EP1882266A2

EP1882266A2 - Direct cooling of an amalgam reservoir in a low-pressure mercury amalgam lamp

Info

Publication number: EP1882266A2
Application number: EP06753735A
Authority: EP
Inventors: Alexei Voronov; Erich Arnold; Erik Roth
Original assignee: Heraeus Noblelight GmbH
Current assignee: Heraeus Noblelight GmbH
Priority date: 2005-05-20
Filing date: 2006-05-19
Publication date: 2008-01-30
Also published as: WO2006122818A3; DE102005023940B3; EP1783819A2; BRPI0611283A2; RU2007147462A; CN101180704A; WO2006122818A2; CA2547306C; US20060261735A1; RU2378737C2; EP1783819A3; US7683542B2; CA2547306A1; CN101180704B

Abstract

The invention relates to a low-pressure mercury amalgam lamp (1) arrangement comprising an amalgam reservoir (2) and a cladding tube (4) that surrounds the lamp. The lamp is provided with a mechanical contact with the cladding tube in the area of the amalgam reservoir. The invention is characterized in that the lamp is annularly enclosed by a metal strip (3) in the area of the amalgam reservoir (2). Said metal strip (3) rests against the lamp. Alternatively, a thermally conductive layer (3) is applied in the area of the amalgam reservoir. The metal strip or said layer represents the mechanical contact with the cladding tube.

Description

Direct cooling of an amalgam deposit in a mercury low-pressure amalgam radiator

The invention relates to a high-performance mercury low-pressure amalgam lamp with an amalgam depot and a cladding tube surrounding the lamp, and to a manufacturing method for arranging the lamp in the cladding tube.

In such radiators, as disclosed in DE 102 01 617 A1 and WO 96/31902, the radiator and the cladding tube in the discharge region and in particular in the field of amalgam deposits are separated by a radial air gap.

According to WO 96/31902 bulges of the lamp tube can be brought into contact with an outer cladding tube.

According to DE 102 01 617 A1, a heating element between the radiator and the cladding tube can be mounted so that it can also be used to cool the amalgam deposit.

It is the object of the present invention to operate such high-power radiators with a power density of more than 3 W / cm, in particular a power density of more than 5 W / cm and to make the simplest possible arrangements for this purpose.

To solve the problem, a thermally conductive layer is applied in the region of the amalgam deposit or the lamp is enclosed in the region of the amalgam deposit with a band.

Solutions to the problem are described in the independent claims. The dependent claims describe preferred embodiments. An apparatus according to the object is an arrangement of a mercury low-pressure amalgam lamp with an amalgam and a surrounding this envelope tube, wherein the lamp has a mechanical contact with the cladding tube and according to the invention the lamp in the region of the amalgam of one of the Lamp adjacent band is annularly enclosed and the tape is the mechanical contact with the cladding tube. Tapes made of metal or plastic, in particular fluoropolymers, have proven useful.

Instead of the band, a layer arranged in the region of the amalgam deposit between the radiator and the cladding tube is also suitable for heat transfer, in particular of metal or plastic.

Another object of the invention is an arrangement of a mercury low-pressure amalgam lamp with an amalgam depot and a surrounding this lamp cladding tube, wherein the lamp has a mechanical contact with the cladding tube and according to the invention the lamp in the field of amalgam deposits a layer for heat transfer in the field of amalgam from the radiator to the cladding tube, wherein the heat transfer coefficient of the layer corresponds at least to that of the cladding tube.

A procedural solution to the problem is a method for producing an assembly of high-performance mercury low-pressure amalgam lamps with an amalgam reservoir and a lamp surrounding the cladding tube, wherein a mechanical contact between the lamp and cladding tube in the region of the amalgam reservoir is prepared and used to cool the Amalgamdepots and according to the invention, in the region of the amalgam deposit, a band is applied annularly around the lamp.

In preferred embodiments

- If a band is tightened around the lamp, if the band is a metal or plastic band, the plastic band contains fluoropolymer, if the fluoropolymer is polytetrafluoroethylene (PTFE), if the band is a staple, if the staple is a metal staple, the staple is an elastomer , in particular fluoroelastomer, if lamps having a power density of more than 3 W / cm, in particular more than 5 W / cm in the region of the amalgam deposit, are enclosed by a band of metal or PTFE, the thickness of the band or of the heat transfer layer exceeds the tolerances of the radiator and the cladding tube, so that the radiator contacts the cladding tube only via the bands or the heat transfer layer,

the layer is a layer of fluoropolymer,

the fluoropolymer is a thermoplastic,

the thermoplastic has ether groups (PFA) and the thermoplastic fluoropolymer has side groups (FEP).

