Classifications

• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01K—ELECTRIC INCANDESCENT LAMPS
  • H01K1/00—Details
  • H01K1/02—Incandescent bodies
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01K—ELECTRIC INCANDESCENT LAMPS
  • H01K1/00—Details
  • H01K1/02—Incandescent bodies
  • H01K1/14—Incandescent bodies characterised by the shape
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01K—ELECTRIC INCANDESCENT LAMPS
  • H01K3/00—Apparatus or processes adapted to the manufacture, installing, removal, or maintenance of incandescent lamps or parts thereof
  • H01K3/02—Manufacture of incandescent bodies

Definitions

• the invention relates to a light source, in particular an incandescent lamp, with a bulb, a filament arranged in the bulb and a heating device for the filament, the filament emitting both visible light and heat radiation. Furthermore, the invention relates to a method for producing a light source of the aforementioned type.
• Incandescent lamps for example, are known as electrical light sources in which a tungsten wire is generally brought to the highest possible temperature by the electrical current heat. Thereby, thermal radiation is generated. The luminous efficacy of glowing wires increases sharply with increasing temperature.
• non-thermal radiation sources such as discharge lamps are also known as noble gas, mercury, sodium or metal halogen discharge lamps in high or low pressure designs.
• a disadvantage of all previously known electrically operated types of light sources is that they are very inefficient in converting electrical power into visible light power. The conversion barely exceeds 30%. The largest share of the electrical power consumed is uneconomic power loss in the form of predominantly heat.
• every thousandth photon is statistically absorbed in the material of the mirror.
• the photon flow may therefore only experience 1000 reflections on the inside of the flask until it is completely absorbed in the flask.
• the known helical shape of the filaments or filaments allows only a very low absorption of the reflected heat radiation, since the majority of the heat radiation is reflected past the thin spiral wire. Effective absorption or reheating is therefore not possible with conventional filaments or filament wires. Therefore, high conversion efficiency cannot be achieved with conventional light sources.
• the present invention is therefore based on the object of specifying a light source of the type mentioned at the outset and a method for producing such a light source, according to which high conversion efficiency is achieved with simple means.
• the probability that the photon flow hits the filament or the filament on the reflection path and is absorbed there is proportional to the ratio of the filament volume or the filament surface to the reflecting piston volume or to the reflecting piston surface.
• the light source according to the invention specifies a light source in which high conversion efficiency is achieved using simple means.
• the bulb In order to optimize the reflection behavior of the inside of the bulb, which is transparent to visible light, the bulb could have a reflective coating on its inside. This could be a dielectric multilayer coating in a particularly favorable manner. A spectrally selective mirroring is present, which essentially reflects the heat radiation component and transmits the component of visible radiation.
• the filament could at least partially be made of a sintered metal powder.
• a sintered material could be thought of as a porous sponge, in which the powder elements or grains of the starting metal usually only have point-like welding contacts with one another. This creates an extremely low effective electrically conductive cross section and an increased effective conductor length. Furthermore, the sintered material has high mechanical stability. Therefore, by using the sintered Metal powder on the one hand provides increased electrical resistance and on the other hand provides increased mechanical strength. This favors the use of large-area filaments.
• the filament or the metal powder could have tungsten and / or tantalum and / or rhenium and / or niobium and / or zirconium, with tantalum having proven particularly advantageous in practice.
• the filament could at least partially be constructed from a non-metal. This also makes it possible to increase the electrical resistance.
• the filament could be at least partially composed of tantalum carbide and / or rhenium carbide and / or niobium carbide and / or zirconium carbide. Specifically, one or more of the latter carbides could serve as a coating material for a filament made of sintered metal powder.
• the filament could be coated with a coating material that has a higher melting point than the filament material.
• the filament could be constructed from a sintered tantalum base body that has an outer layer of tantalum carbide.
• Tantalum carbide is an extremely temperature-resistant hard material that, due to the cross-linking in the porous sponge-like topology of the sintered material, creates a high mechanical or static strength of the material. As expected, the filament material is therefore extremely high-impedance and sufficiently strong to prevent the filament, which is hot during operation, from flowing.
• the flat section could be designed as a band with two long sides. Furthermore, two surface elements could protrude from the belt in the manner of wings on the two long sides. The total of four surface elements could then protrude from the belt at an angle of approximately 90 degrees.
