DE102019129135A1 - 3D printing process for the production of a luminaire element with an optical part - Google Patents

Abstract

The present invention relates to a 3D printing method for producing a lighting element (9) having at least one optical part (1) for directing light with an optical body (2) made of an optical material, with the optical body (2) being made of the optical material during 3D printing a locally defined light-influencing material is also printed in order to form at least one locally defined light-influencing area (3) in the printed optical body (2). The present invention also relates to an optical part (1) produced by a 3D printing process according to the present invention, as well as a lamp (10) having an optical part (1) according to the invention and a lamp (7) for emitting light.

Description

The present invention relates to a 3D printing method for producing a lighting element with an optical part, as well as a lighting element produced using the method and a lighting fixture equipped with the lighting element.

Optical parts or optics are well known from the prior art and basically fulfill the purpose of guiding light. For various reasons, it can be advantageous to incorporate light conversion materials or other light-influencing materials into corresponding optical parts or optics. These are, for example, mixed into the optical material used to manufacture an optical part, for example by means of an injection molding process, and are then present in an undefined distribution in the optical part after the manufacture thereof. The light conversion substances are arranged in a correspondingly chaotically distributed manner in the optical part, which is generally designed as a volume body. The aim of corresponding conversion substances (phosphors) is to convert the light introduced into the optics in a targeted manner, for example, from one wavelength to a defined other wavelength and thus to bring about a targeted change in wavelength, wavelength shift or color change. For example, wavelength changes or shifts or color changes caused by the optics (for example, their geometry) can be generated or corrected. Other light-influencing materials can produce other light-influencing properties; for example, scattering particles can cause light to be scattered through the optics.

It is now an object of the present invention to provide a manufacturing method for a luminaire element with an optical part, by means of which a defined and targeted provision of light-influencing materials - such as color conversion substances - is made possible in a simple manner in the optical body of the optical part; as well as a correspondingly manufactured lamp element itself and a lamp equipped with it, which are equipped in a simple manner with correspondingly defined properties.

According to a first aspect, the present invention therefore relates to a 3D printing method for producing a lighting element. The lighting element has at least one optical part for directing light with an optical body made of an optical material. During the 3D printing of the optic body from the optic material, a light-influencing material is also printed in a locally defined manner in order to form at least one locally defined light-influencing area in the printed optic body. This is how the lighting element is made.

By using the 3D printing process to produce a lighting element with an optical part, the present invention makes it possible for the first time to provide light-influencing materials in a targeted manner in the optical body by printing these materials at the same time. It is thus possible to arrange the light-influencing materials in a spatially selective manner in a volume body forming the optic body and thus to form a lighting element. Using the 3D printing process, the light-influencing materials can be introduced at defined positions even with complex optics. This creates luminaire elements or optical systems with integrated light-influencing areas that are locally tailored to the respective application. In this way, luminaire elements with optical parts are created, which, for example, also change the spectrum in a spatially resolved manner or can influence the light in another way with precise location. Depending on the light-influencing material used, the light can, for example, be converted into a desired color in a spatially resolved manner or color errors (e.g. from LEDs or due to chromatic aberration) in the solid can be corrected. Thus, the luminaire element with an optical part or the optical system (e.g. an LED lens) can, in addition to the function of directing light, also fulfill the function of influencing light - such as color correction or adaptation of the light color. Depending on the light-influencing material, the light can of course also be optically influenced in other ways; e.g. be spread. Overall, the method according to the invention thus serves to produce lighting elements with optical parts with a higher quality of light compared to conventionally produced lighting elements with optical parts with a comparable function.

The light-influencing material can also be printed in a locally defined manner in order to form a plurality of locally defined light-influencing areas in the printed optical body. In this respect, as is basically possible in a simple manner with the 3D printing process, the light-influencing materials can be provided at any point and thus any number of light-influencing areas can be formed or provided in the optic body. This leads to a further optimization of the luminaire element or optical part due to the locally defined provision of light-influencing areas.

The light-influencing area (s) can be printed with the same or at least partially with different light-influencing materials or have these. In this way it is made possible depending on an optical part The need to provide appropriately defined light-influencing materials in a locally defined manner and thus further optically optimize the luminaire element or optics overall.

