TW200842279A - Modular lighting device and lighting arrangement - Google Patents

Abstract

A modular lighting system with at least one light-source module and at least one of the following modules is disclosed: optic module, power module, control module and/or cooling module, where the modules form at least sectionally a common outer-periphery surface or are exchangeably inserted into a common housing. In addition, a lighting arrangement of such lighting systems is also disclosed.

Description

200842279 IX. INSTRUCTIONS: " TECHNICAL FIELD OF THE INVENTION The present invention relates to a modular illumination system and an illumination configuration of the illumination system. The lighting system has at least one light source module and at least one of the following modules: an optical module, a power module, a control module, and/or a cooling module. [Prior Art] The illumination system is known, for example, from the applicant's D E 2 0 3 1 5 2 3 4 U 1 . In such a conventional illumination system, a plurality of light sources on a circuit board are used in the light-emitting housing, which are formed by light-emitting diodes (LEDs). The 发光 light emitting diode arrangement is covered by a cover made of a light transmissive material. The cover body is set on the circuit board when the illuminator is mounted and is fixed in the outer casing by the splint. The current supply to the illumination system is achieved via a plug assembly that is coupled to the electronic ballast via a wire and a contact plug that can extend in the header assembly. A disadvantage of such a lighting system is that the light source, the cover and the electronic ballast are fixedly mounted in the housing, so that the conventional illumination system can only be adjusted to a limited extent depending on the purpose of the illumination. In addition, such illumination systems are only suitable for specific light sources of the same shape, for example, light sources in the LED light band. SUMMARY OF THE INVENTION It is an object of the present invention to provide an illumination system and illumination arrangement that can be modularized to achieve a variable illumination relative to conventional solutions. The above object is achieved by a modular lighting system having one light source module and at least one of the following modules: 200842279: optical module, power module, control module and/or cooling module Each of the modules forms a common outer peripheral surface at least in sections or is replaceably inserted into a common outer casing. The above objects are also achieved by the illumination configuration of the illumination system. Particularly advantageous forms of the invention are described in the respective scope of the patent application. In the solution of the invention, the modules are arranged in a replaceable manner with respect to the prior art of DE 203 1 5 234 U1, The modules form a common outer peripheral surface at least in sections. Therefore, this lighting system achieves the tightest shape and high power density. In another form of the invention, the modules are replaceably inserted into a common housing. Each module has a number of different forms, so that the lighting system with the most different characteristics can be made by combining and changing. Since the modules are configured to be replaceable, the lighting system can be adjusted according to different lighting purposes by module replacement or position change. The illumination system of the present invention is characterized by high optical power and illumination feasibility. Integration and variability. According to a particularly advantageous embodiment of the invention, the modules are arranged coaxially and such that the sides of adjacent modules extend substantially aligned with one another. Preferably, the modules are detachably connected to one another in a positive locking and/or a negative locking manner. Preferably, each module is complementary to an object that is approximately cubic- or rectangular hexahedron. In another form, the modules are arranged substantially on a common plane. The image of the lighting system can be determined by the modular configuration of the modules (e.g., 'coaxial, planar or spatially separated'), so that the illumination system of the present invention is sufficient to meet the highest aesthetic requirements. According to a particularly advantageous embodiment of the invention, each module has a rectangular base body having the same mounting dimensions. Since the mounting dimensions are the same, the modules can be easily and variably configured, so that the lighting feasibility can be greatly changed by the combination of the standardized units. In another form