed from the potting body 76 after curing of the potting compound 74.

The inventive method is not limited to the Her ^¬ position of an electrically insulating potting 76 in a base 1 of a discharge lamp 2 is limited, but the method for insulating embedding different known from the prior art e- lektrischer components can be used. Furthermore, it is possible to provide a plurality of molded parts 80 in a receiving space or a plurality of receiving spaces. Essential to the invention is the formation of at least one buffer zone 78 at a predetermined position of the potting body 76, so that the potting body 76 is able to compensate occurring volume changes due to changes in shape in the region of the buffer zone 78.

Disclosed is a method for producing an electrically insulating potting body 76 in at least ei ^¬ nem potting space 40, in particular in a receiving space for electrical components 44, 52 of a discharge lamp 2. According to the invention, at least one buffer zone 78 at ei ^¬ ner predetermined position of the potting 76th out ^¬ forms. Further disclosed is a base 1 for a lamp 2, particularly for a high pressure discharge lamp, with at least one receiving space 40 for electrical construction ^¬ parts 44, 52 of the lamp 2, which are at least partially eingebet in an electrically insulating potting compound 74 ^¬ tet comprising a potting body 76 trains. According to the invention, a buffer zone 78 is formed at at least one predetermined position of the potting body 76.

Claims

claims

1. A method for producing an electrically insulating potting (76) in at least one Vergussraum (40), in particular in a receiving space for electrical

Components (44, 52) of a discharge lamp (2), characterized in that at least one buffer zone (78) for compensating occurring volume changes at a predetermined position of the potting body (76) is formed.

2. The method of claim 1, comprising the steps of:

- Introducing at least one molding (80) in the Vergussraum (40);

- Introducing an electrically insulating potting compound (74) in the Vergussraum (40), wherein the potting compound (74) after curing of the potting (76) at least partially detached from the molding (80), so that the buffer zone (78) is formed ,

3. The method of claim 2, wherein the molded part (80) is formed of a material, compared to the einzubettenden electrical components (44, 52) and / or against the wall (34) of the Vergussraumes (40) has a reduced adhesion to the potting compound (74).

4. The method of claim 2 or 3, wherein the molding (80) made of polyethylene (PE) or polytetrafluoroethylene

(PTFE) is.

5. The method according to any one of claims 2 to 4, wherein the potting material (74) made of silicone, preferably of two ^¬ component silicone rubber.

6. The method according to any one of claims 2 to 5, wherein the molded part (80) at least partially has a rounded ^¬ te form.

7. The method according to any one of claims 2 to 6, wherein the molded part (80) is spherical, cylindrical or tonn-shaped.

8. The method according to any one of claims 2 to 7, wherein the molded part (80) is a ball or cylinder body and has a diameter (D) in the range of about 3 to 10 mm, preferably of about 5.5 mm.

9. The method according to any one of claims 2 to 8, wherein the molding (80) is completely embedded in the potting compound (74).

10. The method according to any one of claims 2 to 8, wherein the molded part (80) sections in the potting compound

(74) is embedded.

11. The method according to any one of claims 2 to 10, wherein the molded part (80) one opposite the potting compound

(74) has reduced density such that the molding (80) floats in the potting compound (74) prior to curing.

12. The method of claim 10 or 11, wherein the molding (80) after curing of the potting compound (74) is removed from the potting.

13. base (1) for a lamp (2), in particular for a high pressure discharge lamp, with at least one on ^¬ receiving space (40) for electrical components (44, 52) of the lamp (2), which at least in sections in an elec- embedded potting compound (74), which forms a potting body (76), characterized in that at least one predetermined position of the potting (76) is formed a buffer zone (78) for compensating occurring volume changes.

14. A base according to claim 13, wherein in the receiving ^¬ space (40) at least one mold part (50) and the casting compound (74) after curing, at least from ^¬ is section-wise separated from the molded part (80), so that the Buffer zone (78) forms.

15. Socket according to claim 14, wherein the molded part (80) is formed from a material which has a reduced adhesion to the potting compound (74) in relation to the electrical components (44, 52) to be embedded and / or in relation to the potting space (40).

16. Socket according to one of claims 14 or 15, wherein in the receiving space (40) a transformer (44) is arranged, which is connected to a contact element (52), wherein the molded part (80) in the connecting region of the transformer (44 ) is introduced with the contact element (52) in the Ver ^¬ casting compound (74).