DE4211163A1 - High-power floodlight with optimal heat dissipation - has resilient coupling between hottest parts of lamp bases and pressure-cast aluminium rods protruding from finned rear of housing - Google Patents

Abstract

A double-ended halogen-metal vapour lamp (13) has each base (6) coupled by a spring (10) to a fixed post (11) in the region (7) of max. heat development. The posts protrude from the rear section (2) of the lamp housing which is in domed contact with the pure Al reflector (3) over the area (5) of highest thermal loading. The outer edge (9) of the reflector is bent outwards into a flange (4) making close contact with the housing over its entire circumference. USE/ADVANTAGE - At sports stadia and large open spaces, construction guarantees temp. redn. at critical points of lamp bases and protection against overheating of reflector.

Description

The invention relates to a high-performance headlight for a double-ended metal halide lamp for Stadium and large area lighting with facilities for Heat dissipation, especially on the lamp bases and on Reflector, with divided, metallic lamp housing and Cooling fins and a spring connected to the lamp base.

Metal halide lamps develop large ones during their operation Amounts of heat that are dissipated to the outside as quickly as possible need to prevent the reflector from overheating and deforming protect. For this purpose, the well-known lamp housing  made of heat-dissipating metal, especially aluminum provided and provided with large cooling fins. The critical point regarding heat development and heat derivative is located on the lamp base and here on the ver binding point between the power supply coming from outside and the contact material of the electrodes. Materi come across here alien with different expansion coefficients in one so-called squeeze zone together. The heat dissipation is difficult because there is only a small radiation area.

DE-GM 19 89 494 measures for heat dissipation Headlights known. Here are the cooling fins of the housing led around the connection corners of the housing sides and so extended that this the lamp sockets from the outside to two Surrounded sides. The middle cooling fins of the housing are for maximum heat dissipation outside as close as possible to the inside Lamp sockets arranged. The lamp holders are with scha len-shaped bearings for the lamps and who that includes the angular cooling fins on two sides. To further improve the heat dissipation to the crush place the base, heat dissipation springs are provided, which the heat in the reflector and from there through the inner Lead the ribs into the housing.

This type is for use with high-performance headlights the heat dissipation unsuitable because of the many Transition points between those involved in heat dissipation components, heat build-up, and fast Dissipation of large amounts of heat is not guaranteed. The special heat dissipation via springs in the reflector is dangerous detects the function of the reflector. The reflector is the one Risk of overheating and thus deformation with the Result exposed that the light emission is no longer the same moderate.

The invention is therefore based on the object High-performance headlights of the generic type in this way improve that a drop in temperature at the critical Scoring the lamp base to a material-compatible level and protect the lamp reflector from overheating are accomplished.

To achieve this object, the invention provides that the Lamp base in the area of greatest heat development with at least one from the back of the lamp housing protruding web penetrating the reflector in an opening via the pressure force at least one arranged on the web Spring is firmly connected. The webs carry the heat directly on the lamp housing with the cooling fins, so that against a significantly larger solution than previously known Temperature reduction is achieved at these points. The Effect is exerted by a spring increased contact pressure of the lamp base on the web reinforced. The spring is arranged so that the contact pressure increased due to material stresses when heated. With increasing warming ever closer connection between the contact areas increases the effectiveness of heat dissipation. To prevent the lamp reflector from overheating this with part of its area, in the area of the largest Heat radiation from the lamp, closely with the lamp housing Back connected. The back of the lamp housing is in this area according to the radius of the reflector Dome shaped. The outer edge of the reflector is like this trained that he was with a Contact surface in direct contact with the luminaire housing stands and is firmly connected to it, so that a good There is heat dissipation. The good heat dissipation results in Connection with the fixed clamping of the reflector in the Back of the luminaire housing and its closed design,  that a deformation of the reflector and thus an unequal moderate light distribution can be excluded.

Further advantageous embodiments of the invention result itself from the further subclaims.

The invention is based on one in the drawings illustrated embodiment of a high performance certificate thrower for a double-ended metal halide lamp explained in more detail. Show it:

Fig. 1 is a rear view of the high performance headlamp

Fig. 2 is a side view of the high performance headlamp

Fig. 3 is a front view of the high performance headlamp

Fig. 4 shows a longitudinal section through the lamp housing rear part of the high-performance headlight with the lamp and inserted

Fig. 5 is a section along the line AA in FIG. 4 without the lamp envelope.

Figs. 1 to 3 show the high performance projector for metal halide lamps, such as is used for area lighting stadium and bulk. The two-part luminaire housing 1 is made of die-cast aluminum, the reflector 3 is made of pure aluminum. The lamp 13 can be used without tools after the rear housing part 2 has been folded down. A lamp 12 made of fine wire mesh, which is drawn onto a metal ring in the manner of a tennis racket covering and fastened and stretched via a rubber seal and a ring 8 , protects the lamp 13 .

