DE102006033674A1 - Discharge lamp with a discharge vessel - Google Patents

Abstract

The invention relates to a discharge lamp having a discharge vessel (2) which comprises at least three vessel parts (21, 22, 23) which are connected to attachment webs (24, 25) to form a coherent discharge space (2a) and a first electrode (6). which extends at least partially in a first vessel part (21, 22, 23), and a second electrode (7) which extends at least partially in a second vessel part (21, 22, 23), wherein an InAgHg source (9 ) is contained in a tube piece (8) which is connected to a third vessel part (21, 22, 23).

Description

Technical area

The The invention relates to a discharge lamp with a discharge vessel, which comprises at least three vessel parts, which connected with lugs to a contiguous discharge space are. The discharge lamp has a first electrode, which extends at least partially into a first vessel part, and comprises Furthermore, a second electrode, which at least partially extends into a second vessel part.

State of the art

discharge lamps are in more diverse Design and application known. Gas discharge lamps have in recent years, especially in the form of compact fluorescent lamps widespread application found. These discharge lamps usually have a discharge vessel, which for example, several vessel parts in Shape of curved Includes pipes.

Furthermore feature Conventional discharge lamps over a Hg source in the discharge vessel, from the In operation, a suitable amount of Hg evaporates and through the corresponding Hg lines essential for UV production contributes in the discharge vessel. Basically includes the term Hg-Quelle in principle two functions, namely the one of a Hg donor. This is a material or a body, in which the Hg is contained, for example, liquid Hg itself, or a Amalgam. Further, however, there are also frequently independently executed steam pressure regulating Hg elements, such as work amalgam. Again, the amalgam has the functions the introduction of the mercury into the lamp and the rules of the Vapor pressure. In principle, it can also be provided that the two amalgam bodies can be used are, one of which has the function, the mercury in the lamp to bring and the other has the function to regulate the vapor pressure.

Around defined relationships for the In the operation to produce prevailing steam pressure of Hg, is a Vapor pressure regulating element, such as an amalgam needed. The Temperature of the vapor pressure regulating element controls the vapor pressure of the Hg in the discharge.

Known is also, in the region of the discharge tube ends relative thereto to provide thin pump heads, on the one hand in the manufacture of the gas discharge lamp as a pump tube, So for evacuation and filling of the discharge vessel, serve and on the other hand also record the Hg source. So this is in a thinner one Housed in a tube approaching from one of the discharge tube ends in usually in the electronic ballast or its housing inside protrudes when the discharge lamp has an integrated ballast.

In In this context, discharge lamps are known by the applicant, where such a pump stalk or such a pump tube with a BilnHg amalgam contained therein is arranged on a discharge tube of the discharge vessel, in which no electrode coil is arranged.

Furthermore Discharge lamps are known in which a pump tube to a discharge tube arranged the discharge vessel is, in which also an electrode coil is arranged. In these Lamps is located in the pump tubes a PbBiSnHg amalgam or an InSnPbHg amalgam. In the known arrangements and configurations the discharge lamps and amalgams used is the luminous flux-temperature behavior of the discharge lamp not completely satisfied stellend.

Presentation of the invention

Therefore It is an object of the present invention, a discharge lamp to create what an improved luminous flux-temperature behavior having.

These Task is by a discharge lamp, which the characteristics after Claim 1 has solved.

A Discharge lamp according to the invention comprises a discharge vessel, which has at least three vessel parts. The vessel parts are with connecting bridges so interconnected that they in their entirety represent the discharge vessel and a common related Make discharge space. A first electrode of the discharge lamp extends at least partially into a first vessel part, and a second electrode extends at least partially in a second vessel part. The Discharge lamp further comprises a tube piece which is connected to a third vessel part is, wherein in the tube piece a InAgHg source or an InAgHg amalgam is included. By use this specific amalgam and the arrangement of this in a vessel part, in the electrodes of the discharge lamp are not arranged, can the operation of the lamp with a significantly improved luminous flux-temperature behavior are allowed.

Especially this InAgHg amalgam is characterized by an increased operating temperature and a very wide plateau of opti for light generation paint Hg vapor pressure as a function of temperature.

