JPH06283145A - Halogen lamp having sealed both sides - Google Patents

Abstract

PURPOSE: To make it possible to manufacture simply and inexpensively and especially ensure an easy automatic production and prolong a service life by maintaining an illuminant with only a singular or plural webs which is formed from the same material as the bulb. CONSTITUTION: A bulb 2 of a halogen lamp 1 is made of cylindrical crystal glass and has therein a duplicate coil of illuminant in the axial direction. The bulb 2 is connected to a contact of a cap 8 via a molybdenum fused foil in pinch seal members 4,5 and the bulb 2 is filled with gas which includes inert gas mixture and halogen additive after exhaustion performed at a central exhaust pip 3. The illuminant 6 is supported by a blocked part 11 of a tubular web 9 which is pushed in the form of a horn from two opposite positions of a bulb wall 2' in plural short sections situated on the axis of the lamp 1. Accordingly, it is possible to improve a cooling effect, have long service life and a high impact-proof characteristic, reduce the number of components, simplify production and attain miniaturization.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a halogen lamp sealed on both sides according to the general concept of claim 1.

[0002]

2. Description of the Related Art This type of halogen lamp is DE-GM8.
Known from 325115. This lamp is a double-end type tubular lamp in which a luminous body is arranged in the axial direction. Especially in the horizontal lighting posture, because the light emitter is long,
A plurality of helically or annularly wound coil retaining wires are provided to prevent contact with the inner wall of the valve. These wires are in close contact with the inner wall of the bulb in a manner known per se and support the light emitter. A small recess on one or both sides is provided in the valve wall for fixing each holder. However, the assembly of double-ended lamps with coil-holding wires is very cumbersome and expensive, which is especially true for lamps with fixing recesses. This is because, on the one hand, a considerable number of holders (e.g. 4) are required per lamp, which leads to a relatively high material cost, and on the other hand, the method of manufacturing a coil with a holder. Because it is large and expensive. For example, in order to prevent defects in the coil due to deformation, the coils must be separated and machined before mounting the retaining ring. Such processing prior to assembly within the lamp bulb is inefficient and difficult to automate.

[0003]

SUMMARY OF THE INVENTION It is an object of the invention to provide a double-side sealed halogen lamp which is particularly simple and inexpensive to manufacture and which is also particularly easy to automate and has a long life. is there.

[0004]

This object of the invention is solved by means having the features of claim 1. Particularly advantageous implementations are described in the subclaims.

A particularly straightforward attempt at constructing a double-ended sealed double-ended lamp structure is to simplify the design of the holder and thus also to facilitate automation. Much effort has already been made in the art for this purpose. However, the present invention was able to achieve a decisive improvement in an entirely different direction. That is, rather than simply changing the form of the holder, the holder was not used at all. The role of the carrier is now taken over by a glass web made of the same material as the bulb.

This is because it was unexpectedly revealed that a glass web made of the same material as the bulb has a high temperature resistance. The reason for this is that there is additional cooling from the outside and heat dissipation to the outside, which prevents the glass web from separating.

The web can in principle be made solid (as a rod), but is not entirely satisfactory in terms of manufacturing technology and also in terms of cooling effect. Therefore, the web is preferably of tubular design. By doing so, the heat dissipation area is expanded, and the cooling effect is improved.

There are two principal alternatives to the web holding means. One is a mechanical holding part, in which case, for example, a tubular web is passed through the secondary coil of the light emitter, so to speak, as if threaded, or in close contact with the light emitter. In the area of the web, the secondary coil leads are advantageously chosen to a value which is compatible with the outer diameter of the web. Particularly advantageously, the temperature of the phosphor can be significantly reduced by allowing the core pin to cause a short circuit in the web area of the phosphor.

In the case of the second holding means, the tubular web fixes the illuminant by pressing it between two web halves. Due to the particularly close connection by means of the clamping, sufficient heat dissipation occurs in this coil section. This heat dissipation prevents darkening of the bulb and devitrification of the glass web, and in addition, the luminous intensity of the clamped coil area is lost or weakened. The critical temperature of the glass web is about 800 to 900 ° C. when using quartz glass and about 600 ° C. for hard glass. For primarily low wattage lamps (eg, 75 W or less), the entire light emitter can be coiled. The coil in this case
Both single and double coils are possible. The illuminant can in principle be fixed at any location by means of a tubular web. For higher wattages (75 W and above), the fixed part of the light emitter is preferably a primary coil or a coilless, non-luminous (exactly low intensity) connection.
This connecting portion is provided between the light emitting portions of the double coil. For high wattage lamps (eg 200W
In the above), a coilless connecting portion may be provided between the single coil portions. Also in this case, a short core pin can be used in the connecting portion of the single coil.

