EP2604917A1 - Lighting with cooling system - Google Patents

Abstract

The cooling lamp (100) has rotatable fan blade (104) that is arranged around a filament (102). The fan blade is inclined with respect to a longitudinal axis of the filament to generate an air flow in the direction of the longitudinal axis.

Description

The present invention relates to a lighting means, in particular an LED-based lighting means, with a cooling.

With LED-based bulbs, the LEDs (LED: light-emitting diodes) generate a high amount of waste heat, which is generated in a concentrated location. Usually, therefore, large heat sinks are used for cooling. However, classic light bulbs have higher power losses and thus a lower efficiency than LED bulbs. In light bulbs, the power loss is usually dissipated in the form of heat radiation. In LED bulbs, a strong heat is generated, but which can not be radiated and therefore must be dissipated.

A problem of cooling are the dimensions of heat sinks, which greatly increase the dimensions of the bulbs and therefore prevent the use of LED bulbs as a retrofit technology. Thus, it is not possible to reuse existing lamp housing by means of retrofit technology improved technically.

In the publication " RYAN AHEARN, Active cooling can boost lumen output in LED lighting, Thermal ACTIVE COOLING, LEDs Magazine, PennWell Corporation, June 2011 "LED cooling by means of synthetically generated airflow is described as a diaphragm pump which cyclically deflects a membrane, while at the same time the cavity has a small and large opening underneath the membrane and the air is slowly sucked in and jettisoned due to the different diameters Preferably, the air flows out of the large hole and passes through a surface that is thermally conductively connected to the LEDs, thereby continuously dissipating heat in the form of warm air from a relatively small heat sink The cycle frequency of the membrane is about 30 to 200 pulses per second, so the cooling is not continuous.

Due to the membrane principle, however, no large amounts of air can be moved. Also, warm air is always sucked in the slow intake again undesirable. For the suction is also more time than needed for the ejection, which is also disadvantageous. The amount of heat that can be dissipated per unit time is therefore limited. Also, the membrane sits between the LEDs and the ballast module, which can hinder integration and manufacturability. In addition, caused by the cyclical Actuation of the diaphragm audible perceptible noise in the range of 30 to 200 Hz, which can be problematic for consumer acceptance. Such noise is known, for example from the ballasts of the fluorescent tubes. These often hum with 100 Hz, ie the double mains frequency of 50 Hz.

It is the object of the present invention to provide an efficient concept for cooling bulbs.

This object is solved by the features of the independent claim. Advantageous forms of further education are the subject of the dependent claims.

The present invention is based on the recognition that the operating principle of the asynchronous machine, i. a rotating around a stator rotor, which is driven by a rotating field and can be configured, for example, as a squirrel cage, can be used for the cooling of lamps. For this purpose, the construction can be modified such that the stator is arranged inside, ie in the luminous body, and the rotor on the outside. Constructing a rotor with air blades, which are arranged so that the air flow generated by them is passed over the light source, so a cooling with high efficiency can be achieved. The stator can also be arranged outside the luminous element.

The construction of rotor and stator can be adapted to conventional bulbs such that the filament forms the stator and a suitably dimensioned rotor rotates about the acting as a stator filament without significantly exceeding the dimensions of the bulb. Since an asynchronous machine works very quietly, even such a designed cooling of the bulb is almost noiseless. The noise can be further reduced by an irregular arrangement of the air blades. As a result, periodic noise can be avoided.

According to one aspect, the invention relates to a luminous means with a luminous element, wherein at least one air blade rotatable around the luminous element is provided for cooling the luminous element. The respective air scoop can be formed as a lamella.

The at least one air scoop fan-like generates an air flow, which acts on an outer surface of the lamp, whereby the lamp is cooled. As a result, a continuous air flow can be generated because, for example, a Suction that occurs in membranes is excluded. As a result, a permanent cooling of the luminous element can be achieved.

Due to the arrangement of the at least one air scoop outside the luminous body, it rotates faster with increasing distance from a longitudinal axis of the luminous body. This allows efficient cooling can be achieved.