The light-influencing materials can include, for example, light conversion materials, inorganic luminescent materials, organic luminescent materials, quantum dots (“quantum dot” hereinafter also referred to as “quantum dot” or “QD”), and / or light scattering materials. With the first four mentioned, a specific light conversion can be generated to generate light of a different color, for example to effect color corrections or the adaptation of the light color in a targeted manner. The wavelength of the light or its spectrum can thus also be changed or shifted; this with a constant or changing color range. With light scattering materials, it is possible to achieve a defined light scattering at defined locations or areas of the optical part in order to further improve the optical function of the luminaire element or its optical part.

The at least one light-influencing area can be printed with a defined layer thickness and / or a defined shape. The at least one light-influencing area can also be printed in one or more layers. The light-influencing areas can thus be provided in a defined manner not only with regard to their position, but in particular also with regard to their shape and layer thickness and layer structure or layer composition, and thus the luminaire element or optical system can be further optimized overall.

The at least one light-influencing area can be formed in the optic body in such a way that when the luminaire element or its optical part is used with a lighting means for the defined guiding of light from the lighting means through the optical part or its optic body, it effects a (defined) influencing of the light. For example, this preferably defined light influencing can be or cause a wavelength change, a wavelength shift, a spectrum change, and / or a spectrum shift of the light; this with or without changing a color range. The preferably defined light influencing can also be or cause a color change of the light. The light influencing can preferably be a local influencing of the light, which can be implemented in a locally defined manner due to the locally defined provision of the light influencing areas.

The optical body can be printed in such a way that the optical part has at least one defined optical region. The defined optical area can be, for example, defined optical structures and / or contours and / or cavities. In this respect, the optic body can be designed as complex as desired. This is a particularly big advantage of a 3D printing process. The defined optical area can preferably be provided in such a way that when the lighting element or optical part is used with a lighting means for defined guiding light of the lighting means through and / or out of the optic body, it optically interacts with the at least one light-influencing area. In this respect, the optical areas and the light-influencing area (s) can be provided locally and thus also optically defined in order to provide the luminaire element or the optical part and its light-influencing function in a targeted and precise manner.

The optical part can be a lens which has a lens body as the optic body. In principle, all possible types of optical parts are conceivable. In particular, a lens as an optical system is particularly preferred because it represents a preferred element for directing light.

The optical material can be an optical plastic or glass or another optical material. The invention is not restricted to this, provided that the materials can be used by means of 3D printing processes.

The luminaire element can furthermore have a luminaire body or also other structural or optical elements / components of a luminaire. The lamp body or any other elements / components can be printed together with the optical part or the optical body. The material of the luminaire body or the other elements / components can be selected as desired and according to their intended use, provided they can be used in the 3D printing process. This means that there are no limits to the design and functions of the luminaire element.

The so-called drop-on-demand (DoD) process, for example, can be used as a 3D printing process. Here it is preferably conceivable that a separate material nozzle is provided for each material, so that the optical material on the one hand and each light-influencing material on the other hand (and possibly material for the luminaire body and any other elements / components) are each provided by their own material nozzle - preferably dispersed in a matrix - can be applied locally. In this way, luminaire elements or optical systems with integrated light conversion substances that are locally matched to the respective application are created in a particularly simple manner. Of course, others are also known or new in the future resulting 3D printing processes are conceivable and included in the invention as possible 3D printing processes.

According to a further aspect, the present invention also relates to a lighting element which has been produced using a 3D printing method according to the present invention. The luminaire element produced in this way has an optical part with an optic body made of an optic material, with at least one locally defined light influencing area being provided in the optic body. The advantages of such a lighting element or optical part have already been described in detail above and apply in the same way at this point.