Those skilled in the art will immediately understand that the non-luminous connecting portion has a significantly lower power density and a smaller temperature load than the light emitting portion. The fixing is therefore preferably effected at the connection. As a result, it is possible to suppress the dispersion of electrical values and lighting engineering values to a low value, as well as skillfully solving the problem of heat load.

By this technique, the holding portion of the luminous body is remarkably simplified, and the manufacturing is also simplified. In addition, the diameter of the glass web can be such that it does not significantly interfere with the circulation of halogen within the lamp bulb. This diameter is advantageously at least 30% greater than the outer diameter of the light emitter in the fixed area.

A plurality of tubular lateral webs are used to achieve an ideal use state even in a horizontal lighting posture. These webs immobilize the individual coil parts and thus fully take on the classical holding function.

Due to the trumpet-shaped construction of the tubular web, no excessively thin points are formed in the transition region to the valve wall, which would burst at low burst pressures.
The wall thickness is fairly uniform. The inside diameter of the web is typically 0.5 mm to 2.0 mm and has a diameter of 2 to 4 times at the end of the trumpet.

The manufacture of the web is generally carried out after the sealing of the valves and in any case before filling. The lamp bulb is heated with a torch in the area provided with the web and is shaped by the plungers facing each other. The great advantage of this technique is that the molding process ensures that the position of the light emitter is no longer displaced afterwards. These webs consist of two plungers, which are constructed as rods, which push the valve wall into two hollow, especially trumpet-shaped "glass fingers".
Particularly easy to mold. This "glass finger"
Eventually they will touch each other on (or near) the lamp axis. The diameter of the trumpet portion at the bulb wall and the degree of narrowing in the lamp axis direction depend on the heating zone area at the bulb wall. The absolute value of the glass tube diameter near the axis depends on the dimensions of the plunger. An occlusion occurs in the seam area between both "glass fingers".
In the case of this pinching technique, the light emitter lies exactly between both "glass fingers" and is fixed by the formation of a closure.

In another manufacturing technique, a bowl-shaped web (concave bending of the web wall) is formed instead of the trumpet-shaped web (convex bending of the web wall). In this case, the web is shaped without the application of force with a plunger. That is,
Exhaust pip before sealing at this point (the sealed pip after completion of the lamp is indicated by reference numeral 3)
A negative pressure in the mbar range is produced via the valve, while at the same time two opposite points of the valve wall are heated by the torch. This technique is particularly suitable for small lamp bulb diameters (≦ 6 mm). It is also suitable in the case of light emitters with long connections, especially for supply network voltages of about 110V. The advantage of this technique is that the light emitter is not pushed by force, and thus the light emitter is not deviated from the fixed position.

An intermediate technique, that is, a technique of assisting the variation of the plunger with a negative pressure can also be used.

[0017]

As described above, the halogen lamp according to the present invention has a long life (2000 hours) as a whole.
And has a very high impact resistance and a simple structure with few constituent parts. This also makes it possible to reduce the tube diameter by about 20 compared to standardized halogen lamps.
It can be reduced by%. As a secondary effect of reducing the valve volume, it is possible to further reduce the amount of filler. The lamp according to the invention is suitable for use directly at the grid voltage. The grid voltage in this case is to be understood as a voltage in the range of approximately 80V to 250V. Typical wattages range from 50W to 2000W. These lamps are used, for example, in floodlight installations, but can also be used for general lighting.

[0018]

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.

1 and 2 have a base 15 on both sides.
1 shows a 0 W halogen lamp 1 for general illumination. This lamp is suitable for direct connection to a 220V power grid. The bulb 2 is cylindrical and made of quartz glass, has an inner diameter of about 7 mm, a total length of about 105 mm, and an exhaust pip 3 provided at the center. Both ends of the valve are closed by pinch seals 4 and 5, respectively. The valve has 80
% Of Kr and 20% of N _{2 in} an inert gas mixture,
The gas is filled with a halogen additive consisting of 0.005% CBrClF ₂ .