The light source can thus be constructed inexpensively. It can only have a movable component that can be made of only one material, for example, only metal or only conductive plastic. The heat dissipation is very high with small dimensions. The movement of the air scoop is acoustically noticeable only by a noise and not by a periodic sound and is therefore perceived as less disturbing. The light source has only small dimensions and allows use as a retrofit technology and thus access to the retrofit market.

The luminous element can be made of glass or plastic and be provided to house light-emitting elements such as LEDs or OLEDs or halogen elements. The waste heat of the light-emitting elements is conducted via thermally conductive materials to the air flow. However, the illuminant may be another illuminant that generates heat.

The luminous element may e.g. Glass or plastic body, which comprises a light-generating element, for example an LED or a halogen element.

According to one embodiment, the air blade is inclined with respect to a longitudinal axis of the luminous element in order to generate an air flow in the direction of the longitudinal axis. As a result, cooling of the filament in the longitudinal direction is achieved. If a plurality of air blades are arranged around the luminous element, these are also inclined in order to create a ventilator-like air flow along the longitudinal axis.

According to one embodiment, the lighting means comprises a drive and a rotor for driving the at least one rotatable air blade.

The drive can draw its energy from the same source that is used to operate the bulb, such as the power grid or a battery.

The rotor can be compact. The air vane preferably rotates continuously, so that there are no periodic noise, as they may occur in the intake and discharge of air in valve diaphragms. Furthermore, there is no need for continuously moving membranes which could age prematurely. There is a continuous smooth movement which is designed very quiet. Furthermore, no periodic clicking noises occur, because only an air flow is heard, which conveys the auditory impression of a quasi-noise, but not that of a periodic sound. A non-uniform arrangement of a plurality of air blades around the lamp around also avoids annoying whistling.

According to one embodiment, the drive is designed such that a rotating electric field is generated for driving the rotor. Thus, the drive can be arranged, for example, in the interior of the luminous element and the rotor outside the luminous element, for example as an external squirrel cage. In this way, the operating principle of an asynchronous machine for driving the rotor and thus the air scoop can be taken.

The drive is electro-magnetic according to this embodiment and thus operates quietly. In particular, there are no disturbing pumping sounds, as they are audible when using valves.

According to one embodiment, the drive comprises a plurality of coils which are sequentially excitable. For this purpose, the drive may comprise a control electronics for sequential excitation of the coils. In this way, a rotating field is generated that can drive the rotor.

The control electronics for energizing the coils can be accommodated in an optionally existing electronics, so that the light source can be produced inexpensively.

According to one embodiment, the drive is mounted inside the luminous body.

Thus, the structure can be made compact, since no cable must be led out of the lamp. As a result, the size of the luminous means is reduced so that it can be used as a retrofit luminaire in existing housings.

According to one embodiment, the rotor is designed as a cage rotor, which rotates when activating the drive around the luminous body. The squirrel cage can be designed as an outer squirrel cage arranged around the luminous body.

Squirrel-cage drives used, for example, in asynchronous machines, have a long life, are low maintenance, and show no brush wear, as in squirrel-cage rotors. They are briefly overloaded, for example, up to more than twice the nominal torque, show a nearly constant speed, there is no "run-through" at idle, they can be used in potentially explosive atmospheres, as there are no brushes or slip rings, so that brush fire or sparking is avoided. The risk of inflammation of lampshades is avoided.

Furthermore, an independent start-up is possible and the production costs are comparatively low. The squirrel cage is preferably de-energized and can also run in liquids, gases or in a vacuum. A start is also possible against high counter moments without aids. The drive with squirrel-cage rotor is very sturdy and has a high speed capability, so it comes with a power converter with a high power output. In addition, a squirrel-cage drive shows high field-loss efficiency.

According to one embodiment, the rotor is at least partially formed from an electrically conductive material, wherein the rotor is mounted on a plastic ring or on a ball bearing.

The bearing of the rotor on a plastic ring reduces disturbing noises.

According to one embodiment, the luminous means comprises a heat sink which is thermally coupled to the luminous body and the air scoop is designed to direct an air flow through the heat sink in order to cool the heat sink.

Thus both the electronics and the LEDs can use the same cooling concept. Sounds are essentially created only by the air flow, not by the cyclic actuation. That is, the noise is rather noisy and not periodic. This is psychoacoustically perceived as less disturbing.