of the invention, each module has a substantially circular' base having the same mounting dimensions. Thus, this illumination system can be used particularly advantageously to replace conventional lamps, such as the scent reflector lamps of the model HALOSPOT®. It is particularly advantageous when at least one of the front and/or rear walls of the module is provided with a plurality of contact elements that are coupled to contact elements of adjacent modules to transmit power and/or transmit signals. Therefore, the modules can be in contact with each other without additional wires between the modules to transmit power and signals. In a preferred form, the light source module has at least one internal region to accommodate at least one light source. Preferably, the light source module is provided with different light sources to enable the illumination system to achieve as many different illumination effects as possible, such as light color, hue or light dynamics, by replacement of the light source module. In accordance with the present invention, it is particularly advantageous when at least one light emitting diode, such as an OSTAR® or DRAGON® light emitting diode configuration (LED-array), is used as the light source. In particular, RGB-LEDs can be used, whereby colors such as red, green, and blue can be emitted and various specific light colors can be adjusted by control. For example, the optical module can be provided with three 0STAR® light emitting diode configurations that are applied to the inner face of the light module in a triangular fashion. The number and configuration of LEDs can be changed (for example, 1x1, 3x1; 2x2, 4x1, etc.) to form various light source modules with different optical power and optical image, which can be inserted into the lighting system due to the modular shape. 200842279 Tongzhong. In order to eliminate the waste heat generated, in particular the waste heat of the power component % of the light-emitting diode, the modules of the embodiment of the invention shall be constructed with at least one cooling surface provided with cooling ribs. It is particularly advantageous when the power module is provided with cooling ribs on the outer circumference. According to a particularly advantageous embodiment of the invention, the optical module has at least one aperture and a cover for beaming (emission angle, form), steering, homogenizing and mixing the colors. The aperture is preferably constructed of a light transmissive material and has a recess associated with the light source to cover the inner region of the light source module and only the light transmissive surface remains empty. In the form of the invention, the cover has at least one lens associated with the light source, in particular a Fresnel lens (step lens) to steer the light from the source. By using a Fresnel lens, the height and weight of the cover can be much reduced compared to conventional lens systems. The optical module can form a support with a replaceable lens or can also form a complete sputter cast. According to an advantageous embodiment of the invention, the power module has at least one electric operating device, in particular an OPTOTRONIC® operating device for the light-emitting diode. Due to the modular system configuration, a power module that is adjusted based on the set optical power and cooling power can be used and can be replaced when the configuration of the module changes. In order to discharge waste heat, the lighting system is preferably provided with at least one cooling module. The cooling module has an active or passive cooling element or a combination of these two components to cool the light source and power module. Heat is discharged to the environment, for example by free convection (passive cooling elements such as heat sinks, heat pipes, etc.) 200842279 or forced convection (active cooling elements, eg ventilators, Peltier 'components, evaporative Cooler, etc.) to achieve. The modular lighting system can achieve a variety of variable cooling body serial connections, so that a plurality of cooling elements can be connected in series, each cooling element can be provided with a passive cooling body, and the cooling body has an active ventilation fan. Control of the illumination system is preferably achieved by at least one control device disposed in the control module. For example, a digital control device based on the DMX- or DALI-standard can be used. This control device is used, for example, to control the color, light mixing and brightness (dimming) of the LEDs. In addition, the control device can measure and calculate the thermal characteristics of the illumination system and control the active cooling module (heat treatment) by at least