Prefers the tube piece is designed as a pump tube. Advantageously, the pump tube for pumping and filling the Discharge lamp used in the production. An additional Attaching such a tube piece is therefore not required. The tube piece can thus multifunctional in different production and operating phases the discharge lamp can be used. The use of the InAgHg amalgam is much less expensive in such a configuration of a tube piece.

Furthermore it is also not required by an arrangement of the InAgHg amalgam to mount this on a special Amalgam Vehicle. The placement the InAgHg source in such a tube piece, which is designed as a pump tube is needed about that In addition, a significantly lower material and manufacturing costs as the placement on a special amalgam carrier, which about that also in the vicinity an electrode of the discharge lamp is arranged.

The Discharge vessel comprises at least three substantially parallel to each other, elongated Pipe parts, wherein the tube piece to the one Pipe part is arranged, which in each case with a lug with is connected to the two other pipe parts. The InAgHg source is thus about it arranged also in a tube part, which is formed centrally in the discharge vessel. The for the operation of the discharge lamp advantageous central arrangement of this Source can be made possible become.

At least one of the vessel parts, prefers all vessel parts, are as curved Tube units formed. Preferably, a pipe unit is curved so that it has a U-shape. The U-shape is preferably designed that each tube unit at least two substantially parallel to each other includes oriented pipe parts. The tube piece is preferred to that Tube unit arranged, each with a lug with connected to the other two tube units. The pipe unit, in the InAgHg source attached with the tube piece is, is thus preferably in the middle of the discharge vessel.

The InAgHg amalgam is preferably formed without further additional elements or atomic additives. Since the InAgHg amalgam causes no handling difficulties, and always has sufficient viscosity is a Beigeben of eg Ni or Te not required.

The Ag content of the InAgHg compound is preferably between three and six, in particular 4. The Hg content of the InAgHg compound is advantageously between 6 and 12, in particular 10. A particularly advantageous amalgam composition is therefore formed by the composition InAg ₄ Hg ₁₀ ,

The Discharge lamp can be designed with an integrated ballast be. It can also be provided that the discharge lamp without an integrated ballast is formed and only with an external electronic ballast is electrically contacted for operating the discharge lamp.

The Discharge lamp is preferably designed as a compact fluorescent lamp.

Short description of the drawing (s)

One embodiment The invention is explained in more detail below with reference to schematic drawings. It demonstrate:

1 a side view of a discharge lamp according to the invention;

2 a plan view of the discharge lamp according to 1 ; and

3 an enlarged view of a partial section in 1 ,

Preferred embodiment of invention

In The figures are the same or functionally identical elements with the provided the same reference numerals.

In 1 is a side view of a compact fluorescent lamp 1 shown which a discharge vessel 2 includes. The discharge vessel 2 is with a housing 3 connected, in which an unillustrated ballast is arranged. The compact fluorescent lamp 1 is formed in the embodiment with an integrated ballast. It can also be provided that the compact fluorescent lamp 1 is operable with a separate, external ballast. It can then be provided that, for example, four pins from a socket 4 protrude the lamp, which are provided for contacting the ballast. It can also be provided that the lamp are designed with these four contact pins for a throttle-starter operation. It can also be provided that from the pedestal 4 the lamp only protrude two pins, whereby the lamp is designed for operation in throttle-starter circuit with integrated glow starter.

In the exemplary embodiment, the compact fluorescent lamp comprises 1 the pedestal 4 which is attached to the housing 3 followed. Furthermore, in a known manner, electrical contact pins 5a and 5b on the pedestal 4 arranged.

The discharge vessel 2 includes in the exemplary embodiment three vessel parts, which are curved tube units 21 . 22 and 23 are formed. Every tube unit 21 to 23 is designed in the embodiment U-shaped.

The pipe unit 21 is curved so that they are two substantially parallel to each other formed pipe parts 21a and 21b includes. In an analogous way, the second pipe unit 22 curved so that they have two substantially parallel, elongated tube parts 22a and 22b ( 2 ) having. The third pipe unit is also the same 23 shaped so that they are two substantially parallel, elongated tube parts 23a ( 2 ) and 23b having. The pipe units 21 to 23 are arranged so that the pipe parts 21a . 21b . 22a . 22b . 23a and 23b are positioned substantially parallel to each other.