In Figs. 4 and 5, the lamp housing body rear part 2 shown with the essential components, the reflector 3 and is put metal halide lamp 13 in section. The lamp housing back part 2 is provided with cooling fins 14 which run transversely to the longitudinal axis of the lamp 13 ( Fig. 1, 3, 4). It serves as a heat sink for dissipating the heat generated in the lamp operation. The greatest heat development occurs at the junctions between the electrical lines 15 and the molybdenum foils in the lamp base 6 ( FIG. 4). The copper strand of the feed line 15 is welded to the molybdenum foil, which produces the gas-tight contact with the lamp electrodes. The lamp base 6 made of steatite merges into the quartz glass body of the lamp 13 at this so-called pinch point 22 . Depending on the material, temperatures of up to 400 ° C are permitted here. Without heat dissipation, temperatures arise in this limit range. If the temperature is lowered, the service life of the lamp used increases significantly. Through the formation of webs 11 , which are formed in one piece from the back of the lamp housing 2 and are pulled out through openings 21 in the reflector 3 and serve to accommodate the critical areas 7 of the lamp base 6 , heat dissipation is achieved which at this point reduces the temperature by 150 ° C causes, ie below the critical, permitted temperature value. The contact surfaces of the webs 11 are adapted to the geometric conditions of the lamp base 6 at this point, so that a firm, intimate support of the base 6 is achieved. The positionally stable fastening of the base 6 on the web 11 is ensured by a spiral spring 10 ( FIG. 5). The spring 10 consists of several rings arranged parallel to one another, the diameter of which corresponds to the width of the support surface 22 of the webs 11 . The spring washers form two groups that are connected to each other by a web-like bracket. The spring 10 is fastened with its ends in the bores 16 of the web 11 and presses the I-shaped base 6 more firmly onto the likewise I-shaped web 11 , the more it heats up ( FIG. 5). The reason for this is given by the selected spring steel material, the shape of the spring 10 and the type of attachment to the web 11 in a known manner. The spring attachment of the base 6 on the web 11 makes a separate lamp holder unnecessary. The particularly effective heat dissipation via the webs 11 is supported in that the cooling fins 14 on the lamp housing rear part 2 extend in particular over this area ( Fig. 4).

The reflector 3 is most heavily loaded by the heat radiated by the lamp 13 in the area 5 behind the lamp 13 . In order to get good heat dissipation in this area 5 , the reflector 3 is introduced into a spherical shape 19 of the lamp housing rear part 2 in the size of the radius of the reflector 3 so that a closed contact surface is formed, via which the heat is good to the outside is led away. The reflector 3 is formed on its outer edge 9 so that it is connected to the lamp housing rear part 2 in a heat-dissipating manner over its entire circumference. For this purpose, the outer edge 9 of the reflector 3 is bent vertically downward, so that a surface 17 in the form of an annular web is formed, which is angled at an angle of 90 ° to the outside. This creates a further annular surface 18 , which is used to fasten the reflector 3 to the lamp housing rear part 2 by means of screws 20 . The close connection of the reflector 3 with the lamp housing rear part 2 via these surfaces 17 , 18 causes an additional, effective heat dissipation. The closed version of the reflector 3 , in contrast to the slotted version according to the known solutions, as well as the fixed clamping of the reflector 3 over its entire circumference, in conjunction with the good heat dissipation, ensure that no deformation of the reflector 3 can occur and a uniform one Light distribution is ensured.

Provide the measures for heat dissipation according to the invention overall a significant lifespan increase in the high high-performance headlights installed metal halide lamp from 2000 h to 5000 h to 6000 h on average.

Reference list

1 housing
2 lamp housing back
3 reflector
4 contact surface
5 Area of greatest heat load
6 lamp bases
7 Area of greatest heat development
8 ring
9 outer edge
10 spring
11 bridge
12 grids
13 lamp
14 cooling fins
15 supply line
16 holes
17 area
18 flange
19 calotte
20 screw
21 opening
22 contact surface (pinch point)
23 wall

Claims (7)

1. High-performance headlights for a double-ended metal halide lamp for stadium and large area lighting with facilities for heat dissipation, especially on the lamp bases and on the reflector, with a divided, metallic lamp housing and cooling fins and a spring connected to the lamp base, characterized in that each lamp base ( 6 ) in the area ( 7 ) of the greatest heat development with at least one web ( 11 ) protruding from the lamp housing rear part ( 2 ) and penetrating the reflector ( 3 ) in an opening ( 21 ) via the pressing force of at least one on the web ( 11 ) arranged spring ( 10 ) is firmly connected. 2. High-performance headlamp according to claim 1, characterized in that the bearing surface ( 22 ) of each web ( 11 ) is shaped according to the geometry of the lamp base ( 6 ). 3. High-performance headlamp according to claim 1, characterized in that the spring ( 10 ) is a spiral spring, the ends of which are introduced into bores ( 16 ) of the web ( 11 ). 4. High-performance headlamp according to claim 1, characterized in that the reflector ( 3 ) in the area ( 5 ) of its greatest heat load in direct, flat contact with the lamp housing rear part ( 2 ) is arranged and that the outer edge ( 9 ) of the reflector ( 3 ) to a circumferential bearing surface ( 4 ) is bent, which rests flat over the entire circumference of the reflector ( 3 ) on a web-like wall ( 23 ) of the lamp housing rear part ( 2 ). 5. High-performance headlamp according to claim 4, characterized in that the reflector ( 3 ) in the region ( 5 ) of its greatest heat load in a cap ( 19 ) of the lamp housing rear part ( 2 ) is arranged in direct contact with this and that the bearing surface ( 4) of the bent-over edge (9) of the reflector (3) is formed by a relation to the upper edge (9) deeper set annular flange (18) via a web surface (17) with the upper edge (9) of the reflector (3 ) connected is. 6. High-performance headlamp according to claim 1, characterized in that the lamp housing rear part ( 2 ) and the webs ( 11 ) are made in one piece. 7. High-performance headlamp according to claim 3, characterized in that the spring ( 10 ) consists of a plurality of rings arranged parallel to one another, which form two groups which are connected by a web-shaped bracket, the ring diameter of the width of the bearing surface ( 22 ) each Corresponds to web ( 11 ) and the ends of the spring ( 10 ) are led out in a semicircular arc to the bores ( 16 ) in each web ( 11 ).