one sensor. Control of the control module is preferably accomplished by at least one optical signal receiver that can be controlled by means of a data line or a radio connection. In an illumination system constructed by a oscillating radiator, two mutually facing side walls of a module (for example, a light module) are respectively provided with receiving ports for the end sections of the support, and the end regions The segments form a swing axis. According to another embodiment of the illumination system having a gimbal suspension, at least one module is slidably disposed in the frame member and slidably received in a support frame to illuminate the module The system can be swung by a universal joint after it has been attached to the cover, bottom, wall or furniture, for example. In another form of the illumination system of the present invention, at least one module is slidably disposed in a frame rotatably secured to a track movably disposed on a track via a support bar On the runner. The lighting arrangement for forming planar illumination in the present invention uses a plurality of illumination systems of the above-described form -9-200842279. In a preferred embodiment, the illumination arrangement has two or more illumination systems that are disposed adjacently and/or overlappingly and that form a common illumination surface at least in sections. The invention will be described in detail below based on the examples. [Embodiment] FIG. 1 is a diagram showing a modular illumination system 1 according to a first embodiment of the present invention, comprising: a light source module 2, an optical module 4, a power module 6, a control module _ group 8 and a cooling module. 1 0. In the present invention, each of the modules 2, 4, 6, 8, 10 forms a common outer peripheral surface 12 at least in sections or is replaceably inserted into a common outer casing 14 (see Fig. 15). In this embodiment, each module 2, 4, 6, 8, 1 须 is formed so that each module forms a common outer peripheral surface 1 2 because each module 2, 4, 6, 8, 10 is configured to be replaceable. The illumination system 1 can be adjusted according to different illumination or illumination purposes by replacement or positional change of the modules 2, 4, 6, 8, 10, and the illumination system of the invention is characterized by high optical power, Lighting can be integrated and variability. The modules 2, 4, 6, 8, 10 are arranged in a coaxial manner, wherein the optical module 4 is disposed on the light source module 2 with the front surface. The cooling module 10 is connected to the light source module 2 with the back side, and the power module 6 is disposed after the cooling module 10. The lighting system 1 is terminated by a control module 8 set on the power module 6 on the back side. Each of the modules 2, 4, 6, 8, 10 has a substantially circular or rectangular base body 16 having substantially the same mounting dimensions and being locked or negatively locked by an undisplayed buckle. Removably interconnected by bolting or bolting, each module 2, 4, 6, -10- 200842279 8, 10 can be complemented into an object 18 in the form of a cube or a rectangular parallelepiped. Each module 2, 4, 6, 8, 10 is formed such that adjacent sides 2, 4, 6, 8, and 1 sides of the module 20 extend substantially in unison and form a common outer perimeter 1 2, in order to achieve the closest lighting system 1 with the best optical power. Since the mounting dimensions are the same, the modules 2, 4, 6, 8, 10 can be easily replaced and variably arranged to be combined by different modules 2, 4, 6, 8, 10 that have been standardized. Great changes have been made to the feasibility and characteristics of lighting. Other details of each module 2, 4, 6, 8, 10 will be described below in accordance with FIG. ® Fig. 2 is an exploded perspective view of the illumination system 1 of Fig. 1. As can be seen from Fig. 2, the light source module 2 has an inner region 22 for accommodating at least one light source 24. In this embodiment, three types of OSTAR® light-emitting diodes 24 are used as light sources, which are respectively composed of hexagonal metal core circuit boards 26, and each circuit board 26 carries four disposed on the circuit board 26. Light-emitting semiconductor wafer 30 at the center of front side 28. The hexagonal metal core circuit board 26 can achieve a sufficiently large contact surface for thermal coupling to the base 16 of the light source module 2 and allows the light-emitting diodes 24 of each OSTAR® to be most closely disposed on the electrical® road. On board 26. The light-emitting diodes 24 of FIG. 2 are inserted into the corresponding receiving openings 32 of the inner region 22 of the light source module 2 in a triangular shape so that the front surface 28 of the circuit board 26 can be inside the light source module 2 Face 34 extends flush with each other. In particular, RGB-LED 24 can be used whereby red, green and blue light can be emitted and can be controlled to adjust a particular color of light. The number and arrangement of the LEDs 24 are variable and are not limited to the illustrated 3x1 matrix. The light source module 2 can thus form different optical powers and optical images, and can be inserted into the illumination system due to the modular shape. 