Several locally defined light-influencing areas can be provided in the optic body. The light-influencing area or areas can have the same or at least partially different light-influencing materials. The light-influencing materials can have light conversion materials, inorganic phosphors, organic phosphors, quantum dots (QDs), and / or light scattering materials. The at least one light-influencing area can have a defined layer thickness and / or a defined shape. The at least one light-influencing area can be printed or constructed in one or more layers. The at least one light-influencing area can be formed in the optical element in such a way that, when the lighting element or the optical part with a lighting means is used, it effects an influence on the light for the defined guidance of light from the lighting means through the optical body; preferably causes a locally defined light influencing. The light influencing can be a wavelength change, a wavelength shift, a spectrum change, and / or a spectrum shift of the light; this preferably with or without a change in a color range of the light. The influence of light can also be a change in the color of the light. The optical part can have at least one defined optical area, such as defined optical structures and / or contours and / or cavities, the defined optical area preferably being provided in such a way that, when the lighting element or its optical part is used, it can be connected to a light source Defined guiding light of the illuminant through and / or out of the optic body interacts optically with the at least one light-influencing area. The optical part can be a lens which has a lens body as the optic body. The optical material can be an optical plastic or glass or any other optical material suitable for use in a 3D printing process. The luminaire element can furthermore have a luminaire body which is printed together with the optical part and is preferably formed integrally therewith.

The advantages of the above-described features of the luminaire element with optical part have already been described in detail in the explanations of the first aspect of the present invention with regard to the 3D printing process and apply in the same way to the luminaire element or its optical part itself, so that a corresponding repetition is dispensed with here and reference is made to the previous statements.

According to a third aspect, the present invention further relates to a lamp (for example a spot lamp or a spot lamp) having a lamp element according to the present invention and a lamp for emitting light. To direct the light, the light is at least partially guided through the optical part, at least part of the light guided through the optical part optically interacting with the at least one light-influencing area. In other words, the illuminant emits light into the optical part (e.g. in a preferably defined light coupling area of the optic body) of the lighting element, which is guided accordingly due to the structure of the optic body, while at the same time it continues to have an optical effect when it hits correspondingly locally defined light influencing areas, so that the optical function of the lamp element or the optical system or the optical part is further optimized before the light leaves the lamp element or the optical part or the optical body; preferably defined via the optical structures.

The illuminant preferably has an LED illuminant, a conventional illuminant such as an incandescent lamp or halogen lamp, and / or a laser. All common LED types are conceivable as LED light sources. For example, the light source can be an LED chip or an LED module of any type. An LED matrix can also serve as a light source. It is also conceivable to provide RGB LEDs or OLEDs as lighting means. The lighting means can be controlled in any way in order to generate different light output characteristics (direction of emission, emission position, light color, luminosity, etc.).

In addition to the lamp element with the optical part and the lamp, the lamp according to the invention can also have all conceivable further features of a lamp, such as electronics (e.g. driver electronics), a lamp body e.g. having a housing, cabling, sensors, control units, a cover, seals , etc. The lighting element can, for example, in a separately provided luminaire body can be used or connected to it. However, the luminaire body can also at least partially be printed as part of the luminaire element in the 3D printing process and thus preferably be formed integrally with the optical part. The luminaire element can therefore preferably have the luminaire body (at least partially). The separately provided or integrally formed lamp body can preferably carry or receive the lamp.

• 1 eine schematische Darstellung einer erfindungsgemäßen Leuchte mit einem erfindungsgemäßen Leuchtenelement hergestellt nach einem erfindungsgemäßen Verfahren gemäß einem ersten Ausführungsbeispiel der Erfindung, und
• 2 eine schematische Darstellung einer erfindungsgemäßen Leuchte mit einem erfindungsgemäßen Leuchtenelement hergestellt nach einem erfindungsgemäßen Verfahren gemäß einem zweiten Ausführungsbeispiel der Erfindung.

Further embodiments and advantages of the present invention are described below with reference to the figures of the accompanying drawings. Show it:

• 1 a schematic representation of a lamp according to the invention with a lamp element according to the invention produced by a method according to the invention according to a first embodiment of the invention, and
• 2 a schematic representation of a lamp according to the invention with a lamp element according to the invention produced by a method according to the invention according to a second embodiment of the invention.

The 1 and 2 each show exemplary embodiments of a lamp according to the invention 10 with a lighting element according to the invention 9 , which is produced according to the 3D printing process according to the invention.

The luminaire element 9 shows an optical part here 1 with an optic body 2 made of an optical material. The optical material can preferably be an optical plastic or glass. Other optical materials are also conceivable, which can in particular be printed in a 3D printing process.

