DE102013213572A1 - Tube lamp with improved light distribution - Google Patents

Abstract

The present invention shows a tube lamp with a fluorescent tube 1 which is provided with at least one external light-forming layer 4, 5. In other words, the at least one light-forming layer 4, 5 is provided on an outer surface of the fluorescent tube 1. The at least one light-forming layer 4, 5 can consist of a phosphor coating, a phosphor paint and / or a diffuser film and / or other beam-shaping optical means 9b or can be a film which has at least one phosphor layer and / or a diffuser film and / or other beam-shaping optical means 9b is coated or printed. By providing the at least one light-forming layer 4, 5, 9 on the outer surface of the fluorescent tube 1, the light distribution of the tube lamp can be improved. Furthermore, a mechanically more stable tube lamp can be produced, since the light-forming layers 4, 5, 9 and the fluorescent tube 1 of the tube lamp can be protected against scratching and impact.

Description

The present invention relates to a tube lamp, in particular an LED tube lamp. The tube lamp of the present invention comprises at least one external light-forming layer, i. H. a light-forming layer provided on an outer surface of a lighting tube of the tube lamp.

From the prior art it is known to provide a tube lamp, for example a classic fluorescent tube, with a phosphor or diffuser coating. In a known UV-excited fluorescent tube, a phosphor coating is provided on an inner part, for example on the inner surface, of a glass tube. However, the methods used to apply the phosphor coating to the inner surface can not provide a uniform layer thickness of the coating. The uneven film thickness does not pose a serious problem with the UV-excited arc tube because the variation in thickness in the coating affects only the segregation of various types of phosphor particles, but does not affect the color homogeneity of the tube lamp.

Recently, however, LED tube lamps have replaced classic fluorescent tubes. Normally, an LED tube lamp includes at least one LED module that is inserted into a light tube. A disadvantage of these LED tube lamps is that the aforementioned fluctuation of the thickness of a phosphor coating causes color unevenness of the light of the LED tube lamp.

Further, due to the fact that the light is emitted from the LED module, the LED tube lamp has different light distribution characteristics than a fluorescent tube. In particular, the emitted light comes from the radial portion of the arc tube, opposite the LED module, and is directed. When the directional light is needed, a clear tube for LED tube lamps can be used, while a diffused coating can be used to diffuse the emitted light when larger angles of radiation are needed.

It is known from the prior art to provide such a diffuse coating through the use of scattering particles with which both surfaces of the arc tube are painted. A disadvantage of such a tube lamp, however, is that the efficiency of the light distribution of the coating is very low, the recording of the coating is relatively high and the coating is mechanically unstable.

The mechanical instability is due to the fact that if the coating is provided on the inner surface of the arc tube, insertion of the LED module into the arc tube can cause scratching of the coating. Furthermore, a chemical incompatibility may occur, or the bonding of the LED module in the arc tube may be less stable. If the coating is applied to the outer surface of the arc tube, packaging or handling the tube lamp can cause undesirable scratches on the coating.

The object of the present invention is to improve the prior art. In particular, it is the object of the present invention to provide an LED tube lamp with improved light distribution properties. In particular, an object is to provide a LED tube lamp with a phosphor coating that does not cause color non-uniformity of the emitted light. A further object is to provide an LED tube lamp with at least one coating, wherein the LED tube lamp has a higher light distribution effect, lower absorption capacity and improved mechanical stability.

The objects of the present invention are solved by the features of the appended independent claims. The appended dependent claims further develop the advantages of the present invention.

The present invention is directed to a tube lamp having a fluorescent tube and an LED module mounted in the arc tube, wherein at least one light-forming layer is provided for optically and / or spectrally influencing the light emitted by the LED module on the outer surface of the fluorescent tube. The light-forming layer is realized by optical means. There are two types of optical means, namely beam-shaping means and spectral-modifying means. Because the photogenerating layer is on the outer surface of the arc tube, it is unlikely to be damaged during assembly of the tube lamp, especially when the LED module is inserted into the arc tube. The light-forming layer can also be more easily applied to the arc tube, and thus variations in thickness can be reduced. The light-forming layer preferably changes the light-emitting properties of the tube lamp, preferably a color, a color temperature and / or a strength of the emitted light.