1 in. The light source module 2 preferably has different light source configurations and powers for the -11-200842279, so that the lighting system 1 can achieve as many different light effects as possible by replacing the light source module, for example: light color, color ^ Tuning or light dynamics. In this embodiment, the optical module 4 disposed on the front side of the light source module 2 has an aperture 36 and a cover 38 for collecting light (emission angle, shape), turning, homogenizing, and achieving color mixing. The aperture 36 is formed of a light transmissive material and has a recess 40 associated with the light emitting diode 24 of the light source module 2. The recess 40 has a circular cross section and the diameter of the recess must be selected to cover this • The inner region 22 of the light source module 2 and only the light transmissive surface of the semiconductor wafer 30 remains empty. In the present embodiment, the cover 38 is constructed in a transparent manner in which a Fresnel lens 42 associated with the light source 24 is disposed to divert the light emitted by the LED 24 onto the outer surface 44 of the cover 38. With the use of the Fresnel lens 42, the height and weight of the cover 38 can be much lower than that of a conventional lens. The optical module 4 can constitute a support with a replaceable lens or form a complete sputter cast. In order to discharge the waste heat of the lighting module 1 (especially the power component of the light-emitting diode 24 and the waste heat of the power module 6), a cooling module 1 is disposed between the light source module 2 and the power module 6. 0, which has an active or passive cooling element for cooling the light source 24 and the power module 6, or a combination of these two elements (not shown). Exhausting heat to the environment can be achieved, for example, by free convection (e.g., by a heat sink) or forced convection (e.g., by a ventilator, a Peltier element, an evaporative cooler, or the like). Three recesses 48 are formed in the two facing side walls 46 of the cooling module 10, for example, forming a receiving opening for a piece or as a terminal for an active cooling element ^ -12- 200842279 at power At least one electronic operating device, not shown, is inserted into the base 16 of the module 6, for example, the operating device of the model OPTOTRONIC® is configured to supply power to the light-emitting diodes 24 of the light source module 2 and can also be cooled if necessary. The active cooling element of module 10 supplies power. Due to the modular system configuration, a power module 6 can be used which is adjusted according to the set optical power and cooling power, which can be replaced when the configuration of the modules 2, 8, 10 is changed. In order to further improve the heat-dissipating function, the outer peripheral surface 12 of the power module 6 is provided with an annular cooling rib 50. Control of the illumination system 1 is achieved by at least one control device (not shown) disposed in the control module 8. For example, a digital control device based on the DMX or DALI standard can be used. This control means is used, for example, to control the color of light, the degree of light mixing, and the brightness of the light-emitting diode 24. In addition, the control device can measure and calculate the thermal characteristics of the illumination system 1 and control the active cooling module 1 (heat treatment) by at least one sensor (not shown). Control of the control module 8 is preferably accomplished by at least one optical signal receiver that can be controlled by means of a data line or a radio connection. It is particularly advantageous when the rear wall 52 of the light source module 2 and the front wall 54 of the control module 8 and the rear wall 56 and the front wall 58 of the cooling module 10 and the power module 6 are provided with contact elements not shown, each contact element being used for transmitting Power and signal. Therefore, the modules 2, 6, 8, 10 can be in contact with each other, and no additional wires are required between the modules to transmit power or signals, so