• the flat section could be in the form of two U-profiles are available, with the two U-profiles coupled to each other at one end and lying almost back to back. The electrical contacting of the filament is provided at the opposite ends of the U-profiles. With such a flat section, the filament has a very favorable absorption behavior for heat radiation.
• the flat section could be designed in the form of a shell or a cylinder jacket.
• such a cylinder jacket could also be open on the side or slotted lengthways. This is favorable with regard to the thermal expansion behavior of the filament.
• the diameter of the cylinder jacket or the cylinder jacket part or the cylinder jacket half could only be slightly smaller than the diameter of the piston.
• the piston could be tubular.
• the filament could be arranged concentrically in the piston and / or coaxially to a longitudinal axis of the piston in the piston.
• the filament could divide the interior of the piston into one or more half or partial spaces.
• the piston could have such a large outer surface that surface heat generated by, for example, heat radiation absorption can be dissipated by convection cooling or another forced cooling.
• the size and shape of the filament and the piston could be coordinated accordingly.
• the color temperature of the light source can also be set independently of the surface temperature of the filament or the glow element. be put. This can be done by the spectrally selective mirroring, which can specify the transmitted spectral distribution of the radiation power emitted from the bulb and thus the color temperature.
• the surface temperature of the filament can be set lower in comparison to conventional filaments, since the comparable visible luminous flux can be generated by a larger and colder surface of the filament.
• the filament surface forms a new, additional degree of freedom.
• the filament can be operated at a relatively low temperature and thus a relatively low evaporation of the filament material is achieved, disruptive evaporation can occur due to the very large surface area, which is as close as possible to the inside of the piston with regard to effective absorption.
• Evaporated filament material deposited on the inside of the piston reduces the reflectivity of the inside of the piston or the mirror coating on the inside of the piston and increases the absorption of the piston or the mirror coating or the thermal power loss. It is therefore desirable to minimize evaporation of the filament material as much as possible.
• an inert gas and / or a halogen gas could be present in the flask, wherein the halogen gas could contain bromine and / or iodine. This could create a conventional tungsten iodide cycle for a tungsten filament.
• An alternative solution to the evaporation problem could be provided by coating the filament with a coating material that has a higher melting point than the filament material. This is due to the dependence of the temperature-dependent vapor pressure of a solid on its melting point. Furthermore, the precipitation of the coating material could show a lower absorptivity than the precipitation of the usual filament material.
• tantalum carbide and / or rhenium carbide and / or niobium carbide and / or zirconium carbide could be used as the coating material with a very high melting point. Due to the large filament surface area, very large luminous fluxes can be generated and emitted by the light source, so that the illumination of large building interiors or of outside areas is possible with only one light source according to the invention.
• a method for producing a light source of the type mentioned at the outset with the features of patent claim 21 After that, a filament made of sintered metal powder is first provided. By sintering the metal powder, the conductivity of the sintered material can be controlled by means of the starting grain size and the compression of the powder and the sintering temperature. In this way, a correspondingly high-resistance and mechanically stable material can be produced. This enables the use of filaments with large flat sections without the conductor cross-section, which is important for the electrical resistance, leading to an insufficient resistance and without mechanical instabilities due to the large area and under the influence of gravity. Even at high operating temperatures, the filament material does not sag or flow.
• the porous, sponge-like topology of the sintered filament is used to create a high mechanical stability of the material by exposing the filament to a carbon dioxide or carbon dioxide noble gas atmosphere to form a metal carbide.
• exposing the filament to a corresponding gas atmosphere creates a metal carbide layer on the outside of the filament.
• the effective electrical resistance is further reduced depending on the layer thickness or penetration depth of the metal carbide reaction. At process temperatures greater than 1000 degrees Celsius, carbide formation begins and at process temperatures greater than 1400 degrees Celsius, the complete carburization takes place after a certain process time.
• the metal carbide is an extremely temperature-resistant hard material that, due to the cross-linking in the porous spongy topology of the filament material, creates a mechanical or static strength of the filament.
• the fila As expected, mentmatenal is extremely high-impedance and sufficiently strong to avoid the flow behavior of the filament that is hot during operation
