DE202013009629U1 - LED compact fluorescent lamp with internal cooler - Google Patents

Abstract

Double tubular LED lamp (1), comprising - at least two LED illuminant carriers (3, 3 ') and - at least one cooling element (4, 4') per LED illuminant carrier, characterized in that both the at least two LED illuminant carriers (3 , 3 ') as well as the at least one cooling element (4, 4') within a hermetically sealed tube (2, 2 ') are arranged.

Description

The invention relates to a double-tubular LED lamp comprising at least two LED illuminant carriers and at least one cooling element per LED illuminant carrier.

Known compact fluorescent lamps in double-tube form, as they are known with one-sided G23, G24D, 2G7 or 2G11 sockets in rod construction and also by the international lamp designation system IEC 1231 For example, as referred to as FSD-18-E-2G11, at the time of this application are increasingly replaced by double-tube LED lamps. This replacement is intended to reduce energy consumption for lighting purposes. Although the total light output of CFLs can not yet be completely replaced by known double tube LED bulbs, this replacement is attractive because of the very long life of LED bulbs.

In order to be able to use the novel LED lamps in existing versions for compact fluorescent lamps in double-tube form, a large number of so-called retrofits are known, which enable operation of the LED lamps at the power supply intended for the gas discharge. As LED bulbs are usually light sources with LEDs in a so-called chip-on-board (COB) or surface-mounted device (SMD) construction used, in which a larger number of LED bulbs are arranged on an elongated light source carrier , This lamp carrier is usually connected to a designated heat sink to dissipate the heat of each LED. In order to mimic the double tube shape of the known compact fluorescent lamps, two adjacent ones of these COB or SMD designs are slipped over on the front side containing the LED elements with a plastic half shell. If the heat sink also has a semicircular profile relative to the side facing away from the LED elements, an LED lamp produced in double-tube form actually forms an elongated cylinder pair. The design with half shells offers the advantage of very simple machine processing. Furthermore, to construct the LED lamps in double-tube form, no glass is necessary, so that it is possible to resort to extruded half-shell profiles. The half shell profiles assembled with the LED illuminant carriers form a cylinder or a flattened cylinder which can be used in conventional versions of double tubular compact fluorescent lamps.

An alternative construction is made by such LED lamps, in which the Doppler tube is combined to form an oval-shaped tube or united into a profile consisting of two parallel planes with two semicircular sides. In contrast to the double-tubular compact fluorescent lamps, which require a connection of the two glass tubes on the side facing away from the socket to their function, this consuming to produce tubular shape is no longer necessary in LED lamps, because no gas discharge along a tube path is necessary. Many manufacturers therefore drop the double tube shape in favor of the two tubes combined into a flat tube. This results in the advantage of simplified production of the flat tube of half-shells.

In the US 2011 009 068 2 A1 a tubular LED lamp is disclosed in which two half shells are pushed onto a central illuminant carrier.

This design far, however, various disadvantages. First, the connection between the lamp carrier and the cover in half-shell shape is not easy to seal. The edges where the two components abut each other must be glued if an airtight cover is even achieved.

When using these known LED lamps in tubular form in industrial plants, in laboratories, in car parking garages or in non-weather protected operation can accumulate moisture in the microclimate within the cover, resulting in premature aging of the LED lamp. Furthermore, the usually made of plastic covers tend to evaporate plasticizers or monomers of the polymeric plastic, which is optionally decomposed by UV components of the LED light to chemically active substances. These act after decomposition corrosive to the existing on the illuminant carrier lines.

In addition to moisture and mostly organic vapors also form car exhaust gases when used in parking garages, vapors in industrial halls or laboratories problems with the long-term use of these novel known LED lamps.

In the US 2010 006 623 0 A1 discloses a lamp carrier, which is arranged in a closed tube. To improve the cooling is proposed to fix the individual LED with a special thermally conductive glue on the carrier. Another heat sink except the carrier itself is not disclosed in this document.

In the US 2020 303 277 3 A1 different designs for a tubular LED Lamp disclosed, wherein the designated heat sink is located outside.