Another advantage of the present invention is that the cooling of the LED module and the photogenerating layer is separated. The Heat generation of the LED module is directed to the back of the arc tube, while possible heat generation of the light-forming layer is directed to the front of the arc tube to which the LED module emits light. Thus, for example, a light-forming layer comprising phosphor particles (or consisting of a phosphor layer) may have a lower light flux load and better cooling. As a result, less luminescent waste is achieved during the warm-up. In addition, a tube lamp can be constructed with greater strength. The tube lamp further undergoes a lower heat loss of the light-forming layer and the chip of the LED module, resulting in a longer life of the tube lamp.

Preferably, at least one light-forming layer is a phosphor coating or a phosphor paint and / or a diffuser film mounted on the outer surface of the light tube.

A phosphor coating or a phosphor coating may be used to adjust the color of the light emitted by the tube lamp. The phosphor can be excited by the light of a certain wavelength of the LED module to emit secondary light of a certain, continuous wavelength spectrum. The emitted secondary light may thus be added to the light emitted by the LED module, resulting in a mixed wavelength light. For example, white light may be generated, for example, by populating the LED module with LEDs that emit light from the blue wavelength spectrum and a phosphor that emits secondary light from the yellow wavelength range when excited by the blue light. The phosphor coating or the phosphor coating may consist of a phosphor material. The phosphor coating or the phosphor paint may also be made of a non-phosphor material provided with dispersed phosphor particles. The coating or paint can consist of one or more individual layers, which are superimposed and / or next to each other.

As an alternative to the phosphor, quantum dots can also be used. These differ from conventional phosphorus in that their energy transitions always assume discrete values.

A quantum dot or a quantum dot paint can also be used to match the color of the light emitted by the tube lamp. The quantum dot can be excited by the light of a certain wavelength of the LED module to emit secondary light of a certain wavelength. The emitted secondary light may thus be added to the light emitted by the LED module, resulting in a mixed wavelength light. For example, white light may be generated, for example, by populating the LED module with LEDs emitting light from the blue wavelength spectrum and quantum dots emitting secondary light from the yellow wavelength range when excited by the blue light.

Preferably, at least one light-forming layer is a film which is coated or printed with at least one phosphor layer and / or one quantum dot layer and / or one diffuser film.

A film can be easily applied around the outer surface of the arc tube. The film may be provided with the phosphor layer and / or the quantum dot layer and / or the diffuser film before being applied to the arc tube. Thus, the film may be pre-printed, precoated or pre-painted with the phosphor layer and / or the diffuser film, thereby enabling easier and more accurate production of the light-forming layer than if the phosphor, and / or quantum dot and / or diffuser layer were directly on the arc tube would be upset. Printing methods such as ink-jet printing, coating methods such as vapor deposition or sputtering may be used to provide the phosphor layer and / or quantum dot layer and / or the diffuser film on the film. The thickness of the phosphor layer and / or quantum dot layer and / or the diffuser film, or a thickness gradient, can be precisely controlled and variations in thickness can be minimized. The phosphor layer and / or quantum dot layer and / or the diffuser film are preferably arranged between the foil and the arc tube. Thus, the phosphor layer and / or quantum dot layer and / or the diffuser film are protected from scratching by the film. The foil also provides protection for the arc tube. Furthermore, the film provides a shield in the event of a possible electric shock when a user touches a broken tube lamp.

Preferably, the at least one film is a shrink film or hollow cylindrical film which is wrapped or attached around the arc tube.

Such a shrink film is preferably applied to the arc tube because prior to shrinking, the film readily fits around the arc tube and then only heat must be supplied to shrink the film to the dimensions of the arc tube. As a result, the film wraps tightly around the arc tube. The slide could even be removed later, for. B. to be replaced by another, for example, a different precoated film. A foil around the light tube offers additional protection for the outside, for example against scratches or bumps. It could even be several sheets wrapped or mounted around the arc tube, on the one hand to further adapt the emission characteristics of the tube lamp accordingly or on the other hand to provide a particularly pronounced protection.

The at least one film preferably consists of a polymer in which phosphor particles and / or particles containing quantum dots and / or scattering particles are introduced.