According to one embodiment, the heat sink and the rotor are mounted in successively arranged rings, in particular with the same radii, are mounted around the luminous body. The term "equal" refers to a tolerance range of 0%, 1%, 2%, 5% or 10%.

When assembling the lamp, the elements of the lamp such as the LEDs, heat sink, electronics and stator of the fan ring thus form a unit. The fan is no longer a separate component. This reduces the manufacturing cost of the bulb.

According to one embodiment, a plurality of air blades rotatable about the luminous body are provided for cooling the luminous body, which are arranged unevenly around the luminous body. However, the air blades can also be arranged uniformly around the luminous body.

With a large number of air blades, the cooling effect increases and the efficiency increases. In addition, arises in uneven arrangement around the filament around no periodic tone, which is perceived as particularly disturbing. The cooling is therefore particularly quiet.

According to one embodiment, the air vanes have different lengths and / or are arranged aperiodically around the luminous body.

This is particularly advantageous for the perception of noise, since no a sinusoidal tone sets in aperiodischer arrangement, which is particularly disturbing perceptible, but possibly only a poorly perceptible diffuse noise.

According to one embodiment, the air blades and the rotor are formed in one piece.

The air blades and the rotor can be made so easy, for example in an injection molding process. The air blades and the rotor can be manufactured inexpensively from metal or from a conductive plastic.

According to one embodiment, the luminous means comprises a temperature sensor for detecting a temperature of the filament.

The temperature measurement can be used to check whether the light source is working within the permissible temperature range and, if necessary, initiate defensive measures.

According to one embodiment, the luminous means comprises a rotational speed controller which is designed to set a rotational speed of the rotor as a function of the detected temperature.

This allows the cooling then very low energy, since adapted to the temperature, work.

According to one embodiment, the luminous means comprises an LED arranged in the luminous body or an LED field with at least one LED. However, the luminous element can also be a halogen luminous body.

LED panels are constructed of LEDs that, depending on the data sheet, have a lifespan of up to 100,000 hours, which they can easily exceed if they are not connected incorrectly or unprotected. With rectifiers and current-constant buck converters, LEDs can be kept in optimum operating condition with low loss.

According to one embodiment, the luminous means is a retrofit luminous means. The lamp may have a socket for receiving the filament, wherein the socket can be designed as E14 or E27 thread.

The LED-based bulbs 100 can be manufactured in a retrofit housing with classic E14 or E27 thread. The high levels of waste heat generated by the LEDs, which are generated in a concentrated location, are efficiently dissipated to the environment. The luminous means 100 does not need a large heat sink and thus does not exceed the usual dimensions for illuminants, e.g. the incandescent lamp or the saving bulb, thus enabling the retrofit technology. The cooling of the luminous means according to the invention is efficient and very cost-effective.

• Fig. 1 eine schematische Darstellung eines Leuchtmittels gemäß einer Ausführungsform in seitlicher Schnittansicht;
• Fig. 2 eine schematische Darstellung des in Fig. 1 dargestellten Leuchtmittels in vorderwärtiger Schnittansicht; und
• Fig. 3 eine schematische Darstellung des in Fig. 1 dargestellten Leuchtmittels in rückwärtiger Schnittansicht.

Further embodiments will be explained with reference to the accompanying drawings. Show it:

• Fig. 1 a schematic representation of a lighting means according to an embodiment in side sectional view;
• Fig. 2 a schematic representation of the in Fig. 1 illustrated illuminant in Vorderwärtiger sectional view; and
• Fig. 3 a schematic representation of the in Fig. 1 illustrated illuminant in rear sectional view.

Fig. 1 shows a schematic representation of a luminous means 100 according to an embodiment in a side sectional view. The luminous means 100 comprises a luminous element 102 and an air blade 104 which can be rotated around the luminous element 102 and which is provided for cooling the luminous element 102. The air vane 104 is in the Fig. 2 and 3 , which show front and rear sectional views of the luminous means 100, shown once again.

According to one embodiment, the luminous means 100 has a drive 118, which has means for generating a rotary electric field. In one embodiment, the means are a plurality of coils 108 and control electronics 110 for sequentially energizing the coils 108 to produce the rotating field.