In the international patent application WO 2013/1 37816 A discloses a tubular LED lamp having an internal cooler, wherein the radiator is thermally conductively and flatly connected to the inside of the cover, so that the heat can be discharged via heat conduction to the outside. Also in this application no hermetic seclusion is provided. The heat concentration results in thermal stress within the tube, which over the life of the LED lamp can reduce the life of the tube.

In the German Offenlegungsschrift DE 10 2011 084 945 A1 discloses a tubular LED lamp having an internal heat sink. The caps are screwed on. A screw is not hermetically sealed over the life of the LED, so that unwanted foreign gases can adversely affect the microclimate in the tubular LED lamp.

The object of the invention is therefore to provide a double-tubular LED lamp, which overcomes the disadvantages of the prior art.

The object according to the invention is achieved in that both the at least two LED illuminant carriers and also the at least one cooling element each are arranged within a hermetically sealed tube.

For the purposes of this application, "hermetically sealed" is understood to mean an absolutely tight seal, which prevents in particular the exchange of air, gases, solvents or water, and which maintains its tightness over a long period of time and even under extreme temperature fluctuations.

The inventive arrangement of at least one heat sink within the hermetically sealed tube offers the advantage of complete seclusion of the electronic components from environmental influences. This protects the durable, yet delicate electronic components from corrosion or other harmful environmental factors, allowing them to last up to 50,000 hours. The arranged within the hermetically sealed tube at least one heat sink must of course be dimensioned so that the heat absorbed by him as a heat reservoir can be delivered in long-term operation by convection within the enclosing tube or by radiation.

In a preferred embodiment, the hermetically sealed tube is made of glass. The use of glass has the advantage that no aging of the cover takes place. In the previously known use of plastic profiles in known LED lamps in tubular form, the plastics tend to evaporate when their own exposure to weather influences, possibly UV light levels in the LED light. In the very small free volume of the tubular LED lamp can thus accumulate during long-term operation, a significant concentration of organic substances in the inner gas space of the LED lamp.

In order to prevent unwanted substances from accumulating in the gas space within the hermetically sealed tube during long-term operation, in a preferred embodiment of the tubular LED lamp it is provided that a material is present for the adsorption of gases and substances located in the gas space. These substances are preferably activated carbon and / or silica gel. Activated carbon is capable of adsorbing and holding organic substances. Silica gel is capable of adsorbing water vapor so as to absorb any moisture escaping from the components or moisture produced by the chemical reaction of adhesives, plastics or inorganic materials.

So that these adsorbers are not already saturated with moisture and / or organic substances in the manufacture of the LED lamps, it can be provided in a further advantageous embodiment that within the hermetically sealed tube a so-called getter material is present, which upon activation by microwaves or radiant heat has particularly high uptake potential of moisture, residual gases and / or organic substances. Known getter materials for receiving residual oxygen can also be used when the hermetically sealed tube is filled with an inert gas, such as nitrogen.

In order to improve the heat dissipation of the present within the hermetically sealed tube heat sink, the internal pressure of an optionally existing inert gas or air may be increased relative to the atmospheric pressure.

If the double-tubular LED lamp is to produce as glare-free light as possible, the outer surface of the hermetically sealed tubes may be frosted. This matting can be done by etching, by sandblasting but also by vacuum sandblasting. The matting on the outside surface of the tube has the advantage of being inside The smooth, smooth surface is more resistant to scratches when inserting the illuminant carrier into the hermetically sealed tube.

Alternatively or cumulatively, it is also possible to coat the inside of the hermetically sealed tube with a paste or liquid with CaCO ₃ (lime) and / or with TiO ₂ (rutile) and to burn it out during production. The lime has the effect that the light emerging from the LED in the hermetically sealed tube is strongly scattered, thus producing a glare-free light. In order that the lime does not block the light, fine-grained TiO _{2 is} provided, which introduces the light into the very thin layer of lime due to its high refractive index and its transparency.

