DE102007053611B3 - Light for use by dentist, has light arrangements producing operating light beams that meet in pre-determined distance from pivot point of LEDs, where one of arrangements with straightening mirror produces beam from secondary light cone - Google Patents

Abstract

The light (10) has a pair of light arrangements (12.1, 12.2) producing operating light beams (26.1, 26. 2) that meet in a pre-determined operating distance (D) from a geometrical pivot point of LEDs (14.1, 14.2). The arrangements are arranged such that primary and secondary light cones (16.1, 16.2, 22.1, 22.2) run outwardly and away from an operating surface (A). The arrangement (12.1) includes a straightening mirror (24.1) i.e. mangin mirror, producing the beam (26.1) from the cone (22.1). The arrangement (12.2) has a straightening mirror (24.2) producing the beam (26.2) from the cone (22.2).

Description

The The invention relates to a luminaire according to the preamble of claim 1.

Such a lamp is from the DE 36 33 609 A1 known. In the lighting device described therein, two reflectors are used to direct light beams to the work surface via a multiple mirror. The disadvantage of this is the complex structure of the lamp.

Another light is from the DE 10 2006 004 995 A1 known. In the luminaire described there, light-emitting diodes (LED) are used as light sources. From light emitted by the LEDs, a light field is generated by a successor optics in the form of a lens array. A disadvantage of such a lamp is the tendency for strong shadow cracks. Namely, if the light is used, for example, as a dental light to illuminate a patient's mouth, it may happen that the dentist gets his head or his hand in the beam path between light and patient. The result is a sharp shadow between the illuminated area and the unlit area of the patient. This is disturbing for the treatment and therefore undesirable.

Of the Invention is based on the object, a simply constructed light specify.

The Invention solves the problem by a luminaire according to claim 1.

Advantageous on the lamp according to the invention is that sharp silhouettes are avoided. If the dentist gets for example, by hand in the first working light beam of first light assembly, the patient is through the second and optionally further by the further working light beams evenly over that entire illuminated field illuminated. The result is a low-contrast partial shade.

Advantageous In addition, the luminaire is glare-free. The reflector arrangements can namely be formed in particular by using the aperture so that all light that is emitted by the respective light emitting diodes is only directed to the directional mirror. Stray light, for example could dazzle the patient or the dentist, can not arise with it.

in the The scope of the present description is under a light emitting diode also a plurality densely combined in an assembly on individual light-emitting diodes understood. Such light-emitting diodes are under known as multi-LEDs. If more than two lighting arrangements are present, preferably go through all the working light beams the work surface. If the working light beams are convergent, the working surface preferably by the foci of the working light beams. Located in the work surface then the highest illuminance outside the lamp in front. It is possible, not necessary but that all light of all working beams through the work surface runs. It is sufficient if the emerging from the lamp work beams For example, more than 80% run through the work surface.

Prefers the working light beams are not divergent, in particular convergent. Alternatively, the working light beams are substantially parallel, by which is meant that the working light rays are not in the stringent mathematical sense must run parallel, for example a divergence angle of 15 ° is tolerable. It is also possible to provide individual working beams convergent and others in parallel. The distance of the work surface from a geometric center of gravity of the light-emitting diodes is 50 cm up to 150 cm. In this way, a bright light is obtained, the can be well positioned by hand.

In a preferred embodiment are the first and the second arrangement, except where applicable the LEDs, identical or mirror-symmetrical to each other. If more than two light arrangements are present, they are preferred all lighting arrangements, with the possible exception of light-emitting diodes, constructed identical or mirror-symmetrical to each other.

It is possible, that individual luminaire arrangements with each other different light emitting diodes exhibit. For example, a lighting arrangement with a Be provided with a light-emitting diode, which has a particularly high blue light and / or UV component possesses. It is also possible to have one or more lighting arrangements with white light LEDs to equip and individual or all luminaire arrangements with individually controllable Light emitting diodes of different spectral emission characteristics ("Color") This way can with little equipment expenditure the color of the be regulated or controlled by the light emitted light.