According to one embodiment, on the outside of the luminous means 100, a squirrel cage rotor 106 is mounted similar to an asynchronous machine. The difference to the classic asynchronous machine is that the stator is arranged inside the lamp 100, i.e., inside the lamp. is located in the lamp 102, and the rotor 106 is disposed outside, not vice versa as usual. By cyclically driving the stator coils 108, a rotating field is generated, which sets the outer squirrel cage in motion.

The rotor or rotor 106 of the apparatus for generating an air flow, which may be a fan for generating a continuous current, for example, sits on the outside of the tube of the luminous means 100 and not inside. The stator and the rotor 106 are therefore interchanged with respect to the structure of the asynchronous machine. There is only one moving part that sits on the outside of the light source 100 and not inside.

The drive 118 operates on the principle of the asynchronous machine, ie the drive 118 is effected by a rotating field. Seen electrically, the drive 118 corresponds to a transformer. The stator winding is the primary side and the squirrel cage rotor is the secondary side. The self-adjusting current depends on the speed. The rotor of the drive rotates always slower than the rotating field on the coils 108 of the primary side. As long as the rotor 106 is at the beginning, there is a transformer with secondary side short circuit. This results in high currents and strong magnetic fields. In this starting range, the drive 118 has a poor efficiency and warms up a lot. As the rotor 106 rotates and adapts to the rotating rotating field, the currents become smaller. According to one embodiment, the high starting currents are reduced by upstream starting resistors. The speed at the operating point will always be a few percent below the associated synchronous speed. This difference is called slip and is load-dependent. According to one embodiment, the number of slots of stator and rotor 106 is different or the grooves are arranged obliquely to the stator axis, ie to the main radiation direction of the luminous means 100 so as to prevent a resonance of the rotor 106.

According to one embodiment, the rotor 106 is realized as a squirrel-cage rotor with a winding of solid, highly conductive conductor bars (squirrel-cage), which are always short-circuited. In mass production, the laminated core of the rotor 106 can be provided with either grooves or holes which are then filled with aluminum. At the same time, the air blades 104 or fan blades are also cast as cooling fins. In operation, relatively high currents flow through the conductor bars and thus generate strong magnetic fields together with the iron sheets. However, the voltages are so low that no special isolation is necessary. A special design of the cage rotor is the resistance rotor, in which the conductor bars of the shorting cage are made of a material with higher resistivity. This achieves higher slip and modified startup behavior.

In one embodiment, the drive 118 includes control electronics 110. The drive 118 may have a high inrush current. If the inrush current is not known, one can assume about eight times the rated current. In one embodiment, the drive 118 employs a star-delta circuit cranking process. As a result, the starting power is reduced to about one third. The starting torque is reduced in the same ratio. With this circuit, the drive 118 is switched by reversing the contactors after the ramp-up time with star-connected winding strands to delta operation. According to one embodiment, the drive 118 has one or more frequency inverters in order to start up the drive 118 smoothly and adapted to the load with appropriate configuration or programming. In one embodiment, the drive 118 includes a squirrel cage. This has a favorable effect when starting the skin effect. At high slip, the electron concentration increases at the edge of the shorting bars, increasing the resistance. If the frequency drops again, the resistance also decreases. Various short-circuit bar profiles ensure that the characteristic is dynamic with the speed changes. The drive 118 can therefore be operated very quiet and power efficient.

According to one embodiment, the luminous means 100 comprises an LED array 114 arranged in the luminous element 102. LEDs are components made of semiconductors. According to one embodiment, the luminous means 100 comprises an LED chip, in which the energy of the electric current is converted into light energy with relatively little heat generation. In this case, a very narrow-band light is emitted. For this single color LEDs with the colors red, yellow, green, orange can be used. According to one embodiment, to realize white LEDs either the light of different color LEDs is superimposed or part of the light of blue LEDs is transformed into yellow light by means of a fluorescent phosphor which, mixed with the remaining blue component, gives white light.

Since the individual LEDs in comparison to incandescent or xenon gas discharge lamps have a low luminous flux, according to an embodiment, a plurality of LEDs are bundled together in a so-called LED modules or LED fields 114 interconnected. According to one embodiment, each LED is provided with its own bundling optics, according to another embodiment, an overall appearance for the entire module is used.