Such a film is simple and inexpensive to manufacture. The quantum dot or phosphor particles are protected by the polymer. The exact amount of phosphorus and / or quantum dots and / or scattering particles in the polymer can be precisely controlled. The particles may be evenly distributed throughout the polymer or may also be unevenly distributed, for example, to create a gradient either along the length and / or along the radial direction of the arc tube. The tube lamp can thus have different emission properties for light emitted in different directions.

Preferably, a transparent adhesive or elastomer is applied between the at least one foil and the arc tube and / or between at least two foils.

The films can thus be easily attached to the arc tube. In addition, the attachment of multiple slides can be done easily and quickly. Due to its transparency, the adhesive or elastomer does not affect the light emitted by the LED module. Furthermore, air gaps between the films or the film and the arc tube are avoided, and thus does not decrease the light and heat output.

The at least one film is preferably coated with a plurality of different phosphor layers and / or quantum dot layers.

The plurality of phosphor layers and / or quantum dot layers are preferably disposed between the one sheet and the arc tube for protection. The plurality of different phosphor layers and / or quantum dot layers can be stacked on top of each other, ie. H. be stacked, z. B. to provide the emitted light of the tube lamp with a broad, multi-wavelength spectrum. The various phosphor layers and / or quantum dot layers can also be arranged side by side, either overlapping or non-overlapping, for example, to provide different areas of the surface of the tube lamp with different emission properties.

The plurality of different phosphor layers and / or quantum dot layers preferably comprise a first phosphor layer or first quantum dot layer disposed on the foil and comprising a yellow and / or green phosphor or yellow or green quantum dots, a second phosphor layer or quantum dot layer disposed on the first phosphor layer or a first quantum dot layer is arranged and comprises a red phosphorus or red quantum dots, as well as optionally a third phosphor layer or third quantum dot layer which is arranged on the second phosphor layer or second quantum dot layer and comprises a further phosphorus or further quantum dots.

The LED module preferably comprises one or more LEDs emitting in a blue wavelength spectrum. The aforementioned phosphor layers and / or quantum dot layers which emit light from the yellow and / or green wavelength spectrum, the red wavelength spectrum or optionally a further wavelength spectrum can be designed to provide a white light emitting tube lamp. The red phosphorus or the quantum dots can or can also within the arc tube, z. B. on the inner surface and thus not be provided on the film. All or some of the phosphor layers may have the same or a different thickness. The concentration of the phosphor material and / or the first quantum dot material can also be changed within a phosphor layer and / or the quantum dot layer or else from one phosphor layer and / or quantum dot layer to another. As a result, the properties of the light emitted by the tube lamp, preferably a white light, can be adjusted precisely.

Preferably, the at least one film is translucent or milky, or the at least one film is provided with a translucent or milky layer between the at least one phosphor layer and / or quantum dot layer and the film.

Thus, the tube lamp may be configured to either emit directional light because the light from the LED module is already being emitted directionally or to emit diffused light by the application of the milky foil or layer.

The thickness of the diffuser film is preferably in the range of 100 to 200 μm.

A film of this thickness provides good scattering of the emitted light. A film of this thickness can be uniformly applied to achieve homogeneous emission characteristics of the tube lamp. The diffuser film can also consist of a prefabricated, flexible sheet, which is applied to the outer surface of the arc tube, for example by gluing or adhering. Then, the preferred thickness of 100 to 200 microns allows easy bending of the diffuser film for exact adaptation to the outer radius of the arc tube.

The at least one light-forming layer is preferably applied only to a first peripheral portion of the outer surface of the arc tube, and the first peripheral portion is disposed in front of an emission side of the LED module.

Since the light is directed from the LED module, material required to form the photogenerating layer can be saved by eliminating it on a back side of the LED module.

Preferably, a fog layer is provided on a second peripheral portion of the outer surface of the arc tube, and the second peripheral portion is disposed in front of a back side of the LED module.

The veil layer serves to adapt the tube lamp to its environment. The haze layer may be provided for reflecting light and thus acts as a reflector for the light emitted by the LED module. Thus, no light can be emitted from the back of the tube lamp.

Preferably, at least one light-forming layer comprises a holographic pattern and / or a beam-forming pattern.

Several light-forming layers are preferably provided on the outside of the arc tube over its longitudinal extent.

The tube lamp can thus be provided over its length with different emission properties.

Preferably, at least one light-forming element is inserted between the arc tube and the LED module.