As in 1 can be seen, is the orientation of the U-shaped tube units 21 to 23 arranged so that the free ends in the housing 3 extend. To form a common contiguous discharge space 2a inside the discharge vessel 2 are the tube units 21 to 23 through two connecting bridges 24 and 25 ( 2 ) connected with each other.

The attachment of this approach webs 24 and 25 is designed so that these in the embodiment within the housing 2 are located. The diameter of these lugs 24 and 25 is much smaller than the diameter of the pipe parts 21a . 21b . 22a . 22b . 23a and 23b the pipe units 21 to 23 , Exemplary and common diameter for the lugs 24 and 25 amount to about 4 mm. Usual and known exemplary diameter for the pipe parts 21a to 23b amount to about 12 mm. The values mentioned are of course only exemplary and can vary in many ways.

The compact fluorescent lamp 1 further comprises a first electrode 6 in the form of an electrode coil and a second electrode 7 , which is likewise designed as an electrode coil. The first electrode 6 extends inside the housing 3 in the front or free end of the pipe part 21a , The second electrode 7 is also inside the case 3 arranged so that they are at least partially in the pipe part 22a the pipe unit 22 extends. The two electrodes 6 and 7 are thus in different vessel parts or tube units 21 and 22 arranged.

The schematic representation and arrangement of the electrodes shown 6 and 7 is just an example. It can also be provided that the electrodes 6 and 7 so in the respective pipe parts 21a and 22a are arranged, that the coils at least partially outside the housing 3 are located.

Furthermore, the compact fluorescent lamp includes 1 as a pump tube 8th trained tube piece, which for receiving an InAgHg source 9 ( 3 ) is trained. The pump tube 8th is multifunctional usable and serves in the manufacture of the lamp for pumping and filling the compact fluorescent lamp 1 and subsequently for receiving this InAgHg amalgam.

In the exemplary embodiment, this pump tube 8th inside the case 3 arranged and extends partially into the third vessel part and the third tube unit 23 , In the embodiment, the pump tube 8th on the pipe part 23b the third pipe unit 23 arranged. As is apparent from the schematic representation in 1 can be seen, the pump tube extends 8th at the free front end of the pipe part 23b into this.

In the in 1 shown top view of the compact fluorescent lamp 1 is the arrangement of the tube units 21 to 23 shown. It can be seen that these are placed obliquely to each other and the discharge vessel 2 is formed substantially triangular in this plan view.

It can be seen that the pump tube 8th approximately in the middle of the entire discharge vessel 2 and thus the discharge path is arranged. It can also be provided that the pump tube 8th with the InAgHg source 9 at the appropriate place of the pipe part 23a is arranged. However, it can also be provided that this pump tube 8th with the InAgHg source 9 at the appropriate place of the pipe part 21b or the pipe part 22b is arranged. The only important thing is that a specially designed InAgHg source 9 in a vessel part of the discharge vessel 2 is arranged, in which no electrode 6 or 7 is positioned.

In 3 is an enlarged partial section I off 1 shown.

It can be seen that the pump tube 8th is arranged so that it is partially in the discharge space 2a extends and thus at least partially within the pipe part 23b is arranged.

The InAgHg source 9 is spherical. The amalgam composition is formed in the embodiment as InAg ₄ Hg ₁₀ and in the front Area of the pump tube 8th positioned. As can be seen, is the front end of the pump tube 8th curved and on the one hand has a tapered area 81 and an adjoining re-expanded area 82 on. In this expanded area 82 is an exit opening 83 educated. At an optimum temperature for standard applications, ie ambient temperatures of the compact fluorescent lamp 1 as well as the burning position, is achieved between the spherical body of InAgHg source 9 and the front end 82 of the pump tube 8th a retaining body in the form of a stainless steel ball 10 brought in. About the height of this stainless steel ball 10 and thus their diameter can be the operating temperature of the amalgam body or the InAgHg source 9 be set as a function of ambient temperature. In the exemplary embodiment, the pump tube protrudes 8th with a depth t of about 2.5 mm in the discharge space 2a into it. The stainless steel ball 10 has a diameter of about 2 mm in the embodiment. The temperature of the pump tube 8th housed InAgHg source 9 strongly depends on the ambient temperature in the ballast housing 3 which in turn depends on the external ambient temperature, the operating time and also the installation position of the compact fluorescent lamp 1 depends. The inventive arrangement of the amalgam and the specific use of an InAgHg source 9 A significantly improved insensitivity to fluctuations in the ambient temperature and changes in the installation position can be achieved.