that a cost-effective compact structure can be achieved. Figure 3 shows a modular illumination system 1 of a second embodiment of the invention. As can be seen from Fig. 3, the illumination system 1 can also have more than three light-emitting diodes -13 - 200842279 24. The difference between this embodiment and the previous embodiment is that the bases 16 of the modules 2, 4, 6, 8, 10 have a large height and width, respectively, and the light source module 2 has seven models configured to be symmetrical. OSTAR® LEDs 24 (see Figure 2). One of the light-emitting diodes 24 is disposed in the center of the light source module 2 and is surrounded by the other six light-emitting diodes 24 in a substantially annular manner. The optical module 4 is on the outer surface 44 of the cover plate 38. There is a Fresnel lens 42 associated with the light-emitting diode 24 to steer the radiation emitted by the light-emitting diode 24. The embodiment shown in FIG. 4 is different from the embodiment of FIG. 1 in that the light source module 2 has four light-emitting diodes 24 of the model OSTAR® which are symmetrically arranged in a 2×2 matrix. The optical module 4 has only one transparent cover 38, the front side of which is connected to the light source module 2 via a fixing member 62 provided in the corner region 60, wherein the outer surface 44 of the cover 38 is disposed A Fresnel lens 42 belonging to the light-emitting diode 24 is provided to steer the beam. Figure 5 shows the illumination configuration 64 of the present invention of the illumination system 1 of Figure 4. In Fig. 5, the illumination arrangement 64 has four illumination systems 1 to form a planar illumination, wherein two illumination systems 1 are arranged adjacently and the other two illumination systems 1 are also arranged adjacently (2x2 matrix). The illumination systems 1 are each formed with a common illumination surface 118. Figure 6 shows another embodiment of the illumination system of the present invention. As can be seen from Fig. 6, the bases 16 of the respective modules 2, 4, 6, 8, and 10 can be configured to have a relatively high width. In the form shown, the light source module 2 is provided with four types of 〇STAr@发-14-200842279 light diodes 24 which are arranged adjacently according to a 4x1 matrix form, wherein the optical module 4 has only one The transparent cover 38 is connected to the light source module 2 via a fixing member 62 disposed in the corner region 60. The outer surface 44 of the cover 38 is disposed with a light-emitting diode. 24 Fresnel lens 42. As can be seen from Fig. 7, the bases 16 of the modules 2, 4, 6, 8, 10 can also be formed by circular cross-sections having the same mounting dimensions. Therefore, the illumination system 1 can be used particularly advantageously to replace conventional lamps, such as the halogen reflector lamp of the model HALO SPOT®. In this embodiment, the light source module 2 is provided with a light-emitting diode 24 of a type 0STAR® disposed at the center, which is bolted to the light source module 2. The optical module 4 disposed before the light source module 2 has a cover 38 and is constructed by a Fresnel lens 42 disposed in the light path of the light-emitting diode 24. On the light source module 2, a power module 6 provided with annular cooling ribs 50 is connected in a coaxial manner to the end section remote from the optical module 4. Figure 8 shows an illumination system 1 formed by an LED lamp in the first embodiment, having a rectangular light source module 2 comprising three LEDs arranged in a triangle m - model 0 STAR® 24, used here An optical module 4 consisting of an aperture 36 extends the front side 66 of the aperture 36 flush with the front side 68 of the base 16 of the light source module 2. The aperture 36 is formed of a light transmissive material and has a recess 40 corresponding to the light emitting diode 24 of the light source module 2. The recess 40 has a circular cross section to cover the light source module 2 and only The light transmissive surface remains in an empty state. Figure 9 shows an illumination system 1 formed by an LED lamp in the second embodiment, which differs from the previous embodiment in that the light source module 2 and the optical: modulo-15- 200842279 group 4 have a substantially circular shape. The cross section is formed to form a cylindrical lamp body 18. Thus, the illumination system 1 can be used particularly advantageously in place of a conventional lamp', e.g., a halogen reflector lamp of the type HAL® SP® T®. Figure 10 shows an illumination system 1 formed by a swingable radiator having a light source module 2 shown in Fig. 2 and an optical module 4, two of which face each other The