The light-forming element also provides the possibility to adjust the emission characteristics of the tube lamp accordingly.

Preferably, at least one light-forming element comprises a red phosphor and at least one light-forming layer comprises a green and / or yellow phosphor.

The color and / or color temperature of the light emitted from the tube lamp, preferably a white light, can be adjusted accordingly.

The present invention is also directed to a method of making a tube lamp comprising the steps of providing a light tube and inserting and mounting an LED module to the light tube, providing at least one light-forming layer for optically and / or spectrally influencing the light tube light emitted from the LED module on the outer surface of the arc tube.

The method of the present invention enables rapid and convenient production of a tube lamp with well-defined light emission characteristics. The method achieves a higher yield in the mass production of tubular lamps, which is due at least to the fact that during insertion of the LED module into the arc tube the risk of damage to the photogenerating layer is minimized as the photogenerating layer on the Outer surface of the arc tube is provided.

The step of providing at least one light-forming layer preferably comprises coating or coating the outer surface of the light-emitting tube with a phosphor layer and / or a quantum dot layer and / or a diffuser film.

Preferably, the step of providing at least one photogenerating layer comprises wrapping the arc tube with a shrink film coated or printed with at least one of a phosphor layer and / or a quantum dot layer and / or a diffuser film, and heating the shrink film.

The method of the present invention achieves the same advantages described above for the tube lamp of the present invention.

The present invention will be explained below in detail with reference to the accompanying drawings.

1 shows a tube lamp according to the present invention.

2 shows a fluorescent tube of a tube lamp according to the present invention.

3 shows a fluorescent tube of a tube lamp according to the present invention.

4 shows a fluorescent tube of a tube lamp or their preparation according to the present invention.

5 shows a fluorescent tube of a tube lamp according to the present invention.

6 shows a fluorescent tube of a tube lamp according to the present invention.

7 shows a fluorescent tube of a tube lamp according to the present invention.

1 shows a tube lamp according to the present invention. The tube lamp includes a fluorescent tube 1 , preferably a glass tube into which an LED module 2 . 3 is used. The LED module 2 . 3 is preferably mounted in the arc tube I. The LED module 2 . 3 preferably has a heat sink 2 preferably over the entire length of the arc tube 1 extends and is preferably formed from a plastic carrier. On the heat sink 2 at least one LED is mounted, preferably a multi-LED LED string 3 ,

The heat sink 2 can be mounted in the arc tube 1 can be used and inside the arc tube 1 for example, through the heat sink 2 protruding, flexible parts 2a be held in place. The flexible parts 2a can before inserting the LED module 2 . 3 into the arc tube 1 be biased so that they are against the inner surface of the arc tube 1 Press when the LED module 2 . 3 in the arc tube 1 located. Thus, a stable position of the heat sink 2 given without the LED module 2 . 3 must be glued or screwed. However, the LED module can 2 . 3 also to the light tube 1 be glued or screwed. The heat sink 2 can have connections at each of its two ends 2 B which are adapted to electrically and mechanically connect the tube lamp with a socket. An electrical wiring for the LED of the LED string 3 can be in or on the heat sink 2 are located. The light tube 1 can be further closed by at least one, preferably two end caps on its two ends to the heat sink 2 to hold in their position.

2 shows in particular how the arc tube 1 the tube lamp can be designed. In particular, the outer surface of the arc tube 1 with at least one light-forming layer 4 . 5 for the optical and / or spectral influencing of the LED module 2 . 3 emitted light. The light-forming layer 4 . 5 is, for example, a light-forming layer such as a phosphor and / or quantum dot and / or scatter coating, a phosphor and / or quantum dot and / or spread, a phosphor and / or quantum dot film, a diffuser film or sheet, or a coated and / or or printed film and / or a layer with any other optical means 9 ,

There can be several light-forming layers 4 . 5 be used. In 2 are two light-forming layers 4 and 5 shown. The light-forming layers 4 and 5 in 2 are arranged side by side and are partially overlapping. However, the light-forming layers must be 4 and 5 do not overlap, but can only lie side by side, either along the length of the arc tube 1 or along the radial circumference of the arc tube 1 , The light-forming layers 4 and 5 can also be provided one above the other, that is stacked on top of each other.