Between the LED panel 114 and the LEDs 114 and the electronics or the electronic ballast 110, no moving parts are attached. The only thing moving on the light source 100 is the outer squirrel cage. All other parts are static. The small distance between the LEDs 114 and the electronics 110 reduces the losses in delivering power from the electronics 110 to the LEDs 114. Typically, LEDs 114 have very low voltages, resulting in high currents. The length of the lines that carry high currents is thus reduced. This reduces losses and weight. The LEDs 114 as well as components of the electronics of the ballast 110 can thermally contact the same heat sink 112. There are no separate Entwärmungskonzepte necessary.

A short connection between the ballast 110 and the LEDs 114 also has a favorable effect on the EMC behavior. Switching regulators for LEDs are frequently used in ballasts which have a strong harmonic spectrum of the currents and voltages for supplying the LEDs. With a short line, the radiation of the interference spectra can be reduced.

Fig. 2 shows a schematic representation of the luminous means 100 in Vorderwärtiger sectional view. The heat loss of the LEDs 114 is delivered to the relatively small heat sink 112. This transfers the heat to radially mounted ribs. Through these ribs, an air flow 120 is guided, as in Fig. 1 illustrated in more detail, which is generated by the air blades 104 in the squirrel cage.

Fig. 3 shows a schematic representation of the luminous means 100 in rear sectional view. According to one embodiment, power transistors, such as are used in the ballast 110, which can form electronics, are thermally contacted with the same heat sink 112 in order to dissipate the heat. Through the heat sink 112, the plate can be easily contacted with the LED array 114. There are no moving parts between electronics 110 and LEDs 114. According to one embodiment, the generation of a rotating field by sequential driving of the stator coils 108 takes place very cost-effectively by a capacitor for phase shifting. According to one embodiment, the generation of the rotating field by sequential control of the stator coils 108 is very cost-effective by a simple integrated circuit.

According to one embodiment, the outer squirrel cage is made entirely of metal, so that it can be produced easily and inexpensively. According to one embodiment, the outer squirrel cage is mounted on a plastic ring 128, which is a very cost effective solution. A bearing of the Außenkäfigläufers on a ball bearing is not required because no large forces are transmitted. This also reduces potential noises.

According to one embodiment, the heat sink 112 and the rotor 106 are mounted in successively arranged rings with substantially equal radii around the luminous element 102. As a result, the diameter of the luminous means 100 does not exceed the diameter of a conventional illuminant with heat sink, but the diameter is even lower, since due to the cooling by the rotor 106, the heat sink 112 may be smaller, so that reduces its diameter. The diameter 124 of the luminous means 100, which is determined by the outermost parts, ie the rotor 106 and the heat sink 112, is not larger than the diameter of a standard light bulb, so that the lamp 100 due to its small space requirement for the Retrofit use is suitable and can replace conventional light bulbs or LED lighting.

The number of parts to be cooled for cooling is low. There are no continuously moving membranes that could age prematurely. There is a continuous smooth movement which is designed very quiet. There are no periodic pops. There is only one air flow to hear that conveys the sound impression of a quasi-noise, but not that of a periodic sound. A non-uniform arrangement of the profile leads to noise and avoids whistling noises. According to one embodiment, the air blades are not arranged periodically. For this purpose, the luminous element 102 has a multiplicity of air blades 104 which can be rotated around the luminous element 102 and which are arranged unevenly around the luminous element 102. According to one embodiment, the air blades 104 have different lengths and / or are arranged aperiodisch around the filament 102 around.

According to one embodiment, the air blades 104 and the rotor 106 are formed in one piece, for example manufactured as an injection molded part.

According to one embodiment, the rotational speed of the rotor 106 is dynamically adjusted according to the current temperature. For this purpose, the luminous means 100 has a temperature sensor for detecting the temperature of the luminous element 102, as well as a rotational speed controller which adjusts a rotational speed of the rotor 106 as a function of the detected temperature.

According to one embodiment, the luminous element 102 is enclosed by a socket 116, which has the purpose of holding the luminous element 102.