The optical part 1 a lens is preferred, as shown. In this case, the optic body forms 2 the lens body. The optic body 2 or the lens body are generally designed as a volume body. As can be seen from the figures, is in the optic body 2 at least one locally defined light influencing area 3 intended. As can be seen from the exemplary embodiments in the figures, a plurality of locally defined light-influencing areas can preferably be used 3 be provided. In the exemplary embodiments shown, there are a total of twenty-five locally defined light-influencing areas 3 intended. The areas of influence of light 3 can do the same or, as in the 1 and 2 shown, have at least partially different light-influencing materials. Partly means here in particular that a part or a group of the light-influencing areas 3 are made from a first light-influencing material, a second part or a second group of the light-influencing areas 3 are made of a second (different) light influencing material and so on. In the present exemplary embodiments, the optic body 2 two groups of light-influencing areas 3 which appear as black circles (group 1 ; here eighteen light-influencing areas 3 ) and white circles (group 2 ; here seven areas of light influencing 3 ) are shown as examples. The number of groups as well as the light influencing areas having them 3 is of course not limited by the invention. By providing or providing different parts or groups of light-influencing areas 3 can change the areas of influence of light 3 not only be provided locally defined. It is also possible, also by using different light-influencing materials, to use the corresponding locally defined light-influencing areas 3 to be designed and arranged according to the desired light influencing function. It can thus be made possible, for example, in an optical solid 2 which fulfills an optical function of precisely positioning light-influencing materials, such as conversion substances, in different types and / or concentrations (i.e. a defined spatial arrangement in the solid) in order, for example, to modify the light spectra in a location-dependent manner or to scatter or scatter light in a locally defined manner other way of influencing defined.

The light-influencing materials can include, for example, light conversion materials, inorganic phosphors, organic phosphors, and / or quantum dots (QDs), for example to convert the light into a desired color in a locally defined manner or, for example, to color errors (for example from LEDs or chromatic aberration) correct in the solid. Alternatively or additionally, it is conceivable that the light-influencing materials have light-scattering materials. In this way it is also possible to have locally defined light in the optic body 2 to sprinkle.

The at least one light influencing area 3 can have a defined layer thickness and / or a defined shape. A circular or spherical shape is shown here purely by way of example; in principle, any shape and layer thickness possible with a 3D printing process is conceivable. In this way, the light-influencing area can not only be provided in a locally defined manner, but can also be optimally designed in terms of its shape and layer thickness at the defined position. In addition, the at least one light-influencing area can 3 printed in one or more layers or be constructed. In particular with a multilayer structure, the light-influencing area can 3 in any way and possibly also with different materials or material combinations in layers (for example according to the layer structure given by the 3D printing process) in order to enable an optimal influence of light.

The at least one light influencing area 3 can in such a way in the optic body 2 be formed that he when using the lighting element 9 or its optical part 1 with a lamp 7th for defining the guidance of light from the illuminant 7th through the optic body 2 causes a preferably defined influencing of the light. This can preferably be a locally defined influence of light. The light influencing can be a wavelength change, a wavelength shift, a spectrum change, and / or a spectrum shift of the light, this preferably with or without a change in a color range of the light. The influence of light can also be a change in the color of the light. The light influencing can thus in particular through the locally defined and preferably also different light influencing materials and thus light influencing areas 3 be achieved.

The optical part 1 can furthermore have at least one defined optical area 4th , 5 , 6th exhibit. In these optical areas 4th , 5 , 6th it can in particular be defined optical structures and / or contours and / or cavities. The defined optical area 4th , 5 , 6th can preferably be provided in such a way that when using the lamp element 9 or its optical part 1 with a lamp 7th for the defined guidance of light from the lamp 7th through and / or out of the optic body 2 with the least one light-influencing area 3 cooperates optically. In the present exemplary embodiments, the light from the illuminant is 7th here by a light entry area 4th into the optics 1 can be introduced via side panels 5 of the optical part 1 for example, are totally reflected here in order to ultimately have a light exit area 6th of the optical part 1 to be delivered in a targeted manner. On its way through optics 1 the light is here due to the optimized optical part 1 to enable both a defined light guidance and the locally defined positioned light influencing areas 3 optically optimized influenced and guided; consequently, light guidance and light influencing are optimally coordinated or can be coordinated with one another.