side walls 70, 72 are each provided with a receiving opening 74 for use by the end portions 78, 80 of the pedestal 82 for forming the oscillating shaft. The holder 82 is formed of a cylindrical, circular material that is to be bent to form a U-shaped support section 84 that is converted into two angled legs 86, 88 with an end section 78, 80 forms the oscillating shaft of the illumination system 1. Figure 11 shows another form of an illumination system 1. In addition to the coaxial arrangement of the modules 2, 4, 6, 8, 10, the modules 2, 4, 6 in Fig. 11 are arranged in a plane in a planar manner. In this embodiment, a light source module 2 provided with the optical module 4 is slidably received in a notch 92 of a frame member 94 around a horizontal axis 90 and can be surrounded by the frame member. The shaft 96 is received in an octagonal support frame 98. The support frame 98 is rotatably fixed to a track runner 102 via a support rod 100 gripped in the center of the support frame 98. The orbiter 1 2 is movably disposed in the axial direction. The track is not shown and can be fixed to the track by a fixing element 104. In the second recess 106 of the octagonal support frame 98, a power module 6 provided with annular cooling ribs 50 is fixed in the radial direction. Figure 12 shows a swingable illumination system 1 of another embodiment. As shown in FIG. 1 2 -16-200842279, the illumination system 1 can be swingably disposed about a horizontal axis 90 thereof in a frame 108, the cross-section of the frame 108 substantially corresponding to the modules 2, 4 The cross section of a radial gap has been reduced. The frame 1 〇 8 is rotatably fixed to a orbiter 102 via a support rod 100 fixed in the center thereof, and the orbiter 102 is movably disposed in an axial direction on an undisplayed track. And being fixed by a fixing component 104, the illumination system 1 can be moved along the track, can be rotated by the support bar 100 and can also be set by the swingable frame 108 to achieve May be different for the purpose of lighting. Figures 13 and 14 show an embodiment of a lighting arrangement 110, respectively, having four illumination systems 1 constructed in a gimbal fashion in accordance with the first embodiment. The illumination system 1 is disposed in a frame 1 1 2 so as to be swingable about its horizontal axis 90 and is slidably received in a notch 1 1 4 of a support frame 1 16 to make the module 2 4 After the support frame 116 is fixed, for example, on a cover, bottom, wall or furniture, the universal joint can be swung. Figure 13 shows a lighting arrangement 110 that is particularly suitable for wall mounting. The support frame 116 in Fig. 13 has a substantially square cross section, wherein the recesses for receiving the frame 1 1 2 are disposed adjacently and overlapping such that the configurable illumination system 1 forms a square Light emitting surface 118. In the embodiment shown in FIG. 14, the support frame 116 is formed in a rectangular shape, and the length thereof is larger than the width. The notches 1 1 4 of the support frame 116 are disposed adjacent to each other, so that the illumination system 1 is formed. A rectangular luminous surface 11 8 . Figures 15 and 16 show a modular illumination system i of another embodiment, wherein each of the modules 2, 4, 10 is coaxially reconfigurably arranged in a housing 14 of a common 17-200842279 . As can be seen from Fig. 16, it shows a modular illumination system 1 of Fig. 15, in which three optical bodies are applied in a triangular manner on the front surface 124 of the light source module 2 provided with cooling ribs 50 on the back side. The type 122 of the STAR® light-emitting diode 24 is a type of cooling module 10 constructed by a shaft fan 128 connected to a light source module 2 having a square cross-section. An optical module 4 constructed of a transparent cover plate 130 is attached to a parallel spacing to the front side 124 of the light source module 2. The cover plate 130 forms a contact protection for the light-emitting diodes 24 and causes the light radiation to achieve a homogenization and removal of the aperture by a stray effect. Each of the modules 2, 4, and 10 is respectively penetrated by a bolt 1 2 0 in the corner region, and each of the modules 2, 4, and 10 is provided with a sleeve 1 3 4 to cover the cover plate 130 and the light source module. The 4 phases are spaced apart and bolted to the back support ring 136. A circular recess 138 is mounted in the support ring 136 to supply cooling air to the area of the ventilator 128. Each of the modules 2, 4, 10 can be inserted into a common outer casing 14 of electrically insulating plastic via a support ring 136 and bolted thereto by