In one embodiment, the socket 116 is an E14 socket or an E27 socket. As a socket 116 or lamp socket or lamp base, the mechanical support of bulbs such as incandescent or the filament 102 is referred to, which also produces the electrical contact. For this purpose, the socket 116 has a contact 126, which is attached to the underside of the socket 116. Another contact can be realized on the socket itself, for example via a thread. Thus, the filament 102 are interchangeable without tools. According to an alternative embodiment, the luminous means 100 has a socket-free filament with free wire ends. These are either connected directly by soldering or terminals or made pluggable again by an additional element such as fairy lights.

According to one embodiment, an Edison thread is used as the base 116. The dimensions of the Edison thread are standardized according to DIN 40400 and also in IEC 60238: 1998. Common Edison threads according to DIN 40400 are for example E14, common for candle lamps up to 60 watts and for incandescent and energy-saving lamps up to 40 watts for example, 230 V and E27 as the most common version for 230 V incandescent and energy-saving lamps. E14 has an outside diameter of 14 mm, a core hole diameter of 12.5 mm and a pitch of 2.82 mm. E27 has an outer diameter of 27 mm, a core hole diameter of 24.5 mm and a pitch of 3.62 mm. Other alternatives for the socket 116 are the types E5.5, E10, E11, E12, E16, E18, E33 and E40.

According to one embodiment, the luminous means 100 has an electronic ballast 110. The ballast 110 is the device required for current limiting in gas discharge lamps and fluorescent lamps. It can be installed as a separate component in the luminaire or also be integrated in the luminous means 100, such as in the so-called energy-saving lamps. In this case, the lamp 100 can be operated directly on the mains. Ballasts 110 may also include the ignition and starting equipment required in some lamps. In this case, pulses of a few hundred volts to several kV and / or a preheating of the cathode can be effected in fluorescent lamps. Conventional ballasts (KGV) consist of an inductor or inductor, an iron core usually wound with copper wire. Due to the ohmic resistance of the copper, the so-called copper losses, and the Ummagnetisierungs- and eddy current losses in the core, it comes to heat generation and power losses of about 10-20% of the lamp power. The so-called low-loss ballasts (VVG) are a further development of the KVG. The VVG are characterized by a lower power loss. However, they sometimes have larger dimensions than the CCGs and are more costly due to the use of larger iron packages and better alloys in the production material. The losses are reduced by a larger winding cross-section and higher quality core materials or by lower magnetic flux densities. Conventional ballasts for fluorescent tubes and cold cathode tubes are stray field transformers and combine the transformation of the mains voltage into a high voltage, ie a few kilovolts, as well as their current limitation. They often have an adjustment for the current in the form of a mechanically variable magnetic shunt. In addition to KVG there are also electronic ballasts (ECG). A distinction is made between cold-start ECGs and warm-start ECGs. With warm start, there are still one-sided and two-sided warm starts. Cold start electronic ballasts ignite the fluorescent tube immediately after switching on with a high voltage. They claim The cathodes at startup strong, therefore, reduces the life of such luminous means. In the case of a warm start ECG, on the other hand, the glow cathodes of the fluorescent tube are first preheated for a period of about 0.5-2 seconds and then ignited first. Starting and ignition operations of electronic ballasts are, in contrast to conventional ballasts (CCGs), flicker-free with a conventional starter. The boot process is therefore noticeably faster than with KVG.

According to one embodiment, the luminous means 100 is a compact fluorescent illuminant with an integrated electronic ballast 110 for 230 V AC. This compact fluorescent lamp, like incandescent lamps, has an E14 or E27 Edison screw base. In foreign countries, such as the United Kingdom and Ireland, the United States, and partly also in France, bayonet bases, i. Socket of type B15d and B22d, common. According to one embodiment, the socket 116 is a bayonet socket, in particular of the type B15d or B22d.

According to one embodiment, the luminous means 100 has a plug-in socket or a socket. Plug-in sockets for compact fluorescent lamps with starter integrated in the bulb have two pins. Between the two contacts on the socket or on the socket is an elongated, block-shaped block made of plastic, the starter, i. a glow starter with suppression capacitor contains. The luminaire into which this bulb is inserted requires a conventional ballast for operation, including a 50 Hz choke coil. The starter is integrated into the light source and is exchanged with each change. Sockets for compact fluorescent lamps without integrated starter have four pins. This version does not contain a starter, only the phosphor itself. All four heating wire or cathode connections are led out. It is structurally equivalent to large tubular fluorescent lamps. The base is relatively short and therefore compact. The lamps suitable for these lamps can be equipped with either electronic or conventional ballasts.