In a preferred embodiment the reflector assembly comprises a diaphragm, the aperture of which focus area forms. In this way, scattered radiation is effectively suppressed and introduced Dazzling avoided by doctor or patient. The reflector arrangement For this purpose, it is preferably completely closed away from the diaphragm.

The reflector arrangement preferably comprises a lens, in particular a cylindrical lens. These Lens is preferably arranged between diaphragm and straightening mirror. Through the lens, a predetermined shape can be impressed on the secondary cone of light. For example, the lens is designed so that an ellipsoidal or rectangular secondary cone of light is formed.

A particularly robust and easy to maintain light is obtained when the leveling mirror is a manganese mirror. Particularly preferred the manganese mirror convex concave, with one of the reflector assembly opposite side an outer radius of curvature has 1.2 to 2.8 times, especially about one and a half times so big like an inside radius of curvature an inner circle of curvature one of the reflector assembly facing side of the Mangin mirror. The advantage of this is that the reflector arrangement with its focus area in the vicinity of a Indoor curvature circle center of the inner circle of curvature can be arranged. In this way, with simple constructive Means a parallel or divergent working light beam obtained. Further, in contrast to a front surface mirror, the mirror surface is mechanical protected and disturbing retroreflections do not run into the work area (reflex suppression).

Prefers the lamp has a plurality of lamp assemblies whose Light-emitting diodes arranged at least in groups in a common light-emitting diode level are. For example, four, five, six, seven, eight or more luminaire arrangements provided. Particularly preferred are the Light emitting diodes at least in groups on a circular, elliptical or rectangular curve arranged or form a regular polygon. Alternatively, they are at least in groups linear, in rows of two or arranged in several lines. It results so very compact Luminaires whose LEDs are also easy to cool.

According to the invention Luminaire assemblies arranged so that the primary light cone outward. In other words the light emitting diodes of the individual lamp assemblies are adjacent arranged to each other, resulting in a compact design of the lamp leads. Because of their proximity to each other, the LEDs are also easy to cool and to supply electricity.

A particularly simple design for the lamp results when the lamp assemblies on a common pedestal are mounted.

According to one preferred embodiment the LEDs in their blue light portion adjustable and the light has an operating device for regulating and / or for switching on and off of the blue light component. Under blue light is especially blue and violet visible light and adjacent UV radiation understood. Alternatively or additively, the luminaire has at least one filter for filtering a blue light component. The filter may be adjacent be arranged to the reflector. Will the light as a dental light used, there are applications where a UV or blue light component undesirable is. For example, harden for sealing teeth used plastics under blue light irradiation. The light is then set up such that the blue light component can be suppressed, which leads to curing in dental polymers. For example, the Light-emitting diodes designed so adjustable that a wavelength component is largely suppressed below 450 nm.

A particularly effective cooling the lamp is achieved when the LEDs at least in groups in thermal contact with a common, central cooling device, especially with a heat pipe stand. Under a heat pipe (English: heat pipe) is understood to mean a heat transfer device, when at one point a coolant evaporated and recondensed at another point, the coolant.

The specified LEDs have conveniently a power of more than 1 W. Also favorable is a performance of less than 50 W per LED.

in the Following is an embodiment of the Invention with reference to the attached Drawings closer explained. It shows

1 a luminaire according to the invention in a cross-sectional view,

2 the luminaire according to 1 in a perspective view,

3 the lamp according to 1 and 2 in a side view and

4 a view from above of the lamp according to the preceding figures.

1 shows a lamp 10 which is a first lighting arrangement 12.1 and a second luminaire arrangement 12.2 includes. In the following, only the lighting arrangement 12.1 described in more detail. The corresponding components of the luminaire arrangement 12.2 and the other lamp arrangements carry a corresponding Zählsuffix. The luminaire arrangement 12.2 , is mirror-symmetrical to the luminaire arrangement 12.1 and carries the counting suffix ".2". Reference numerals without counting suffix refer to the respective object as such.

The luminaire arrangement 12.1 includes one first light-emitting diode 14.1 for emitting a first primary cone of light 16.1 and a first reflector arrangement 18.1 for bundling the primary cone of light 16.1 on a first focus area 20.1 , This creates beyond the first focus area 20.1 a first secondary cone of light 22.1 , The secondary beam 22.1 falls on a first leveling mirror 24.1 in the form of a mangin mirror. This creates a first working light beam 26.1 at an angle α relative to a plane of symmetry S _{1 of} the luminaire 10 runs.