For example, the scattering of the LED module 2 . 3 emitted light at least one light-forming layer 4 . 5 be designed as a light-shaping diffuser film. Such a film is preferably 50 to 300 μm, more preferably 100 to 200 μm thick. The diffuser film may be a film directly on the outer surface of the arc tube 1 coated or painted on. The diffuser film preferably comprises scattering particles. The diffuser film may also be formed as a separate diffuser film, or may be provided on a sheet or foil preprinted or precoated with a diffuser layer. Such a thin diffuser film can easily adapt to the radius of the arc tube 1 can be adjusted and thus easily at the arc tube 1 attached, z. B. are glued with transparent casting resin. The diffuser film can also be in the arc tube 1 be used. In addition, the diffuser film around the arc tube 1 be wound and act as a protective shield in case of a possible electric shock in case of breakage and as a mechanical protection. The light-forming layer 4 . 5 but can also be implemented as a film as just described, but instead of the diffuser with any other optical means 9 or combinations.

For the optical and / or spectral influence of the LED module 2 . 3 emitted light can be at least one light-forming layer 4 . 5 as a film, preferably as a shrink film or hollow cylindrical film 8a be trained, the around the arc tube 1 , optionally around the light tube 1 and another light-forming layer 4 . 5 as wound or attached around a diffuser film. Such a film may for example consist of polymers such as PC, PMMA, PET, cross-linked polyethylene or the like. The folio may contain at least one phosphorus and / or quantum dot layer preprinted or precoated to affect the wavelength spectrum of the emitted light and / or a diffuser film or a layer for diffusing the emitted light. The folio may initially be loose around the arc tube 1 can be wound and then simply by applying heat exactly to the diameter of the arc tube 1 be adjusted. The pre-printed or pre-coated phosphorus and / or quantum dot layer and / or the diffuser film is preferably between the polymeric material of the foil and the arc tube 1 arranged when the film around the arc tube 1 is wound. Alternatively or additionally, phosphor particles and / or particles may contain the quantum dots and / or quantum dots and / or scattering particles may be introduced into the polymer of the film.

2 shows how a light-forming layer 5 in the form of a foil around a fluorescent tube 1 can be wound or attached, the arc tube 1 additionally with a further light-forming layer 4 coated or painted as a diffuser film or a phosphor and / or quantum dot layer. The light-forming layer 5 can also consist of several slides surrounding the arc tube 1 and / or a coated or coated light-forming layer 4 be wrapped. A transparent adhesive or elastomer may be placed between each or some of the sheets and / or between the innermost sheet and the arc tube 1 and / or the coated or coated photogenerating layer 4 be applied to avoid air gaps. Air gaps would reduce the light and heat output of the tube lamp. Preferably, the outermost photogenerating layer 4 . 5 on the surface of the arc tube 1 a foil containing all the inner light-forming layers 4 . 5 protects.

A phosphor and / or quantum dot material may be preprinted or precoated on the at least one film, and preferably has a plurality of phosphorus and / or quantum dot layers. The plurality of phosphorus and / or quantum dot layers are preferably arranged in the order of a yellow / green phosphor and / or quantum dot layer directly on the film and a red phosphorus and / or quantum dot layer on the yellow / green phosphor and / or quantum dot layer. Optionally, a further phosphorus and / or quantum dot layer is provided on the red phosphorus and / or quantum dot layer. The further phosphorus and / or quantum dot layer can also be inside the arc tube 1 be provided. Also, the red phosphorus and / or quantum dot layer may be provided on the inner surface of the arc tube, so that the film is provided only with the yellow / green phosphorus and / or quantum dot layer.

2 shows that the first light-forming layer 4 on the entire outer surface of the arc tube 1 is applied. In other words, the light-forming layer 4 completely over the circumference of the arc tube 1 applied. As described above, the light-forming layer 4 however, it may also comprise at least one microlens, at least one raster, one or more microprisms, one or more Fresnel optics or one or more holographic diffuser optics. Around the light-forming layer 4 around is in 2 the light-forming layer 5 preferably provided as a shrink film for protection. The film may, as mentioned above, z. B. pre-printed or pre-coated phosphorus and / or quantum dot and / or diffuser layers.