As can be seen from the figures, a lamp body can also be used 8th be provided. As in 1 shown as a separate part of the lamp 10 to be provided. The luminaire element 9 which according to 1 only the optical part 1 has, can then for example with the lamp body 8th be rigidly connected or movably coupled to this and thus carried or received by this. It is also conceivable that the lamp body 8th is also printed by means of a 3D printing process. The lamp body 8th can then preferably together with the optical part 1 to be printed; these components are then preferably integral with one another as the lighting element 9 trained as it is in 2 is shown by way of example.

The combination of the luminaire element 9 according to the present invention and a lighting means 7th for emitting light forms a luminaire according to the invention 10 . The light of the lamp 7th is used to direct the light at least partially through the optical part 1 guided, at least part of the through the optical part 1 guided light with the at least one light influencing area 3 cooperates optically. The light source 7th can preferably have an LED illuminant and / or a laser and / or another illuminant of any kind; an LED module is shown here as an example.

The luminaire element 9 can, as described and in 2 shown the lamp body 8th have, which then preferably the illuminant 7th carries or receives. As described and in 1 shown, a separate lamp body 8th be provided, which preferably the lighting element 9 (here only the optical part 1 having) as well as the illuminant 7th carries or receives. The lamp body 8th can also carry or accommodate other luminaire components. So can, in addition to the luminaire element 9 with optical part 1 and the lamp 7th the lamp according to the invention 10 furthermore have all conceivable further elements / components of a lamp, such as electronics (e.g. driver electronics), cabling, sensors, control units, a cover, reflectors, seals, etc. of the luminaire element 9 trained) lamp body 8th be worn or picked up.

A 3D printing method according to the invention for producing a lighting element is described below 9 having at least one optical part 1 for directing light with an optic body 2 described from an optical material. During the 3D printing of the luminaire element 9 or the optic body 2 the light-influencing material is also printed in a locally defined manner from the optical material in order to be included in the printed optical body 2 at least one locally defined light influencing area 3 to form. The light-influencing material is preferably also printed in a locally defined manner in such a way that it is in the printed optical body 2 several locally defined light influencing areas 3 to form like this the optical parts 1 according to the 1 and 2 can be seen (shown here as an example as white and black circles).

The light-influencing area or areas 3 can preferably be printed with the same or, as shown, at least partially with different light-influencing materials or have these.

As already described, the light-influencing materials can have, for example, light conversion materials, inorganic phosphors, organic phosphors, quantum dots (QDs) and / or light scattering materials.

The at least one or all light-influencing areas 3 can be printed with a defined layer thickness and / or a defined shape. The at least one light influencing area 3 can also be printed in one or more layers. All of this is made possible by the 3D printing process, which can usually generate a particularly defined material structure through layer-by-layer construction with point-by-point or layer-by-layer or surface application of material, whereby this can be implemented with high accuracy even with the most complex structures.

The at least one light influencing area 3 can in such a way in the optic body 2 be formed that he when using the lighting element 9 or its optical part 1 with a lamp 7th for the defined guidance of light from the lamp 7th through the optic body 2 brings about a preferably defined influencing of light and preferably a locally defined influencing of the light. The light influencing can be or cause a wavelength change, a wavelength shift, a spectrum change, and / or a spectrum shift of the light, preferably with or without a change in a color range of the light. The influence of light can also be or cause a change in the color of the light.

The optic body 2 can also preferably be printed in such a way that the optical part 1 at least one defined optical area 4th , 5 , 6th , such as defined optical structures and / or contours and / or cavities, wherein the defined optical area 4th , 5 , 6th is preferably provided in such a way that when using the lamp element 9 or its optical part 1 with a lamp 7th for the defined guidance of light from the lamp 7th through and / or out of the optic body 2 with the at least one light-influencing area 3 cooperates optically.

The optical part 1 can be a lens or be designed as a lens, which has a lens body as an optic body 2 having.

The optical material can be an optical plastic or glass or another optical material which is particularly suitable for use in a 3D printing process.

The luminaire element 9 can also use the lamp body 8th have, which preferably together with the optical part 1 or the optic body 2 is printed. These components of the lighting element 9 are then preferably formed integrally with one another. Also other elements / components of the luminaire 10 can be printed with a 3D printing process and preferably also an integral part of the luminaire element 9 form.

