DE202004009691U1 - Electrical light for use in a torch has a light emitting diode that can be adjusted relative to focal point of a reflector - Google Patents

Abstract

The lighting unit has a light emitting diode, LED, [16] mounted on a holder [19] that is set into a mirrored reflector [30.1]. The LED position may be adjusted so that it is at the focal point of the reflector. A lens is set into the end [30.2] and the unit is built into a torch.

Description

The The present invention relates to a lamp with a housing, at least one in the case arranged LED lamps and with an optical device, which are at a distance from the LED illuminant in a beam path at least one light beam is arranged and a light beam can reflect and / or break.

Such Luminaires are known from the general prior art.

today will replace Halogen lamps or other known light sources often have one LED (light emitting diode) inserted in a lamp. The well-known state The technology with an LED as the illuminant shows the disadvantage that such lights are not focusable and therefore only for generation a wide beam can be used. When trying with one LED lamps can also produce a spot beam So far, only to generate wide beams with a reduced width. Such lights can are not and are not used to generate a spot beam so far not comparable to conventional lights with which a spot beam can be set.

The The object of the present invention is therefore a lamp with at least to create an LED as a lamp with which both wide beams and a point beam can also be generated.

The The object is achieved in that the LED lamp in an upstream or in the optical device existing focus is arranged.

The Arrangement of the LED illuminant in the upstream or in the optical device Focus is a prerequisite for that with the help of the optical device, either a reflector, a lens device or a combination thereof, a spot beam can be generated.

It is advantageous if the optical device has a specular reflector which limits the beam path.

On Another advantage of the lamp according to the invention results if the optical device has an aspherical lens.

By the change the distance between the LED illuminant and the optical device broad beams and at least one spot beam can be generated.

According to the Light as a street light be used. Due to low energy consumption Such a street lamp can achieve an optimized radiation effect be operated with an accumulator that is powered by solar energy becomes.

Further Advantages of the present invention result from the features of further subclaims.

embodiments The present invention is described in more detail below with reference to the drawings. Show it:

1 is a schematic representation of the side of an optical device in a first embodiment, in which an LED lamp is arranged in the focus of a mirror reflector;

2 a schematic representation of the side of an optical device in a second embodiment, in which the LED illuminant is arranged in the lying focal point of an aspherical lens;

3 a schematic representation of the side in which the LED lamp of the first embodiment is rotatably arranged in a mirror reflector for use in a beacon;

4 a schematic representation of a variant of the first or second embodiment of the present invention, in each of which an LED illuminant is arranged on one side surface of a multi-sided carrier with a rotating lens or rotating reflector;

5 is a schematic representation of a street lamp with one or more LED lamps with an aspherical lens.

6 is a schematic representation of the lamp according to the invention as a hand lamp.

In 1 the part of a lamp is shown schematically, which has to do with the radiation characteristics of a lamp. A complete light fixture that the in 1 shown components can be found in 6 shown schematically. In the 6 The lamp shown is a hand lamp, but in other embodiments such a lamp can also be a floor lamp or a street lamp. Using the example of the portable spotlight 6 the general structure will now be described. 6 shows a portable spotlight 10 in a partially cut representation. The portable spotlight 10 has a housing 11 which is essentially made in one piece. The housing 11 can consist of common materials, for example aluminum, polyethylene or a other suitable material. The housing 11 is in the area of a top to a handle 12 shaped. On both sides of the handle 12 are means for attaching a shoulder strap formed, the two eyelets in the present embodiment 13 represent. In the area of an underside, the housing is shaped into support surfaces, for example the feet shown 14 with which the handheld spotlight 10 can be placed on a surface. The housing faces on one side 11 continue to have an opening that acts as a circular recess 15 is trained. In other embodiments, the opening can also have other geometric shapes. Inside the case 11 is an LED lamp 16 arranged. The LED illuminant 16 is in the area of the recess 15 of the housing 11 arranged and is in the focus of an optical device 30 (Details are given below). The optical device 30 comprises a specular reflector in a first embodiment 30.1 and a windscreen 30.2 , in a second embodiment only an aspherical lens 30.3 and in a third embodiment a combination of a specular reflector 30.1 and aspherical lens 30.3 , In the embodiments with an aspherical lens 30.3 can optionally also have a windscreen 30.2 be provided. Between the optical device 30 and the housing 11 is a sealing ring 19 positioned to prevent dust and / or moisture from entering the housing 11 prevented.