The light-emitting body 6, which is a double coil as a whole, is arranged in the axial direction, and almost extends over the entire length inside the bulb. The emitter has a filament diameter of 53 μm and the outer diameter of the secondary coil is 580 μm. The light emitter is connected to the contacts of the base 8 (ceramic) through both end portions 7 of the single coil and both molybdenum fusion foils (not shown) in the pinch seals 4 and 5. There is.

In the case of another embodiment, the light emitting body 6 is a single coil and both ends 7 are non-coiled, and the other portions are the same as those of the embodiment of FIGS.

In these two embodiments, four tubular webs 9 are used instead of the commonly used metal wire coil holder. These webs are arranged in a row at right angles to the lamp axis. These webs 9
Divides the light-emitting body 6 into equal-length portions 10. These parts are short and will not sag. These transverse webs 9 are molded of the material of the bulb and extend over two bulb diameters from two opposite sides of the bulb wall 2'to contact the lamp axis.

The web 9 has a symmetrical trumpet shape. Starting from both origins of the valve wall 2 ', each web 9 is continuously narrowed inward. This shape is advantageous in avoiding thin wall areas during manufacture.
The web 9 has a tube inner diameter of about 1.2 mm near the lamp axis, expands towards the bulb outer wall and has a diameter of about 2 to 4 times at the bulb outer wall. In the area of the lamp axis, a clamping closure forms a solid closure 11, which has a substantially solid cylindrical shape. The height of this solid cylinder is approximately equal to its diameter. The short section 12 of the light emitter is pressed and fixed in the closed portion.

The number of webs 9 varies depending on the power level of the lamp, the length of the light emitter, the stability in terms of sag and the like. In the case of low-power rigid emitters, one web is sufficient for some reasons. For light emitters with higher wattage and lower stiffness, more than three webs, for example six webs, can be provided depending on the circumstances.

If the number of webs is large (for example four or more), the webs 9a, 9b are advantageously arranged in a plane rotated alternately by 90 ° instead of being aligned in a row (FIG. 3). . Another possibility is to form the webs sequentially offset by 45 ° about the lamp axis. In this case, the second web is positioned at an angle of 45 ° with respect to the first web, the third web is positioned at an angle of 90 °, and so on. The advantage of this embodiment is that the halogen circulation process is not hindered and the optical characteristics (irradiation characteristics) are
However, it is a point that is maintained substantially uniform.

Another embodiment of a 100 W lamp (FIG. 4) has a double coil section 10 from the light emitter 6 ', which is separated by a single coil connection 13. Fixing of the light-emitting body 6 ′ by continuously enclosing the trumpet-shaped web 9 in the closed portion 11 is performed at the height of the connecting portion 13. This embodiment is, on the one hand, advantageous in the case of a double-coil emitter with a large-diameter secondary coil. This is because the light emitter of the double coil tends to be distorted or twisted during encapsulation. On the other hand, this technology is about 20
Suitable for lamps up to 0W. This is because in these lamps, the temperature of the double coil illuminator becomes so high that darkening (of the bulb coating), devitrification, and even stress in the glass occurs.

In one embodiment of a 200 W double-ended lamp (FIG. 5), the transverse tubular web 14 has a constant diameter over most of its length, in the immediate vicinity of the bulb wall 2 '. For the first time, the flared portion 15 is formed. A short core pin 18 made of molybdenum wire is arranged in the connecting portion 13 of the single coil. The web 14 is pressed against the connecting portion at the height of the core pin 18, and the inside of the connecting portion is hollow.

Another variant is shown in FIG. Both halves of the web 14 clamp the double coil emitter at the single coil connection. At the axis, a seam 19 is visible between the two halves of the closure 11, since both halves are only imperfectly welded together. The trumpet-like portion of the web 14 continuously expands outward (and thus not linearly) towards the valve wall. This optimum form of the trumpet-like part is produced by the uniform supply of heat during the continuous pressing of the rod-shaped plunger 20.

This optimum configuration most certainly guarantees a uniform wall thickness of the web. For webs of other shapes, the plunge speed and / or the heat supply and also the pressing pressure of the plunger must be changed appropriately.