The so-called drop-on-demand (DoD) process, for example, can be used as the 3D printing process. For this purpose, it is preferred that a separate material nozzle is provided for each material, that is to say for each optical material and for each light-influencing material (and possibly for each lamp body material). By means of the respective material nozzles, the respective materials are applied in a locally defined manner, so that a defined structure of the optic body 2 (and if necessary the lamp body 8th ) is made possible while at the same time in the optical part 1 locally defined and adapted to the respective application, integrated light-influencing materials are provided or introduced and thus the locally defined light-influencing areas 3 can be formed. This can of course also be achieved with any other 3D printing method, so that the invention is not limited to any specific 3D printing method.

The present invention is not restricted to the exemplary embodiments described above, provided that it is covered by the subject matter of the following claims. In particular, every known 3D printing process is used to manufacture a lighting element 9 having at least one optical part 1 for directing light with an optic body 2 from an optical material conceivable. As an optical part 1 any possible optical part for guiding light is conceivable, such as, in particular, lenses and other optical elements. The optic body 2 is designed in particular as a volume body, which can have simple (for example symmetrical or rotationally symmetrical) shapes or any complex structures or shapes, as is the case, for example, with Fresnel lenses. The design of the optic body 2 is not limited by the present invention, and it can take any form as previously described. The luminaire element 9 only the optical part can do it 1 include, or have other components (integral), such as the lamp body 8th and other structural or optical (lighting) components. All conceivable optical materials that can basically be used in a 3D printing process can be used as optical materials. The same applies to the materials of other components, which also - preferably as part of the lighting element 9 - be printed at the same time. Any light influencing material that is suitable for influencing light and can also be used in a 3D printing process is also conceivable. The number, shape, concentration, layer thickness and the like of the light-influencing areas 3 is not limited by the present invention. The same applies to the number of different materials to be used, and here both the optical material and, in particular, the light-influencing material and also materials of further components, in particular of the luminaire element 9 , not limited by the invention. Likewise, depending on the material, the same or different material nozzles can be used for the 3D printing, as well as it is preferred for the 3D printing process depending on the desired specification. With a view to the luminaire according to the invention, the present invention is also not limited to a specific lighting means or a specific type of lighting means. So can be used as a light source 7th every conceivable light source can of course be used. LEDs and lasers are particularly preferred here, since the use of light influencing materials and preferably light conversion materials (phosphors) is particularly preferred for them and here in particular a defined light influencing such as a wavelength change, a wavelength shift, a spectrum change, a spectrum shift, a color change and / or a light scattering of the light for targeted light emission and also for the correction of undesired color deviations find an effective application. The features of the exemplary embodiments can be combined with one another in any desired manner and interchanged with one another.

Claims (29)