The LED illuminant 16 sits on a bracket 19 in the housing 11 , The bracket 19 can consist of an elastic material, for example a plastic or rubber 15 , Through the bracket 19 are impacts, for example from the outside of the housing 11 act, for example, if the headlight is dropped roughly 10 , attenuated, so that damage to the LED lamp 16 is avoided.

Furthermore is inside the case 11 a power source 17 to supply the LED lamp 16 arranged with energy. The power source 17 consists of several accumulators in the present case 18 that over lines 20 with the LED lamp 16 are connected. Alternatively, batteries can also be used for the power supply. For starting up the portable spotlight 10 the housing is an on / off switch 23 assigned to that via lines 20 with the accumulators 18 and the LED lamp 17 connected is.

In the area of the housing 11 Means for acoustic and / or optical signaling can also be arranged, for example a (light) diode or a loudspeaker. These means are used to signal the impending end of the operating period, that is to say the point in time at which they are in the accumulators 18 stored energy is consumed or the capacity of the accumulators 18 is exhausted. To determine the capacity of the accumulators 18 is in the housing 11 a circuit arranged consisting of electronic components 22 on a circuit board 21 , As soon as the capacity of the accumulators falls below a certain threshold value, this is signaled by the acoustic and / or optical means. For this purpose, the circuit is connected on the one hand to the accumulators and on the other hand to the acoustic and / or optical means, which are actuated automatically by the circuit. In the place of the capacity of the accumulators 18 the voltage can also be measured to determine the remaining operating time. The optical and / or acoustic means can be actuated, for example, five minutes before the end of the operating time. The time at which the end of the battery capacity is warned can be adjusted by programming the circuit accordingly.

Multiple LED lamps can also be used 16 in the housing 11 be arranged. For example, two LED lamps with different energy consumption and correspondingly different luminosity can be used, for example 1 watt or more. Depending on the capacity of the accumulators 18 the operation of the two LED lamps 16 automatically controlled by the circuit. In this case, the housing faces 11 a single on / off switch 23 on, with the handheld spotlight 10 can be put into operation. As long as there is sufficient capacity, both LED bulbs 16 or alternatively the LED lamp 16 operated with the greater energy consumption. As soon as the capacity falls below a certain threshold, the LED light bulb turns off 16 switched off with greater energy consumption and only the LED lamp 16 operated with lower energy consumption.

Furthermore, the LED lamps 16 an operating element for regulating the intensity of the light beam generated can be assigned, for example a controller with which the intensity can preferably be regulated continuously. In the exemplary embodiment shown, the housing has 11 still a socket 24 on. With the help of the socket 24 is the power source 17 and / or the at least one LED lamp 16 connectable to an external power source. In this way, the at least one LED lamp 16 regardless of the inside of the case 11 arranged power source 17 operate. Furthermore, the external power source can be used, the accumulators 18 charge. The case also points 11 a transport lock 25 on. With the help of the transport lock 25 can the operation of the bulbs 16 regardless of the switch 23 under be bound. In this way, accidental actuation of the hand lamp can be avoided 10 be avoided during transport.

The operation of the hand lamp is advantageous 10 using a wireless remote control. For this purpose, the remote control can have an on / off switch, the function of which on the housing 11 attached switch 23 equivalent. In this way, any lamp 16 be operated. Furthermore, the remote control can have a controller for the intensity of the light beam generated. However, the remote control preferably has a switch with which the two aforementioned functions can be controlled in combination. For example, a button that switches each lamp when simply pressed 16 switches on or off. A longer press on the button serves to regulate the intensity of the light beam generated, i.e. for dimming. Furthermore, the remote control can have the same optical and / or acoustic means for signaling the end of the operating time as the hand lamp 10 ,

In 1 is the LED lamp 16 arranged in the focal point F1, which is upstream before a light beam emerges from the lamp. The reflector 30.1 limits the beam path of the LED illuminant 16 emitted light rays. On the opening side of the mirror reflector 30.1 is a translucent pane 30.2 arranged. The beam angle of the LED lamp is 120 to 160 °. The distance of the LED lamp 16 from the specular reflector 30.1 can be changed (see arrow direction), depending on whether a wide beam or a point beam is to be generated.