According to one embodiment, the luminous means 100 has a tube socket. The tube diameter of fluorescent lamps is standardized. The number after the letter "T" (T: Tube) stands for eighths of an inch, ie 1/8 of 25.4 mm = 3.175 mm. For example, a T5 tube has a diameter of 5/8 inches, which is about 16 mm. The pin spacings of the pedestals at both ends of the straight types are also standardized. For different tube diameters come here partly identical Base with, for example, the same pin distance to use. As a result of this measure, T8 tubes fit into the sockets of older T12 tubes and can replace them.

According to one embodiment, the luminous means 100 has a tube socket. The bayonet base is also referred to as Swansocket or Swanfassung. It consists of a smooth metal cylinder with two stripped elevations. To attach, it is first inserted and then fixed by rotation. For this purpose, a bayonet closure may be provided.

According to one embodiment, the luminous means 100 has a pin base or a bipin foot base. Bipin-foot standardization is standard on lamp sockets for halogen lamps and is part of IEC standardization. In smaller versions, where the pins are closer together, one speaks of mini-bipin. The lamp base here has two grooves in which a spring mounted on the front side can engage.

LIST OF REFERENCE NUMBERS

100

Lamp

102

illuminant

104

An airfoil (s)

106

rotor

108

Do the washing up)

110

Control electronics or ballast

112

heatsink

114

LED field

116

version

118

drive

120

airflow

122

lampshade

124

Diameter of the bulb

126

Contact

128

Plastic ring

Claims (17)

Lighting means (100), with a luminous body (102), wherein for cooling the luminous body (102) at least one of the luminous body (102) rotatable around air blade (104) is provided. Illuminant (100) according to claim 1, wherein the air scoop (104) is inclined with respect to a longitudinal axis of the luminous body to produce an air flow in the direction of the longitudinal axis. A lighting device (100) according to claim 1 or 2, comprising a drive (118) having a rotor for driving the at least one air blade (104). The lighting device (100) of claim 3, wherein the drive (118) is configured to generate a rotary electric field for driving the rotor. A lighting device (100) according to any one of claims 3 or 4, wherein the drive (118) comprises a plurality of coils (108) which are sequentially energizable. Illuminant (100) according to one of claims 3 to 5, wherein the drive (118) is mounted within the luminous body (102). Illuminant (100) according to one of Claims 3 to 6, in which the rotor (106) is designed as a squirrel cage rotor, in particular as an external squirrel cage rotor arranged around the luminous body (102). Lamp (100) according to one of claims 3 to 7, wherein the rotor (106) is formed of an electrically conductive material and mounted on a plastic ring (128) or on a ball bearing. A lighting device (100) according to any one of the preceding claims, comprising a heat sink (112) thermally coupled to the light body (102), the air blade (104) being adapted to direct an air flow (120) through the heat sink (112) to direct the air flow (120) To cool the luminous body (102). Illuminant (100) according to claim 9, wherein the heat sink (112) and the rotor (106) in successively arranged rings, in particular with the same ring radii, around the luminous body (102) are mounted around. Illuminant (100) according to one of the preceding claims, wherein for cooling the luminous body (102) a plurality of around the luminous body (102) around rotatable air vanes (104) is provided, which are arranged uniformly or non-uniformly around the luminous body (102) around. Illuminant (100) according to claim 11, wherein the air blades (104) have different lengths and / or aperiodisch around the filament (102) are arranged around. A lighting device (100) according to claim 11 or claim 12, wherein the air blades (104) and the rotor (106) are formed in one piece. Illuminant (100) according to one of the preceding claims, with a temperature sensor for detecting a temperature of the luminous body (102). The illuminant (100) of claim 14, further comprising a speed controller configured to adjust a speed of the rotor (106) in response to the sensed temperature. Illuminant (100) according to one of the preceding claims, wherein the luminous body (102) comprises an LED field (114) with at least one LED or a Halogenleuchtelement. Illuminant (100) according to one of the preceding claims, which is a retrofit lamp.

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