The luminaire arrangement 12.2 is mirror-symmetrical to the luminaire arrangement 12.1 built so that a second working light beam 26.2 with the first working light beam 26.1 meet in a work surface A, located at a working distance D of about 80 cm below the light-emitting diodes 14.1 . 14.2 located. It can be seen that the secondary light cone 22.1 . 22.2 run outward with respect to the first plane of symmetry S ₁ .

The light-emitting diodes 14.1 and 14.2 are on boards 28.1 respectively. 28.2 arranged on a common base 30 are attached. In 1 not visible are the LEDs 14.1 . 142 via thermally conductive structures, such as thermal grease and a copper component, in contact with a likewise not shown heat pipe. From the light-emitting diodes 14.1 . 14.2 Heat generated during operation is directed into the heat pipe, where it vaporizes a coolant, dissipating heat. The vaporized coolant is passed via a likewise not shown coolant vapor channel to a capacitor, for example, in a frame 32 the light 10 integrated is the reflector arrangement 18.2 includes a bezel 34.2 , which is the only opening of an otherwise closed body 36.2 represents. The aperture 34.2 is located in an inner curvature circle center M _{IK of} an inner circle of curvature K _{inside of} the standard mirror 24.2 , For adjustment of the leveling mirror 24.2 this is about a sliding bracket 38 at the frame 32 attached.

In the beam direction under the reflector 18.2 a non-drawn cylindrical lens is arranged, which is the working light beam 26.2 gives an oval shape. For this reason, the working surface A is oval to substantially rectangular. The work surface A is an area in space and not a physical surface of an object, but in operation, the work surface A is preferably provided so that the work surface A coincides with the surface of an object to be illuminated.

2 shows a perspective view of the lamp 10 , It can be seen that these six lighting arrangements 12.1 to 12.6 includes, of which the lighting arrangements 12.1 . 12.3 and 12.5 only partially visible. All luminaire arrangements are with their reflector arrangements 18 on the pedestal 30 attached, in turn, to the frame 32 screwed on. The frame 32 includes a crossbar 40 , the one positioning handle 42 wearing. The lights 12.1 to 12.6 are arranged in pairs opposite each other in pairs and the directional mirror 24.1 to 24.6 are inclined so that all working light rays meet in the non-marked working surface A. If now a working light beam is obscured, for example the working light beam 26.2 Thus, an object in the work surface A becomes the other working light rays 26.1 . 26.3 . 26.4 . 26.5 and 26.6 still fully lit and there is no sharp silhouette.

At the frame 32 a non-illustrated control unit is arranged with which the LEDs can be switched on and off individually or jointly. There is also a control device with which the spectrum of the light emitted by some or all light-emitting diodes can be adjusted in terms of its spectrum or its frequency constituents.

3 shows a side view of the lamp 10 with the reflector arrangements 12.2 . 12.4 and 12.6 , It can be seen that the socket 30 is convex shaped, so that the lighting arrangements 12.2 . 12.4 . 12.6 with respect to a second plane of symmetry S ₂ which is perpendicular to the first plane of symmetry S ₁ (cf. 1 ) run away. The frame 32 includes a roof 44 , at the Richtspiegel 24.2 . 24.4 . 24.6 are attached.

The beyond the central lighting arrangements 12.4 and 12.3 (not visible in 3 ) arranged lateral lamp assemblies 12.1 . 12.2 . 12.5 . 12.6 have working light beams which are β at an angle relative to the second plane of symmetry S ₂ .