Out 3 it can be seen that the light-forming layer 4 even just a part, preferably a half 1a which can be provided around the light tube. This one half is preferably one half 1a with respect to the circumference of the arc tube 1 , Preferably, a part of the arc tube 1 which is in the emission direction of the LED module 2 is arranged, with the light-forming layer 4 Mistake. The other half 1b the arc tube 1 may remain free or transparent or may be with another light-forming layer 4 . 5 be provided. This back half 1b the arc tube 1 Can also use a white foil to cover the heat sink 2 or another veil element. 4 shows the arc tube 1 or their preparation according to the present invention. In the arc tube 1 , preferably glass tube, is an LED module 2 . 3 as in 1 described used. Regarding the LED module 2 . 3 the description becomes 1 directed. 4 shows like a light tube 1 will be produced. On a light tube 1 , are optical means such as in the embodiments of the 2 . 3 . 4 . 6 and 7 described. As optical means 9 are light-shaping agents 9a and spectral modifiers 9b possible. To the optical means 9 around is a shrink film or hollow cylindrical film 8a attached, which shrinks irreversibly under the action of heat. The arrangement consisting of the arc tube 1 , the optical means 9 and the shrink film or hollow cylindrical film 8a is now heated by a preferably artificial, external heat source 7 For example, oven or heating coil. As a result shrinks the shrink film or hollow cylindrical film 8b on the arc tube 1 , It is advantageous if the arc tube 1 slowly from one end of the arc tube 1 to the other end of the arc tube 1 at the heat source 7 in the direction 6 is moved past. Alternatively, the heat source 7 in the direction 6 be slowly moved along the arrangement. Unlike one uniform heating z. B. in a conventional oven over the full length of the arc tube 1 this has the advantage that wrinkling of the shrunk-on film 8b is avoided. It is particularly advantageous if the heat source 7 is annular and the arc tube 1 through the center of the ring in the direction 6 the vertical of the ring is moved or the heat source 7 in this direction 6 is moved, so that the heating of the film 7 radially symmetric happens.

5 shows a further embodiment of a fluorescent tube 1 , especially glass tube. A light tube 1 , preferably glass tube, preferably with a hollow cylindrical shape forms the core of the lamp. Preferably, the outer coating of the arc tube 1 is on one and other half-cylinders 1a . 1b the arc tube 1 differently. On a half cylinder 1a the arc tube 1 are outside one or more optical means 9 intended. The optical means 9 can spectral-changing agents 9b included, the z. Example of a coating, an additional film, a phosphor, a layer or film containing quantum dots, and / or jet-forming agent 9a included, such as As a diffuser, prisms, micromirrors, microlenses or the like. It is an advantage if the other half cylinder 1b outside with a camouflage 12 is provided. This can be realized, for example, with a coating or an additional film. Alternatively to the camouflage 12 may also be provided a painting, a pattern or a company logo or the like.

To the two half cylinders just described 1a . 1b around is a shrink film or hollow cylindrical film 8a , which shrinks under the action of heat, preferably with the method which in the remarks to 4 was described on the half cylinders 1a . 1b was shrunk.

6 shows the beam-shaping optical means 9a which already in the remarks to 5 were described closer. The basic building block is again a fluorescent tube 1 , In the arc tube 1 , preferably glass tube, is an LED module 2 . 3 as in 1 described, can be used. Regarding the LED module 2 . 3 will be on the description of 1 directed.

The beam-shaping optical means 9a are located on the outside of the arc tube 1 , There are embodiments in which only part of the arc tube 1 beam-shaping optical means 9a are located. But also on the whole light tube 1 can be beam-forming optical means 9a are located. There may also be different beam-shaping optical means 9a on different parts of the arc tube 1 be arranged. The different parts with different beam-shaping optical means 9a can also overlap. The beam-shaping optical means 9a include, jet-forming patterns. Directional patterns (Emboss) 11 come into question, for example, in the direction of the axis, the arc tube I run or alternatively circularly around the arc tube 1 around. Structures are also used which consist of microlenses, microprisms, holographic patterns or Fresnel optics or Fresnel patterns, diffusing disks, damping disks or combinations of said optics. Around the arrangement just described is advantageously a hollow cylindrical film 7 Applicable according to the method, which in the remarks to 4 has been described.

The jet-forming means 9a For example, they may be applied with a film containing the agents or, alternatively, adhered or otherwise mechanically secured. Especially in the case of diffuser elements, these can also by sputtering, chemical vapor reaction, steaming, printing, z. B. by ink-jet, needle dosing, or similar methods are attached.