FIG. 7 shows an embodiment of a light emitter having a coil having a particularly large lead. The entire light emitting body 6 is continuously coiled. For the sake of clarity, the individual windings of the emitter are shown, the coating 6 "being shown in broken lines. A trumpet-shaped web intersecting the lamp axis and offsetting both origins at the bulb wall 2 '. 15 is threaded through one winding section, the web 15 being constructed as a continuous central cylinder or with a central closure 11 (as shown) near the axis. The outer diameter of the web matches the individual windings of the phosphor.

The angle of inclination of the web with the lamp axis preferably matches the lead angle. This is because, on the one hand, the fixation is best guaranteed and, on the other hand, the web diameter can be chosen relatively large. However, in principle, the web can also be provided in this embodiment in a direction perpendicular to the lamp axis. Alternatively, the illuminator may be provided with one extra large winding (or coil portion) to allow the web to pass through.

In yet another embodiment (FIG. 8), the light emitter comprises a continuous coil. The glass web 16 is
They are arranged so as to be displaced by a coil radius and a web radius in a direction perpendicular to the lamp axis. The web is, in this case,
The light emitting bodies 17a and 17b are alternately arranged above and below the horizontal lighting position. The advantage of this arrangement is that the light emitter can be easily manufactured regardless of the dimensions of the coil. In the case of this embodiment, no connecting portion may be provided. Preferably web 16
a core wire 18 short to the height of a, 16b
Place it in the coil. The web can be tubular or trumpet-shaped. In this embodiment, the web 16
The diameters of a and 16b can be selected to be four times as large as the leads of the light emitter 17a. In this case, the leads can be chosen accordingly small (see the left half of FIG. 8). On the other side, the diameter of the glass webs 16c, 16d is
Since it can be chosen to be significantly smaller than the leads of the light emitter 17b, each web 16c, 16d can fit into the "dimple" formed by the individual windings (see the right half of FIG. 8). This form of implementation
It is suitable when the leads of the light emitter are correspondingly large.

In FIG. 9, 11 having a bowl-shaped web 26 is shown.
A portion of the 0V-lamp 25 is shown. Both halves of the web 26 are concavely curved and adhere to the single coil connection 27 of the double coil emitter 28 over a relatively large area of 7 mm.

Leads used in the above-mentioned embodiments,
Unless otherwise specified, the concept of a coil or the like basically means a secondary coil of a double coil or a winding of a single coil, unless otherwise specified.

The invention is not limited to the illustrated embodiment. In particular, it is also suitable for a halogen lamp used in a 110 V power supply network. The filling is composed of inter alia known constituents, such as argon inert gas and 0.05% CH 2.
It is also possible to use ₂ Br ₂ halogen additives. Hard glass can also be used as the valve material. The phosphor is then fused directly into the pinch seal. It is connected to an external contact pin via a power supply unit known per se.

The web may have an elliptical cross section instead of a circular cross section. In that case, the elliptical major axis is located within the lamp axis in order to enhance the holding action.

During manufacture, the plunger is shaped accordingly.

The invention provides in particular an inexpensive halogen lamp with a power of at least 30 W, which is connected directly to the supply network. This lamp is particularly suitable for general lighting.

[Brief description of drawings]

FIG. 1 is a side view of a first embodiment of a double-end type halogen lamp having both sides sealed.

FIG. 2 is a side view showing the halogen lamp of FIG. 1 rotated by 90 °.

FIG. 3 is a partial side view of another embodiment of a double end type halogen lamp.

FIG. 4 is a partial side view of another embodiment of the same type halogen lamp.

FIG. 5 is a partial side view of another embodiment of the same type halogen lamp.

FIG. 6 is a partial side view of another embodiment of the same type halogen lamp.

FIG. 6 is a partial side view of another embodiment of the same type halogen lamp.

FIG. 7 is a partial side view of still another embodiment of the same type halogen lamp.

FIG. 8 is a partial side view of still another embodiment of the same type halogen lamp.

FIG. 9 is a partial side view of still another embodiment of the same type halogen lamp.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Halogen lamp 2 Bulb 3 Exhaust pip 4,5 Pinch / seal 6 Light emitter 7 Single coil end part 8 Base 9 Tubular web 10 Light emitter part 11 Closure part 12 13 Connection part 14 Lateral web 15 Trumpet shape Part 16 Glass web 17a, 17b Coil of luminous body 18 Core wire 25 110V-Lamp 26 Bowl-shaped web 27 Coupling part 28 Luminous body

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[Procedure amendment]

[Submission date] March 3, 1993

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] Brief description of the drawing

[Correction method] Change

[Correction content]

[Brief description of drawings]

FIG. 1 is a side view of a first embodiment of a double-end type halogen lamp having both sides sealed.