3D printing method for the production of a lighting element (9) having at least one optical part (1) for directing light with an optical body (2) made of an optical material, wherein during the 3D printing of the optical body (2) made of the optical material, a light influencing material is also locally defined is also printed in order to form at least one locally defined light-influencing area (3) in the printed optic body (2). 3D printing process according to Claim 1 wherein the light-influencing material is also printed in a locally defined manner in order to form a plurality of locally defined light-influencing areas (3) in the printed optical body (2). 3-D printing method according to one of the preceding claims, wherein the light-influencing area or areas (3) are printed with the same or at least partially with different light-influencing materials or have these. 3-D printing method according to one of the preceding claims, wherein the light-influencing materials comprise light-conversion material materials, inorganic luminescent materials, organic luminescent materials, quantum dots, and / or light-scattering materials. 3-D printing method according to one of the preceding claims, wherein the at least one light-influencing area (3) is printed with a defined layer thickness and / or a defined shape. 3-D printing method according to one of the preceding claims, wherein the at least one light-influencing area (3) is printed in one or more layers. 3-D printing method according to one of the preceding claims, wherein the at least one light-influencing area (3) is formed in the optic body (2) in such a way that when the optical part (1) is used with a lamp (7) for the defined guidance of light from the lamp (7) brings about a defined influence of light, preferably a locally defined influence of light, through the optic body (2). 3-D printing method according to one of the preceding claims, wherein the light influencing is a wavelength change, a wavelength shift, a spectrum change, and / or a spectrum shift of the light, this preferably with or without a change in a color range of the light, and / or wherein the light influencing a color change of the Is light. 3-D printing method according to one of the preceding claims, wherein the optical body (2) is printed in such a way that the optical part (1) has at least one defined optical area (4, 5, 6), such as defined optical structures and / or contours and / or Cavities, wherein the defined optical area (4, 5, 6) is preferably provided in such a way that when the optical part (1) is used with a lighting means (7) for the defined guiding of light from the lighting means (7) through the and / or from the optic body (2) interacts optically with the at least one light-influencing area (3). 3-D printing method according to one of the preceding claims, wherein the optical part (1) is a lens which has a lens body as the optical body (2). 3-D printing method according to one of the preceding claims, wherein the optical material is an optical plastic or glass. 3-D printing method according to one of the preceding claims, wherein the light element (9) further comprises a light body (8) which is printed together with the optical part (1) or the optical body (2). 3-D printing method according to one of the preceding claims, a drop-on-demand (DoD) method being used as the 3-D printing method, a separate material nozzle preferably being used for each material for locally defined printing or application of the respective material. Luminaire element (9) produced by a 3D printing process according to one of the Claims 1 to 13th , comprising an optical part (1) with an optic body (2) made of an optic material, at least one locally defined light influencing area (3) being provided in the optic body (2). Light element (9) after Claim 14 , wherein a plurality of locally defined light influencing areas (3) are provided in the optic body (2). Light element (9) after Claim 14 or 15th wherein the light-influencing area or areas (3) have the same or at least partially different light-influencing materials. Lighting element (9) according to one of the Claims 14 to 16 , wherein the light-influencing materials have light conversion materials, inorganic luminescent materials, organic luminescent materials, quantum dots, and / or light scattering materials. Lighting element (9) according to one of the Claims 14 to 17th , wherein the at least one light-influencing area (3) has a defined layer thickness and / or a defined shape. Lighting element (9) according to one of the Claims 14 to 18th , wherein the at least one light-influencing area (3) is constructed in one or more layers. Lighting element (9) according to one of the Claims 14 to 19th , wherein the at least one light-influencing area (3) is formed in the optic body (2) in such a way that, when the optical part (1) is used with a lighting means (7) for the defined guiding of light from the lighting means (7) through the optic body (2 ) causes a defined influence of light, preferably a locally defined influence of light. Lighting element (9) according to one of the Claims 14 to 20th , wherein the light influencing is a wavelength change, a wavelength shift, a spectrum change, and / or a spectrum shift of the light, this preferably with or without a change in a color range of the light, and / or wherein the light influencing is a color change of the light. Lighting element (9) according to one of the Claims 14 to 21 , wherein the optical part (1) has at least one defined optical area (4, 5, 6), such as defined optical structures and / or contours and / or cavities, the defined optical areas (4, 5, 6) preferably such it is provided that when the optical part (1) is used with a lamp (7) for the defined guiding of light from the lamp (7) through and / or out of the optic body (2) it interacts optically with the at least one light-influencing area (3) . Lighting element (9) according to one of the Claims 14 to 22nd , wherein the optical part (1) is a lens which has a lens body as an optical body (2). Lighting element (9) according to one of the Claims 14 to 23 , wherein the optical material is an optical plastic or glass. Lighting element (9) according to one of the Claims 14 to 24 , wherein the lamp element (9) further comprises a lamp body (8) which is printed together with the optical part (1) and is preferably formed integrally therewith. Light (10) having a light element (9) according to one of the Claims 14 to 25th as well as a light source (7) for emitting light, which is guided at least partially through the optical part (1) to direct the light, at least part of the light guided through the optical part (1) being optical with the at least one light-influencing area (3) cooperates. Lamp (10) Claim 26 , wherein the illuminant (7) comprises an LED illuminant and / or a laser. Lamp (10) Claim 26 or 27 , wherein the lamp (10) has a lamp body (8) which preferably carries or receives the lamp (7), Lamp (10) Claim 28 wherein the luminaire body (8) is provided separately and furthermore receives or carries the luminaire element (9), or wherein the luminaire element (9) has the luminaire body (8) which is printed together with the optical part (1) and preferably integrally therewith is trained.

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