The pump tube 8th is in the front or free end 231b of the pipe part 23b arranged. The InAgHg amalgam has a much broader temperature range over which the Hg vapor pressure over the amalgam is optimally range above the light generation in fluorescent lamps than is the case with other amalgams such as BilnHg amalgam. The temperature range with optimum Hg vapor pressure over this InAgHg amalgam ranges from about 105 ° C to about 155 ° C. In addition, this InAgHg amalgam is also lead-free and in this context has a distinct advantage over the amalgams PbBiSnHg or InSnPbHg. In contrast to the BilnHg amalgam, which has a Hg concentration of 3% by weight, the InAgHg amalgam has an Hg concentration of the order of 10% by weight. This has the advantage that the absolute weight of the amalgam body is significantly lower when using InAgHg than with another amalgam, for example BilnHg. The advantage lies in a lower material usage and in the significantly lower total weight of the amalgam body or the InAgHg source. In addition, only one InAgHg source is sufficient 9 or such an amalgam ball, which is also lighter and smaller than a BilnHg ball. The lower weight of this InAgHg ball also increases the risk of dripping past the retention body or the stainless steel ball 10 , significantly reduced.

Claims (12)

Discharge lamp with a discharge vessel ( 2 ), which at least three vessel parts ( 21 . 22 . 23 ), which are provided with attachment webs ( 24 . 25 ) to a contiguous discharge space ( 2a ) and a first electrode ( 6 ), which at least partially in a first vessel part ( 21 . 22 . 23 ) and a second electrode ( 7 ), which at least partially in a second vessel part ( 21 . 22 . 23 ), characterized in that an InAgHg source ( 9 ) in a tube piece ( 8th ) containing a third vessel part ( 21 . 22 . 23 ) connected is. Discharge lamp according to claim 1, characterized in that the tube piece as Pumprohr ( 8th ) is trained. Discharge lamp according to Claim 2, characterized in that the pump tube ( 8th ) for pumping and filling the discharge lamp ( 1 ) is usable in the production of these. Discharge lamp according to one of the preceding claims, characterized in that the discharge vessel ( 2 ) at least three substantially mutually parallel, elongated tube parts ( 21a . 21b ; 22a . 22b ; 23a . 23b ), wherein the tube piece ( 8th ) on the pipe part ( 21a . 21b ; 22a . 22b ; 23a . 23b ) is arranged, which in each case with a lug ( 24 . 25 ) with the two other pipe parts ( 21a . 21b ; 22a . 22b ; 23a . 23b ) connected is. Discharge lamp according to one of the preceding claims, characterized in that the vessel parts curved tube units ( 21 . 22 . 23 ) are. Discharge lamp according to claim 5, characterized in that at least one tube unit ( 21 . 22 . 23 ) has a U-shape. Discharge lamp according to Claim 5 or 6, characterized in that each tube unit ( 21 . 22 . 23 ) at least two mutually parallel pipe parts ( 21a . 21b ; 22a . 22b ; 23a . 23b ). Discharge lamp according to one of claims 5 to 7, characterized in that the tube piece ( 8th ) on the pipe unit ( 21 . 22 . 23 ) is arranged, which each with a lug ( 24 . 25 ) with the two other tube units ( 21 . 22 . 23 ) connected is. Discharge lamp according to one of the preceding claims, characterized in that the InAgHg source ( 9 ) is formed without additional atomic elements. Discharge lamp according to one of the preceding claims, characterized in that the Ag content of the InAgHg source ( 9 ) is between 3 and 6, in particular 4. Discharge lamp according to one of the preceding claims, characterized in that the Hg content of the InAgHg source ( 9 ) is between 6 and 12, in particular 10. Discharge lamp according to one of the preceding claims, which is a compact fluorescent lamp ( 1 ) is trained.