The inventive arrangement of the at least one heat sink within the hermetically sealed tube requires a correspondingly dimensioned design of the heat sink. This must be dimensioned so that the heat absorbed by the heat sink as a reservoir by convection and / or radiation is delivered to the wall of the hermetically sealed tube. Care must be taken to ensure that the distance of the heat sink to the inner surface of the hermetically sealed tube provides space for free convection of the gas contained in the hermetically sealed tube. The arrangement must be able to provide sufficient convection cooling both in vertical and in horizontal operation. In contrast to a conventional tubular LED lamp having two opposing sockets, a standard G-socket, for example a G23 or a G24D socket, is provided in the double-tubular LED lamp. Alternatively, a 2G7 or a 2G11 socket may be provided. This design allows a mechanical recording of the illuminant carrier only on one side. In order to space the heat sink from the tube surrounding it, spacers may be provided which are arranged on the tip of the illuminant carrier and either fixedly connected to this or are attached to it. It is also possible to have the heat sink touched only at one point in the tube via a point contact or via line contact with the inside of the tube. An essential idea of the invention, however, is to provide the heat sink in such a way that the substantial amount of heat is conducted by convection from the heat sink to the tube.

In a specific embodiment, the hermetically sealed tube and / or the coating has a blue filter. This blue filter for filtering blue and ultraviolet radiation enables the use of these LED lamps in clean rooms where semiconductors are fabricated that are sensitive to blue and ultraviolet light.

The invention will be explained in more detail with reference to the following figures.

It shows

1 a double-tubular LED lamp according to the invention in a broken view,

2 the double tubular LED lamp according to 1 without openwork view,

3 the double tubular LED lamp according to 2 in a view from the side,

4 a cross section through the double tube with partially resting on the inside of the tubes heat sinks,

4 a cross section through the double tube with spaced from the inside of the tubes heat sinks,

5 a perspective view of the double-tubular LED lamp according to 1 ,

In 1 is a double-tubular LED lamp according to the invention 1 shown in a partially broken view. It can be clearly seen that in the two tubes 2 and 2 ' one illuminant carrier each 3 and 3 ' approximately in the middle of the hermetically sealed tube 2 and 2 ' is arranged. Below the illuminant carrier 3 and 3 ' and hidden in this figure are on the LED bulbs 3a and 3a ' opposite sides each have a heat sink 4 and 4 ' , the same as the illuminant carrier 3 and 3 ' inside the hermetically sealed tubes 2 and 2 ' are arranged and do not form part of the outer housing. The hermetically sealed tubes 2 and 2 ' can be filled with an inert gas. adsorber 5 in the form of activated carbon, silica gel and / or as a getter can on the illuminant carriers 3 and 3 ' be arranged or with a cap 6 into the hermetically sealed tubes 2 and 2 ' are introduced to remove moisture, residual oxygen, organic substances and / or noxious gases from the microclimate of the interior of the double-tubular LED lamp.

In 2 is that out 1 illustrated double-tubular LED lamp 1 shown without a broken view, wherein an existing matting in this embodiment, the view through the tubes 2 and 2 ' at least veiled. The attached socket 6 closes the tubes 2 and 2 ' completely and hermetically off, so no Mass transfer over the lifetime of the double-tube LED lamp takes place, thus affecting the microclimate in the tubes life shortening. The base has electrical contacts 7 . 7 ' and 8th and 8th' to power the illuminant carrier 3 and 3 ' on. The double-tubular LED lamp has a special feature on two independent, tubular LED lamps, which also have no material connection with each other, via the mass transfer between the two tubes 2 and 2 ' could take place. The two tubes 2 and 2 ' work like two electrically but also microclimatically independent tubular LED lamps.

In 3 is that out 1 illustrated double-tubular LED lamp 1 shown without a broken view in a view from the side and shows that in the lamp according to the invention two tubes 2 and 2 ' are juxtaposed and lie one behind the other in this view, leaving only a first tube 2 is visible, however, is a second tube 2 ' behind the first tube 2 concealed in this view.

In 4 is a cross section of the double tube LED lamp 1 according to 1 displayed. In the tubes 2 and 2 ' are light sources 3 and 3 ' arranged, each with at least one heat sink 4 and 4 ' are thermally connected. Since, in the double-tube LED lamp, a socket is arranged only on one side of the tubes, in a first embodiment, the double-tubular LED lamp 1 be provided that the ever at least one heat sink 4 and 4 ' only with a point contact or only via a line contact on the inside of the tubes 2 . 2 ' if necessary, it rests with mechanical tension. According to the invention, however, it is provided that there is no surface contact between the heat sink 4 . 4 ' and the insides of the tubes 2 and 2 ' but that is a distance between the heat sink and the inside of the tubes 2 and 2 ' present, so that the heat from the illuminant carriers 3 and 3 ' in essence is given by convention to the tube walls.