means of a bolt wall 142 The side 140 of the support ring 136 is fixed in the outer casing 12. The illumination system 1 is swingably disposed in the frame member 152 by the oscillating member 154, and the oscillating member 154 is grasped in the two mutually facing side walls 144, 146 of the housing 12, and The U-shaped frame member 152 is in the foot members 148, 150. The frame member 152 is rotatably attached to a orbiter 102 or the like via a fixing screw 156. The power supply and control of the modules 2, 10 is achieved by wires 158 which extend through fixing bolts 156 formed by hollow bolts. The illumination system 1 and illumination arrangements 64, 11 0 of the present invention are not limited to the combination of modules 2-4, 200842279, modules 2, 4, 6, 8, 10 as shown. Conversely, each lighting system 1 can have as many different combinations of modules as possible. The illustrated modular form has been exemplified as described herein and is arbitrarily changeable due to the modular nature of the illumination system 1 and illumination arrangement 64, 1 1 of the present invention. An illumination system 1 having at least one light source module 2 and at least one of the following plurality of modules has been disclosed: an optical module 4, a power module 6, a control module 8 and/or a cooling module 1A. Each of the modules 2, 4, 6, 8, 10 forms a common outer peripheral surface 12 at least in sections or is replaceably inserted into a common outer casing 14. Furthermore, the present invention also discloses an illumination arrangement 64, 110 formed by the illumination system described above. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram showing a modular illumination system of a first embodiment of the present invention. Fig. 2 is an exploded perspective view of the illumination system of Fig. 1. Figure 3 is an illustration of a modular illumination system in accordance with a second embodiment of the present invention. Figure 4 has a modular illumination system of a light source module having four LEDs symmetrically arranged in a 2x2 matrix. ® Figure 5 is an illustration of the illumination configuration of the first embodiment of the invention. Figure 6 is an illustration of an illumination system in accordance with another embodiment of the present invention. Figure 7 is an illustration of an illumination system having a circular cross-section of the module. Fig. 8 shows an illumination system formed by an LED lamp in the first embodiment. Fig. 9 is a lighting system formed by an LED lamp in the second embodiment. Figure 10 shows an illumination system formed by a swingable radiator. Figure 11 shows an illustration of a lighting system with modules arranged on a common plane. -19- 200842279 Figure 1 2 shows a swingable illumination system having a light source module and an optical module. Fig. 13 is a swingable illumination system having four illumination systems constructed in a gimbal suspension in accordance with the first embodiment. Fig. 14 is a swingable illumination system having four illumination systems constructed in a gimbal suspension in accordance with a second embodiment. Figure 15 shows an illustration of a lighting system in which the modules are coaxially and interchangeably arranged in a common housing.

Figure 16 is an exploded perspective view of the illumination system of Figure 15. [Main component symbol description] 1 Lighting system 2 Light source module 4 Optical module 6 Power module 8 Control module 10 Cooling module 12 Outer peripheral surface 14 Housing 16 Base 18 Object 20 Side 22 Internal area 2 4 Light source 2 6 Metal core Circuit board -20- 200842279

28 front side 30 semiconductor wafer 32 receiving port 34 inner surface 36 aperture 38 cover plate 40 notch 42 Fresnel lens 44 outer surface 46 side wall 4 8 notch 50 cooling rib 52 rear wall 54 front wall 56 rear wall 58 front wall 60 corner Crotch area 62 Fixing element 64 Lighting configuration 66, 6 8 Front 70, 72 Side wall 74 Receiving port 7, 8, End section 8 2 Support-21 200842279

84 Support section 86, 88 Foot 90 Horizontal axis 92 Notch 94 Frame 96 Local axis 98 Support frame 100 Support bar 102 Orbiter 104 Fixing element 106 Notch 108 Frame 110 Lighting configuration 112 Frame 114 Notch 116 Support frame 118 Light surface 120 bolt 122 lens 124 front 126 cooling rib 128 shaft runner 130 cover 132 bolt 200842279

134 Pitch Sleeve 136 Support Ring 138 Notch 140 Side 142 Bolt 144, 146 Side Wall 148, 150 Foot 152 Frame 154 Swing Element 156 Mounting Bolt 158 Wire

Claims (1)