7 teaches structures such as the spectrum of light emitted by the tube lamp with spectrally-varying optical means 9b can be changed. The basic building block is again a fluorescent tube 1 , In the arc tube 1 , preferably glass tube, is an LED module 2 . 3 as in 1 shown, can be used. Regarding the LED module 2 . 3 will be on the description of 1 directed.

The spectral-changing optical means are located on the outside of the arc tube 1 , There are embodiments where only on a part of the arc tube 1 Spectral-changing optical means 9b are located. But also on the whole light tube 1 can spectrally-changing optical means 9b are located. There may also be different spectrally-varying optical means 9b on different parts of the arc tube 1 be arranged. The different parts with different spectrally changing optical means 9b can also overlap.

The spectral-modifying optical means 9b contain phosphorus and / or quantum dots. It can be different layers 10a . 10b . 10c be arranged one above the other with different phosphors and / or quantum dots.

For example, the bottom layer 10a contain red, orange, yellow, green, blue, violet, or red-orange, yellow-green, or blue-green phosphors or quantum dots.

It can be another layer 10b may be arranged, which contain red, orange, yellow, green, blue, violet, red-orange, yellow-green, and / or blue-green phosphors and / or quantum dots.

This can be another layer 10c be arranged, which contains red, orange, yellow, green, blue, violet, red-orange, yellow-green and / or blue-green phosphors and / or quantum dots.

Preferably, the lowermost layer contains 10a a red-orange phosphor and / or quantum dots, the middle layer 10b a yellow-green phosphor and / or quantum dots and the top layer 10c a blue-green phosphor and / or quantum dots,

Around the arrangement just described is advantageously a hollow cylindrical film 8b Can be applied according to the method, which in the remarks to 4 has been described.

Likewise, a structure of beam-forming means as in the comments to 6 described with a structure that changes the light spectrum as in 7 be combined described. Arrangements are possible in which the lowermost layer of beam-shaping optical means 9a and the upper layers spectrally-changing optical means 9b contain. However, arrangements are also possible in which the upper layer of beam-shaping optical means 9a and at least one lower layer or the lower layers consists or contains spectrally-varying optical means 9b contain. This has the advantage that the light beam path of the spectrally-converted or spectrally-modified light by the beam-shaping optical means 9a can be influenced.

In summary, the present invention provides a fluorescent tube 1 a LED tube lamp with at least one external light-forming layer 4 . 5 ready. In other words, at least one light-forming layer 4 . 5 . 9 on an outer surface of the arc tube 1 intended. The at least one light-forming layer can be made of a phosphor coating, a phosphor coating and / or a quantum dot coating, a quantum dot coating and / or diffuser film and / or other beam-shaping optical means 9a consist, or may represent at least one film, with at least one phosphor layer and / or a quantum dot layer and / or a diffuser film and / or other beam-forming optical means 9a coated or printed. By providing the at least one light-forming layer 4 . 5 . 9 on the outer surface of the arc tube 1 , the light distribution of the tube lamp can be improved. In addition, a more mechanically stable tube lamp can be achieved since it can be protected against scratching and impacting the photogenerating layers and the arc tube. The present invention thus improves a tube lamp known from the prior art, in particular LED tube lamp.

The individual, different embodiments can be combined with each other.

Claims (23)