• the process temperature and later also the operating temperature of the metal carbide metal filament can be raised above the melting point of the metal.
• the metal carbide forms a solid sheath around the liquid metal core liquid metal escaping at the fractures or repaired by the metal carbide formation which immediately begins there
• the filament is enclosed in the bulb and a light source with high conversion efficiency is provided
• an additional compression step can be carried out in the process, which also affects the conductivity.
• the filament could be introduced into a piston open at two ends after its provision and electrically contacted at one end of the piston.
• the filament would already be provided protected in the piston after its provision and possibly rolling mechanical protection during further process steps
• the flask could be formed by a quartz tube
• Exposure of the filament to a carbon dioxide or carbon dioxide noble gas atmosphere could now be carried out in a particularly simple manner by flowing a carbon dioxide or carbon dioxide noble gas gas through the other end of the piston in the pistons.
• the filament could be electrically heated before and / or during metal carbide formation.
• the metal carbide formation could possibly be controlled until its completion.
• the metal carbide formation could be controlled based on the resistance characteristics of the filament.
• the heating current and the heating voltage could be measured via the electrical contacting of the filament and evaluated accordingly for the control.
• the metal carbide formation could be directly monitored via the electrical voltage-current characteristic or via the electrical resistance characteristic and therefore controlled.
• Talum carbide has a very high melting temperature, an extremely low evaporation rate of the tantalum carbide and a very low piston fogging can be expected at the usual light source operating temperatures. Tantalum carbide is also black in the visible spectrum, which is why there is a high spectral emissivity of the tantalum carbide. In particular, the porous tantalum carbide surface shows an increased blackness in the sense of Planck's blackbody radiation compared to non-porous surfaces.
• tantalum carbide tantalum filament lies in its thermal conductivity, which is only about half that of tungsten filaments. Together with the large reabsorbing surface of the tantalum carbide tantalum filament or the infrared radiation that is less often reflected on the inside of the bulb and therefore less absorbed there, and the comparably low thermal conductivity, a significantly lower thermal power loss is achieved.
• the tantalum carbide Tantalum filament could be heated to the maximum possible operating temperature of tungsten filaments.
• FIG. 1 is a perspective side view of the embodiment of a light source according to the invention
• FIG. 3 shows a top view of the exemplary embodiment from FIG. 1.
• Fig. 1 shows a perspective side view of the embodiment of a light source according to the invention.
• the light source is designed as an incandescent lamp which has a bulb 1 in which a filament 2 or a glow element is arranged.
• a heating device 3 is provided, which provides an electric current.
• the heated filament 2 emits both visible light and heat radiation.
• the filament 2 has a flat section 4.
• the flat section 4 enables a high degree of absorption of the thermal radiation reflected from the inside of the bulb 1 and originally radiated from the filament 2.
• the filament 2 is quasi re-heated. This makes it possible to supply less energy to the light source to achieve the same light output of the light source than is the case with conventional light sources. Consequently, the light source according to the invention can be energy and therefore more economically than conventional light sources.
• Power supplies 5 are attached to the filament 2 and are coupled to electrical contacts 6 of the heating device 3.
• a mirror 7 is provided, which significantly increases the reflectivity of the inside of the bulb 1 for heat radiation.
• the filament 2 is essentially made up of two U-profiles 8.
• the U-profiles 8 are electrically coupled at their upper ends. At their lower ends, the U-profiles 8 are each contacted with a power supply 5.
• the flat section 4 of the filament 2 is designed as a band with two longitudinal sides 9, on each of which two flat elements 10 project from the band in a wing-like manner. The total of four surface elements 10 each protrude from the band at an angle of approximately 90 degrees.
• the entire electrical contacting of the light source is provided at the lower end 11 of the bulb 1.
• Filament 2 consists of sintered tantalum powder and a tantalum carbide layer on its surface.
• FIG. 2 shows the light source from FIG. 1 in a position rotated by 90 degrees around the longitudinal axis of the bulb 1.
• the flat elements 10 are particularly well recognizable.
• the U-profile 8 is formed in each case by two flat elements 10 and a band or band-shaped base part of the filament 2.
• FIG. 3 shows the embodiment of a light source from FIG. 1 in a top view.
• the two U-profiles 8, which are connected to one another at their upper ends, can be seen particularly well.
• the filament 2 is arranged coaxially in the piston 1.
• the power supply lines 5 are attached to the inside of the U-profiles 8.
• At the A mirror 7 is applied to the inside of the piston 1.
• the surface elements 10 are arranged along the long sides 9 of the filament.