In 4 is a cross section of the double tube LED lamp 1 according to 1 displayed. Since in the double-tubular LED lamp, a socket is arranged only on one side of the tubes, in a second embodiment, the double-tubular LED lamp 1 be provided that the ever at least one heat sink 4 and 4 ' in the respective tube 2 . 2 ' is free and no heat-tight contact with the respective tube 2 . 2 ' having. The distance d between the heat sinks 4 and 4 ' on one side and the tubes 2 and 2 ' on the other hand can be stabilized by heat-insulating spacers. In this embodiment, the double-tubular LED lamp 1 gets the heat from the illuminant carriers 3 and 3 ' to the heatsink 4 and 4 ' and from there the heat flows exclusively via convection to the outside of the tubes 2 and 2 ' ,

In 5 is finally the double tubular LED lamp 1 out 1 shown in a perspective view. The two tubes 2 and 2 ' are at a first end over a pedestal 6 hermetically sealed and at a second end via a hermetically sealing cap 6a hermetically sealed, with the hermetically sealing cap 6a both tubes 2 and 2 ' mechanically stabilized. Alternatively, the tubes can 2 and 2 ' on the pedestal 6 opposite side also be fused to ensure a better hermetic seal. Unlike in compact fluorescent lamps is not provided in this embodiment that the two tubes 2 and 2 ' have a material connection, so that no mass transfer between the tubes 2 and 2 ' takes place.

LIST OF REFERENCE NUMBERS

1

Led lamp

2, 2 '

tube

3, 3 '

Lamp support

3a, 3a '

LED bulbs

5

adsorber

4, 4 '

heatsink

6

base

6a

cap

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 20110090682 A1 [0005]
• US 20100066230 Al [0009]
• US 20203032773 A1 [0010]
• WO 2013/137816 A [0011]
• DE 102011084945 A1 [0012]

Cited non-patent literature

• IEC 1231 [0002]

Claims (10)

Double tubular LED lamp ( 1 ), comprising - at least two LED illuminant carriers ( 3 . 3 ' ) and - at least one cooling element each ( 4 . 4 ' ) per LED illuminant carrier, characterized in that both the at least two LED illuminant carriers ( 3 . 3 ' ) as well as the at least one cooling element ( 4 . 4 ' ) within a hermetically sealed tube ( 2 . 2 ' ) are arranged. Double tubular LED lamp according to claim 1, characterized in that the hermetically sealed tubes ( 2 . 2 ' ) consist of glass. Double tubular LED lamp according to claim 1 or 2, characterized in that in the hermetically sealed tubes ( 2 . 2 ' ) an adsorber material ( 5 ) is present for the adsorption of gases and substances located in the gas space, preferably activated carbon and / or silica gel. Double tubular LED lamp according to claim 1 or 2, characterized in that in the hermetically sealed tubes ( 2 . 2 ' ) a radiation activatable getter ( 5 ) is present for the adsorption of oxygen and / or organic substances. Double tubular LED lamp according to one of claims 1 to 4, characterized in that the hermetically sealed tubes ( 2 . 2 ' ) are filled with an inert gas, which preferably has an overpressure relative to the atmospheric pressure. Double tubular LED lamp according to one of claims 1 to 5, characterized in that the hermetically sealed tubes ( 2 . 2 ' ) on the outside have a matting done by etching, sandblasting or vacuum sandblasting or by coating. Double tubular LED lamp according to claim 6, characterized in that the coating contains fine-grained TiO ₂ and / or fine-grained CaCO ₃ . Double tubular LED lamp according to one of claims 6 to 7, characterized in that the coating comprises a blue filter. Double tubular LED lamp according to one of claims 1 to 8, characterized in that the at least one heat sink ( 4 . 4 ' ) is dimensioned so that the heat absorbed by it as a reservoir by convection and / or radiation to the walls of the hermetically sealed tubes ( 2 . 2 ' ) is delivered. Double tubular LED lamp according to one of claims 1 to 9, characterized in that the base ( 6 ) is a G-socket, such as a G23 socket or a G24D socket, or a 2G socket, such as a 2G7 or a 2G11 socket.

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