The radiator with the band or the layer for heat transfer can rest loosely or firmly in the cladding tube. In vertically operated spotlights attachment of the radiator in the cladding tube is advantageous to maintain contact.

The invention will be clarified by means of embodiments with reference to the drawings.

FIG. 1 shows an emitter with strapped band in the region of the amalgam depot.

FIG. 2 shows a thermal bridge between the radiator and the cladding tube.

In one embodiment of Figure 1, a radiator 1 is spanned in the region of the amalgam deposit 2 with a metal strip 3, wherein the metal strip 3 forms a mechanical contact with the cladding tube 4 after insertion into the cladding tube 4. The metal strip 3 can be fastened in the form of a screw clamp around the lamp tube. For mass production, the tightening of a metal strip 3 has proven itself analogous to packaging technology. For this purpose, the metal strip 3 is tightened with a tensioning device, superimposed and fastened the superimposed sections together. The fastening of the overlying ends with a sleeve has proven itself.

Based on this technology, radiators 1 with a power of 500 watts and 800 watts, or a power density of 3 W / cm and 5 W / cm are operated in an externally water-cooled cladding tube 4. For this purpose, the radiator 1 are pushed into the cladding tube 4, on which they ultimately rest with the metal strip 3. Particularly suitable is a cladding tube 4 made of quartz glass. For the radiator 1 with a power density of 3 W / cm is set with a 5 mm wide and 0.5 mm thick metal strip 3 made of stainless steel optimum operating temperature of the amalgam reservoir 2. For the radiator 1 with a power density of 5 W / cm, the bandwidth is doubled. Incidentally, the lamp corresponds to any mercury low-pressure amalgam lamp with an amalgam depot 2, as can be seen, for example, the cited prior art.

Alternatively, the band is formed as a clamp which clamps the radiator.

In a further embodiment of Figure 1, instead of the metal strip of the previous embodiments, a 1, 5 mm wide band of polytetrafluoroethylene (PTFE) is applied. For the radiator with a power density of 3 W / cm, the thickness of the PTFE tape is 0.7 mm and for the radiator with a power density of 5 W / cm, the thickness of the PTFE tape is 1 mm.

As a further embodiment, a fluoroelastomer is formed as a clamp which clamps the radiator.

In an embodiment according to FIG. 2, a heat transfer layer 3, with which the emitter 1 rests in the cladding tube 4, is arranged on the emitter 1 in the region of the amalgam deposit 2. The layer 3 can be applied with a paste according to the thick-film technique.

In a further embodiment according to FIG. 2, a layer 3 is arranged between the radiator and the cladding tube. For this purpose, the layer 3 is applied according to the paste technique and then sintered.

In a further embodiment according to FIG. 2, a thermoplastic layer of fluoropolymer, in particular PFA or FEP, is applied as a melt on the radiator or in the cladding tube or between the radiator and the cladding tube.

Claims

claims

1. Arrangement of a mercury low-pressure amalgam lamp (1) with an amalgam depot

(2) and a cladding tube (4) surrounding this lamp, wherein in the region of the amalgam depot (2) the lamp (1) has a mechanical contact with the cladding tube (4), characterized in that the lamp (1) in the region of the amalgam depot ( 2) is surrounded annularly by a voltage applied to the lamp (1) band (3) and the band

(3) represents the mechanical contact with the cladding tube.

2. Arrangement according to claim 1, characterized in that the band (3) is a metal band.

3. Arrangement according to claim 1, characterized in that the band (3) is a plastic band.

4. arrangement of a mercury low-pressure amalgam lamp (1) with an amalgam depot (2) and a lamp (1) surrounding the cladding tube (4), wherein in the region of the amalgam depot (2) the lamp (1) has a mechanical contact with the cladding tube (2) 4), characterized in that the lamp (1) in the region of the amalgam depot (2) has a plastic layer.

5. Arrangement of a mercury low-pressure amalgam lamp (1) with an amalgam depot (2) and a lamp (1) surrounding the cladding tube (4), wherein in the region of the amalgam depot (2) the lamp (1) has a mechanical contact with the cladding tube (2). 4), characterized in that the lamp (1) in the region of the amalgam depot (2) has a layer (3) for heat transfer from the radiator (1) to the cladding tube (4), wherein the heat transfer coefficient of the layer (3) at least the of the cladding tube (4).

6. A method for producing an arrangement of high-performance mercury low-pressure amalgam lamps (1) with an amalgam reservoir (2) and a lamp (1) surrounding the cladding tube (4), wherein a mechanical contact between the lamp (1) and cladding tube (4 ) in the region of the amalgam deposit (3) and used for cooling the amalgam deposit (2), characterized in that in the region of the amalgam deposit (2) a band (3) is annularly applied around the lamp (1).