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• Engineering & Computer Science (AREA)
• Manufacturing & Machinery (AREA)
• Resistance Heating (AREA)
• Yarns And Mechanical Finishing Of Yarns Or Ropes (AREA)
• Eye Examination Apparatus (AREA)
• Devices For Indicating Variable Information By Combining Individual Elements (AREA)
• Polymerisation Methods In General (AREA)
• Non-Portable Lighting Devices Or Systems Thereof (AREA)

Applications Claiming Priority (5)

Publications (1)

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ID=26054698

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Family Applications Before (1)

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• 2000
  • 2000-03-24 WO PCT/DE2000/000912 patent/WO2001015207A1/fr not_active Application Discontinuation
  • 2000-03-24 US US10/069,260 patent/US6903508B1/en not_active Expired - Fee Related
  • 2000-03-24 MX MXPA02001858A patent/MXPA02001858A/es active IP Right Grant
  • 2000-03-24 BR BR0013480-5A patent/BR0013480A/pt not_active IP Right Cessation
  • 2000-03-24 DE DE50013668T patent/DE50013668D1/de not_active Expired - Fee Related
  • 2000-03-24 CN CNB008119082A patent/CN1215527C/zh not_active Expired - Fee Related
  • 2000-03-24 AU AU47422/00A patent/AU4742200A/en not_active Abandoned
  • 2000-03-24 KR KR1020027002274A patent/KR20020038737A/ko active IP Right Grant
  • 2000-03-24 CN CNB008119074A patent/CN1211829C/zh not_active Expired - Fee Related
  • 2000-03-24 WO PCT/DE2000/000911 patent/WO2001015206A1/fr active IP Right Grant
  • 2000-03-24 AU AU47423/00A patent/AU4742300A/en not_active Abandoned
  • 2000-03-24 EP EP00929240A patent/EP1206793B1/fr not_active Expired - Lifetime
  • 2000-03-24 KR KR1020027002273A patent/KR100664601B1/ko not_active IP Right Cessation
  • 2000-03-24 JP JP2001519474A patent/JP2003508875A/ja active Pending
  • 2000-03-24 BR BR0013489-9A patent/BR0013489A/pt not_active IP Right Cessation
  • 2000-03-24 MX MXPA02001856A patent/MXPA02001856A/es unknown
  • 2000-03-24 JP JP2001519473A patent/JP2003507878A/ja active Pending
  • 2000-03-24 EP EP00929241A patent/EP1206794A1/fr not_active Withdrawn
  • 2000-03-24 US US10/069,140 patent/US6777859B1/en not_active Expired - Fee Related
  • 2000-03-24 RU RU2002107206/09A patent/RU2260226C2/ru not_active IP Right Cessation
  • 2000-03-24 AT AT00929240T patent/ATE343850T1/de not_active IP Right Cessation
• 2002
  • 2002-11-22 HK HK02108487A patent/HK1048704A1/xx not_active IP Right Cessation

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