FIG. 2 is a side view showing the halogen lamp of FIG. 1 rotated by 90 °.

FIG. 3 is a partial side view of another embodiment of a double end type halogen lamp.

FIG. 4 is a partial side view of another embodiment of the same type halogen lamp.

FIG. 5 is a partial side view of another embodiment of the same type halogen lamp.

FIG. 6 is a partial side view of another embodiment of the same type halogen lamp.

FIG. 7 is a partial side view of still another embodiment of the same type halogen lamp.

FIG. 8 is a partial side view of still another embodiment of the same type halogen lamp.

FIG. 9 is a partial side view of still another embodiment of the same type halogen lamp.

[Explanation of Codes] 1 Halogen lamp 2 Bulb 3 Exhaust pip 4,5 Pinch / seal 6 Light emitter 7 Single coil end portion 8 Base 9 Tubular web 10 Light emitter portion 11 Closure portion 12 13 Connection portion 14 Lateral direction Web 15 trumpet-like portion 16 glass web 17a, 17b luminous body coil 18 core wire 25 110V-lamp 26 bowl-shaped web 27 connecting portion 28 luminous body

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Laurent Stark Federal Republic of Germany Welheim Sdetenstraße 9 (72) Inventor Michael Blinkhof Federal Republic of Germany Wippelfurth Hassipen (no address)

Claims (14)

[Claims] 1. A halogen lamp (1) sealed on both sides for use in a power grid voltage, the lamp axis being defined.
A hermetically sealed tubular bulb made of translucent material, a filling consisting of an inert gas and a halogen-containing additive, an axially arranged luminophor with two ends, and both ends of the luminophore. In the form of a connected power supply, the illuminant is held only by one or more webs, which are made of a material which is equal to the bulb material, each of which has two bulb walls. A halogen lamp with both sides sealed, which extends between the points. 2. Halogen lamp according to claim 1, characterized in that the web (9) extends in a direction perpendicular to the lamp axis and is in contact with the lamp axis. 3. A web (16) is formed perpendicular to the lamp axis and is also arranged alternately on one side (16a, 16c) and the other side (16b, 16d) of the lamp axis. As a result, as a result, the luminous bodies (17a, 17a
Halogen lamp according to claim 1, characterized in that b) is held mechanically by a web (16). 4. Halogen lamp according to claim 1, characterized in that the webs (9) lie in the same plane. 5. Halogen according to claim 1, characterized in that the webs (9a, 9b) alternate in two planes, which are at right angles to one another and which are in contact with the lamp axis. lamp. 6. Halogen lamp according to claim 1, characterized in that the light emitters (6; 6 ') are pressed into the web (9). 7. Halogen lamp according to claim 1, characterized in that the web (9; 14; 15; 17) is tubular. 8. The web is flared in a trumpet shape or funnel shape toward the outer wall of the valve.
Halogen lamp described. 9. Halogen lamp according to claim 1, characterized in that the luminous body (6; 17) is constructed as a coil throughout. 10. A light emitting body (6 ') comprises a plurality of parts (10').
Divided into two parts, and these parts are separated by a connecting part (13), and in that case, these parts (10 ') are made into a double coil, and the connecting part is made into a single coil or no coil. The halogen lamp according to claim 1, wherein: 11. Halogen lamp according to claim 10, characterized in that the web (9; 14) holds the light emitter (6 ') in the area of the connection (13). 12. Halogen lamp according to claim 1, characterized in that the light emitter has a core wire at the location held by the web, which improves the cooling effect. 13. The lamp is provided with a luminous body, the ends of the bulb are sealed, and then the bulb is point-heated by two torches facing each other and pushed by two rod-shaped plungers. The method for manufacturing a halogen lamp according to claim 1, wherein the tubular webs are formed by forming the tubular webs. 14. After introducing the luminous body and sealing the bulb end, the bulb of the lamp is point-heated by two torches facing each other to form each tubular web. A method according to claim 1, characterized in that at the same time a negative pressure is created in the bulb of the lamp via the exhaust pip.