200842279 X. Patent application scope: 1 · A modular lighting system comprising at least one light source module (2) and at least one of the following plurality of modules: an optical module (4), a power module (6), a control module (8) and/or a cooling module (1), characterized in that each module (2, 4, 6, 8' 10) forms a common outer peripheral surface (12) at least in sections It is inserted into a common housing (14) in a replaceable manner. 2. If the lighting system of the scope of the patent application is applied, the modules (2, $, 6 ' 8, 10) are arranged in a coaxial manner and adjacent modules (2, 4, 6, 8, 1〇) The side (20) is substantially flush extending. 3. If the illumination system of claim 2 or 2 is applied, the modules (2, 4, 6, 8, 10) are complemented by an object (18) which is substantially in the form of a cube or a rectangular parallelepiped. 4. The illumination system of any one of claims 1 to 3, wherein each module (2, 4, 6, 8, 10) is detachably interconnected in a positive locking and/or negative locking manner. With. 5 · The illumination system of claim 1 wherein each module (2, 4, 6 ' 8, 10) is substantially disposed in a common plane. 6. The illumination system of any one of claims 1 to 5, wherein each module (2'4, 6, 8, 1) has a substantially rectangular base (16), each matrix comprising Same installation size. 7. The illumination system of any one of claims 1 to 5, wherein each module (2, 4, 6, 8, 1) has a substantially circular base (16) 'each substrate Contains the same mounting dimensions. 8. The illumination system of any one of claims 1 to 7 wherein at least one front wall (54) and/or rear wall of each of the-24-200842279 modules (2, 6, 8, 10) 56) There are a plurality of contact elements, each of which is connected to an adjacent module (2, 6, 8, 10) to connect the touch elements to transmit power and/or signals. The lighting system of any one of items 1 to 8, wherein each module (2, 6, 8, 10) is provided with at least one cooling surface (46) provided with cooling ribs (50, 126). The illumination system of any one of items 1 to 9, wherein the light source module (2) has at least one inner region (22) for accommodating at least one light source (24). Φ Π as claimed in claims 1 to 10 The illumination system of any one of the preceding claims, wherein the light source module (2) has at least one light emitting diode (24), in particular an OSTAR® or DRAGON® light emitting diode configuration. 1 2 · as claimed in claim 1 The illumination system of any of the items 1 to 1, wherein the optical module (4) has at least one aperture (36) and/or a cover <38). The light system (36) is composed of a light transmissive material and has a notch (40) associated with the light source (24) of the light source module (2). A lighting system of item 13, wherein the cover (38) has at least one lens (42), in particular a Fresnel lens, to steer light emitted by the light source (24). 15 as claimed in claims 1 to 14 The lighting system of any one of the preceding claims, wherein the cooling module (10) has an active and/or passive cooling element. The lighting system of any one of claims 1 to 5, wherein the power module Group (6) has at least one electronic operating device for the light source (24) 'especially with the 0PT0TR0NIC® operation-25-200842279 device for the light emitting diode configuration. "1 7 · as claimed in the first to The lighting system of any one of the six items, wherein the sacrificial control module (8) has at least one digital control device. 18. The illumination system of claim 17, wherein the control module (8) has at least one signal receiver, in particular an optical signal receiver or a signal receiver controllable according to a radio connection. The illumination system of any one of claims 1 to 18, wherein the two mutually facing side walls (70, 72) of the module (2) respectively have a terminal (82) φ end region The segment (78, 80) is used for the receiving port (74), and the end segment (78, 80) forms a wobble axis. 20. The illumination system of any one of clauses 1 to 18, wherein at least one module (2, 4) is swingably disposed in a frame member (112) and slidably received In a support frame (116), the modules (2, 4) can be swung with a universal joint. The illumination system of any one of claims 1 to 18, wherein at least one of the modules (2, 4) is swingably disposed in a frame (94, 108) #' box (94, 108) rotatably secured to the orbiter (102) movably disposed on a track by a support rod (100). 22. A lighting arrangement (64, 110) for forming a planar illumination and having a plurality of illumination systems (1) as claimed in any one of claims 1 to 21. 23. The lighting arrangement of claim 22, wherein the lighting arrangement (64' 110) has two or more lighting systems (1) that are disposed adjacent and/or overlapping and at least in sections The way forms a common luminous surface (1 18). -26-