Tube lamp with a light tube ( 1 ), and one in the arc tube ( 1 ) mounted LED module ( 2 . 3 ), wherein at least one light-forming layer ( 4 . 5 ) for the optical and / or spectral influencing of the LED module ( 2 . 3 ) emitted light on the outer surface of the arc tube ( 1 ) is provided. Tubular lamp according to claim 1, wherein at least one light-forming layer ( 4 ) is made of a phosphor coating or a phosphor paint and / or a diffuser film, which on the outer surface of the arc tube ( 1 ) is arranged. Tubular lamp according to claim 1 or 2, wherein at least one light-forming layer ( 5 ) consists of a film which is coated or printed with at least one phosphor layer and / or a diffuser film. Tubular lamp according to claim 3, wherein the at least one foil ( 5 ) is a shrink wrap around the arc tube ( 1 ) is wrapped around. Tubular lamp according to claim 3 or 4, wherein the at least one foil ( 5 ) consists of a polymer in which phosphor particles and / or scattering particles are introduced. Tubular lamp according to one of claims 3 to 5, wherein a transparent adhesive or elastomer between the at least one film ( 5 ) and the arc tube ( 1 ) and / or between at least two films ( 5 ) is applied. Tubular lamp according to one of claims 3 to 6, wherein the at least one foil ( 5 ) is coated with several different phosphor layers. A tube lamp according to claim 7, wherein the plurality of different phosphor layers comprise a first phosphor layer deposited on the foil ( 5 ) and comprises a yellow and / or green phosphor, a second phosphor layer, which is arranged on the first phosphor layer and a red phosphor, and optionally a third phosphor layer disposed on the second phosphor layer and comprising a further phosphor. Tubular lamp according to one of claims 3 to 8, wherein the at least one foil ( 5 ) is translucent or milky, or the at least one film ( 5 ) with a translucent or milky layer between the at least one phosphor layer and the film ( 5 ) is provided. A tube lamp according to any one of claims 2 to 9, wherein a thickness of the diffuser film is in the range of 100 to 200 μm. Tubular lamp according to one of claims 1 to 10, wherein the at least one light-forming layer ( 4 . 5 ) only on a first peripheral section ( 1a ) of the outer surface of the arc tube ( 1 ) is provided, and the first peripheral portion ( 1a ) in front of an emission side of the LED module ( 2 . 3 ) is arranged. A tube lamp according to claim 11, wherein a haze layer on a second peripheral portion ( 1b ) of the outer surface of the arc tube ( 1 ) is provided, and the second peripheral portion ( 1b ) in front of a rear side of the LED module ( 2 . 3 ) is arranged. Tubular lamp according to one of claims 1 to 12, wherein at least one light-forming layer ( 4 . 5 ) has a holographic pattern and / or a beamforming pattern. A tube lamp according to claim 13, wherein an upper layer comprises beam-shaping optical means ( 9a ) and at least one lower layer contains spectrally-changing optical means ( 9b ) contains. Tubular lamp according to one of claims 1 to 14, wherein a plurality of light-forming layers ( 4 . 5 ) on the outer surface of the arc tube ( 1 ) are provided over their longitudinal extent. Tubular lamp according to one of claims 1 to 15, further comprising at least one light-forming element ( 6 ) between the arc tube ( 1 ) and the LED module ( 2 . 3 ) is used. A tube lamp according to claim 16, wherein at least one light-forming element ( 6 ) comprises a red phosphor, and at least one light-forming layer ( 4 . 5 ) comprises a green and / or yellow phosphor. Tubular lamp according to claim 16 or 17, wherein at least one light-forming element ( 6 ) comprises red quantum dots, and at least one light-forming layer ( 4 . 5 ) comprises green and / or yellow quantum dots. A method of manufacturing a tube lamp comprising the steps of: providing a fluorescent tube ( 1 ) and inserting an LED module ( 2 . 3 ) in and attaching it to the arc tube ( 1 ), Providing at least one light-forming layer ( 4 . 5 ) for the optical and / or spectral influencing of the LED module ( 2 . 3 ) emitted light on the outer surface of the arc tube ( 1 ). The method of claim 19, wherein the step of providing at least one photogenerating layer ( 4 . 5 ) the coating or coating of the outer surface of the arc tube ( 1 ) comprising a phosphor layer and / or a diffuser film. A method according to claim 19 or 20, wherein the step of providing at least one light-forming layer ( 4 . 5 ) wrapping the arc tube ( 1 ) with a shrink film or the attachment of a hollow cylindrical film 7 which is coated or printed with at least one phosphor layer and / or a diffuser film, and the heating of the shrink film or hollow cylindrical film 7 includes. A method according to claim 21, wherein the heating is carried out by exposing the arc tube ( 1 ) from one end of the arc tube ( 1 ) to the other end of the arc tube ( 1 ) at a heat source ( 7 ) is passed. or that the heat source ( 7 ) on the arc tube ( 1 ) is moved along. A method according to claim 22, wherein the heat source ( 7 ) is annular and the arc tube through the center of the ring in the direction of the vertical of the ring ( 6 ) is moved or the heat source ( 7 ) is moved in this direction, so that the heating of the film is radially symmetrical.

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