In 2 is a second embodiment of the optical device 30 shown. The LED illuminant 16 is in the focal point downstream 1 an aspherical lens 30.3 arranged. The aspherical lens 30.3 is with a straight base 30.4 the LED lamp 16 facing. The distance between the LED lamps is also in the second embodiment 16 and the aspherical lens 30.3 changeable, depending on whether a broad beam or a point beam is to be generated.

The change in the distance between the LED lamps 16 and the optical device 30 takes place by known adjustment means, which will not be described in more detail here. As a rule, the optical device 30 be adjusted and not the LED lamp 16 ,

In 3 is the LED lamp 16 in relation to the optical device 30 shown schematically in a third embodiment of the present invention. In the third embodiment, the LED lamp is located 16 also in a mirror reflector 30.1 in the focal point F1, but is rotatably supported there. The rotation takes place around the optical axis coinciding with a primary light beam. Such an embodiment can be used in a beacon, for example a blue light. In this embodiment, current is transmitted via a slip ring (not shown) with carbon brushes. With a 1 watt LED it is possible to generate the legally required amount of light.

In 4 a holder for several LED lamps is schematically shown, which can be used in a lamp according to the present invention.

A triangular or polygonal beam 31 , with the corresponding number of areas, which is installed in the middle of an all-round beacon, points to each side 32 at least one LED lamp 16 on. At least an aspherical lens 30.3 moves concentrically around the wearer 31 around, and at a distance through which the LED lamps 16 lie in the central focal point F1 of the aspherical lens. The carrier preferably has four side surfaces 32 , so that four LED lamps with a beam angle of 110 ° meet the legal requirements for all-round light of 360 °.

Instead of the aspherical lens 30.3 can also be a light reflector in this embodiment 30.1 be used. The light reflector 30.1 then turns at such a distance around the LED lamps 16 around that they are in focus F1.

In 5 the upper part of a street lamp, a so-called street lighting, is shown schematically. The street lighting becomes at least one LED lamp 16 and preferably with several LED lamps 16 operated. The LED lamps 16 have a beam angle of 110 ° or more. The optical device 30 comes with an aspherical lens 30.3 operated.

by virtue of Street lighting can use energy-saving LED bulbs operated with an accumulator as an energy source, like this already for the hand lamp was described. The accumulator can be powered by solar energy and the corresponding device, which is generally known and is not the subject of the present invention, constantly fed become. The accumulator is preferably located in the mast of one Street lighting and has a sensor for Day and night switch on.

Claims (11)

Luminaire with a housing, at least one LED illuminant arranged in the housing and with an optical device which is arranged at a distance from the LED illuminant in a beam path of at least one light beam, characterized in that the LED illuminant ( 16 ) in an upstream of the optical device ( 30 ) existing focal point (F1) is arranged. Luminaire according to claim 1, characterized in that the optical device ( 30 ) a specular reflector ( 30.1 ) widened, limited the beam path. Luminaire according to claim 1 or 2, characterized in that the optical device ( 30 ) an aspherical lens ( 30.3 ) having.. Luminaire according to one of claims 1 to 3, characterized in that the distance between each LED lamp ( 16 ) and the optical device ( 30 ) is changeable. Luminaire according to claim 1 or 2, characterized in that each LED lamp ( 16 ) is arranged rotatably about an axis coinciding with a primary light beam. Luminaire according to claim 2, characterized in that each LED lamp ( 16 ) on one side surface ( 32 ) a multi-sided carrier ( 31 ) is arranged and the specular reflector ( 30.1 ) around the multi-sided carrier ( 31 ) is rotatably arranged around. Luminaire according to claim 3, characterized in that each LED lamp ( 16 ) on one side surface ( 32 ) a multi-sided carrier ( 31 ) is arranged and at least one spherical lens ( 30.3 ) around the multi-sided carrier ( 31 ) is rotatably arranged around. Luminaire according to one of claims 1 to 7, characterized by an accumulator ( 18 ) as an energy source. Luminaire according to one of claims 1 to 8, characterized in that the or each lamp ( 16 ) can be operated by a wireless remote control. Luminaire according to claim 9, characterized in that a decrease in capacity an energy source below a certain threshold by optical and / or acoustic means can be signaled. Luminaire according to claim 9 or 10, characterized in that the intensity of the at least one generated light beam preferably continuously adjustable is.