4 shows a view from above of the lamp according to the invention 10 ,

10

lamp

12

light assembly

14

led

16

Primary light cone

18

reflector arrangement

20

focus area

22

Secondary beam

24

directing mirrors

26

Operating light beam

28

circuit board

30

base

32

frame

34

cover

36

body

38

bracket

40

transverse spar

42

positioning handle

44

top, roof

α

working angle

β

angle

A

working surface

D

working distance

K _inside

Inside turning circle

M _IK

Indoor curvature circle center

S ₁ , S ₂

plane of symmetry

Claims (13)

Lamp ( 10 ), with (a) a first luminaire arrangement ( 12.1 ) for generating a first working light beam ( 26.1 ), which (i) a first light-emitting diode ( 14.1 ) for emitting a first primary light cone ( 16.1 ) and (ii) a first reflector arrangement ( 18.1 ) for bundling the first primary light cone ( 16.1 ) on a first focus area ( 20.1 ), so that beyond the first focus area ( 20.1 ) a first secondary cone of light ( 22.1 ), (b) at least one second luminaire arrangement ( 12.2 ) for generating a second working light beam ( 26.2 ), which (i) a second LED ( 14.2 ) for emitting a second primary cone of light ( 16.2 ) and (ii) a second reflector arrangement ( 18.2 ) for bundling the second primary cone of light ( 16.2 ) to a second focus area ( 20.2 ), so that beyond the second focus area ( 20.2 ) a second secondary cone of light ( 22.2 ), (c) wherein the first luminaire arrangement ( 12.1 ) and the second luminaire arrangement ( 12.2 ) are arranged to one another such that the first working light beam ( 26.1 ) and the second working light beam ( 26.2 ) at a predetermined working distance (D) from a geometric center of gravity of the light-emitting diodes ( 14.1 . 14.2 ) in a working surface (A), characterized in that (d) the luminaire arrangements ( 12 ) is arranged so that the primary light cone ( 16.1 . 16.2 ) and the secondary light cone ( 22.1 . 22.2 ) and away from the working surface, (e) the first luminaire arrangement ( 12.1 ) a first leveling mirror ( 24.1 ) for generating the first working light beam ( 26.1 ) from the first secondary cone of light ( 22.1 ) and (f) the second luminaire arrangement ( 12.2 ) a second leveling mirror ( 24.2 ) for generating a second working light beam ( 26.2 ) from the second secondary cone of light ( 22.2 ). Luminaire according to claim 1, characterized in that the working light beams ( 26 ) are not divergent, in particular convergent. Luminaire according to one of the preceding claims, characterized in that the first and the second luminaire arrangement ( 12.1 . 12.2 ), with the possible exception of light-emitting diodes ( 14 ), identical or mirror-symmetrical to each other are constructed. Luminaire according to one of the preceding claims, characterized in that the reflector arrangement ( 18 ) an aperture ( 34 ) whose aperture is the focus area ( 20 ). Luminaire according to one of the preceding claims, characterized in that the reflector arrangement ( 18 ) comprises a lens, in particular a cylindrical lens. Luminaire according to one of the preceding claims, characterized in that the directional mirror ( 24 ) is a manganese level. Luminaire according to claim 6, characterized in that the manganese mirror is konvexkonkav, wherein one of the reflector arrangement ( 18 ) side has an outer radius of curvature which is 1.2 to 2.8 times as large as an inner radius of curvature of an inner circle of curvature (K _inside ) of the reflector assembly ( 18 ) facing side of the mangin mirror. Luminaire according to claim 6 or 7, characterized in that - the inner circle of curvature (K _inside ) has an inner curvature circle center (M _IK ) and the - diaphragm ( 34 ) or the lens is disposed in the immediate vicinity of the inner circle of curvature center (M _IK ). Luminaire according to one of the preceding claims, characterized by a plurality of luminaire arrangements ( 12 ), whose LEDs ( 14 ) are arranged at least in groups in a common light-emitting diode level. Luminaire according to claim 9, characterized in that the light-emitting diodes ( 14 ) at least in groups form a regular polygon or are arranged on a circle, rectangle or ellipse line. Luminaire according to claim 10, characterized in that the lighting arrangements ( 12 ) on a common base ( 30 ) are mounted. Luminaire according to one of the preceding claims, characterized in that light-emitting diodes ( 14 ) are controllable in their blue light component and that the lamp ( 10 ) comprises an operating device for controlling the blue light component and / or that the lamp comprises at least one filter for filtering a Blue light component includes. Luminaire according to one of the preceding claims, characterized in that the light-emitting diodes ( 14 ) are in thermal contact with a heat pipe.