NL1038327A - LED MODULE AND LAMP CONTAINING A LED MODULE. - Google Patents

Description

LED Module and lamp containing an LED module.

FIELD OF THE INVENTION

The invention relates to an LED module comprising a number of LEDs and a reflector for reflecting light emitted by the LEDs.

State of the art.

An LED module as described in the first paragraph is known from the German patent application DE 10 2004011600. The reflector is formed as a circumferential ring with an inner and an outer reflector surface, the surfaces being shaped as parabolas. A ring with LEDs is placed in the reflector. LED is the standard expression for a Light Emitting Diode.

The LEDs emit light sideways, in the direction of the reflective surfaces of the reflector. The light is reflected through the reflective surfaces of the reflector.

The annular reflector can have an opening in the middle behind which an LED can also be placed. Such a module can be used, for example, for the rear lights of a vehicle. The rear of the ring can have a different function, for example be provided with reflectors.

The light image is a central, light, part, and an outer light ring separated by a dark band. Although this could be suitable for the rear lights of a car, this is not suitable for existing LED lights in lighting equipment.

The known lamp is not suitable for the continuing miniaturization of LED modules.

The ever-increasing miniaturization of LED modules creates, among other things, an effort to create space for electronic circuits in the LED module.

An obstacle in this regard is the fact that, in order to ensure that LED lamps can be deployed quickly, it is important that the LED module is no larger than existing LED lamps, because otherwise the module will no longer fit into existing lighting appliances. The outside dimensions of the module are therefore preferably not or hardly changed. This places limitations on the design because on the one hand you want to gain space but on the other hand the outside dimensions are limited and the total light output and the light image must of course also not be negatively influenced. In addition, heat management is important.

Summary of the invention

In order to meet these initially contradictory requirements, according to the invention an LED module is provided which comprises a ring of LEDs, the module comprising a reflector cup for each LED, and wherein a common annular reflector space is arranged for the collection of reflector cups, the annular reflector space encloses a central space with a raised edge, shielded from the light from the LEDs.

This arrangement makes it possible to obtain a focused, more or less uniform light beam, whereby the LEDs and the reflectors require less space. A space has been saved in the middle of the LED module. A part of the electronics that are normally in the power supply can be placed in this space. The vacant space can also be used to add an extra function to the LED module, for example a sensor, speaker, camera. The light from the LEDs does not enter this central space and can not interfere with the function of the parts placed in the recessed space.

This is particularly advantageous if an optical sensor location is located in the recessed space. Optical sensors include cameras, FIR sensors, motion sensors, and some smoke sensors.

The reflector cups preferably overlap each other. The overlapping of the reflector cups gives a better light profile and makes it possible to design the module slightly smaller.

The module preferably comprises a diffuser between the reflector cups and the 2nd reflector space.

Alternatively, the module includes a diffuser on the front of the common reflector space.

The LED module preferably comprises a heat sink with a recess for a reflector cup.

A reflector cup preferably has an elongated recess on the side facing the LED.

It is noted that EP2034234A1, US72441019B1 and US2004095763 describe LED modules that contain a ring of LEDs. However, none of these modules contains a common reflector space with a raised edge enclosing a central space, which central space is shielded by the raised edge of the reflector space of the light from the LEDs. There is no question of a sensor in the central room.

Brief description of the drawings

The invention will be explained in more detail below with reference to exemplary embodiments of the LED module according to the invention shown in the drawings.

It shows:

Figure 1 is a perspective view of an LED module according to the invention with power supply;

Figure 2 shows a more detailed perspective view of an LED module according to the invention;

Figures 3A and 3B show two examples of a reflector for an LED module according to the invention;

Figures 4A to 4C show views of a reflector for an LED module according to the invention;

Figure 5 shows a cross section of a reflector for an LED module according to the invention. Figure 6 shows a further example of a module according to the invention.

The figures are exemplary figures, the same parts are generally designated by the same reference numerals.

Detailed description of the drawings

Figure 1 shows in perspective view an embodiment of an LED module according to the invention with power supply.

The LED module contains a PCB 1 on which LEDs are mounted. A reflector 2 is provided for the PCB. To dissipate the heat, the PCB is mounted against a heat sink 3. In this example, a shielding glass 4 is provided for the reflector 2 in order to ensure that the inside of the reflector does not become dirty, as a result of which the light output would be reduced. A diffuser 5 is placed in the reflector in this exemplary embodiment. This is an optional application depending on the extent to which a focused beam is to be made. The diffuser is preferably matte in color to optimally mix the light and preferably has a light loss of less than 15%.

A secondary connection cable 8 is supplied via a mains plug 6 for the 230V mains network and a 230V / 24V 7 power supply.

It is desirable to have the largest possible space inside the LED module for inserting an electronic circuit. Sometimes the features require more than the usual 2 wires (+ and - wires) for the power supply. By moving part of the electronics from the power supply to the LED module, it is possible to continue working with only 2 wires. In this embodiment, a female socket 11 is integrated in the rear side of the heat sink so that different cable diameters and cable qualities can be connected to this

Due to the ever-increasing miniaturization of electronic circuits, it will probably become possible in the future to have the 230V / 24V power supply decayed and to connect the module directly to 23 OV. An enlarged space for an electronic circuit by means of a second printed circuit board which is connected to the first printed circuit board via a plug also offers the possibility of an additional component (for example a sensor or camera 12) on the front of the lamp, shielded from the light of the LEDs. , so that this extra part can do its job well. The light from the LEDs in the ring does not enter the room, so that this light cannot affect the function of a component negative placed in the room. This is particularly important for optical sensors, including cameras, FIR sensors and some smoke sensors.

However, in order to achieve rapid deployment of LED lamps in practice, it is important that the LED module is not significantly larger than the existing halogen lamps.

The external dimensions of the existing halogen lamps are laid down in standards (“lamp outlines”) and it is therefore important to stay inside with the LED modules so that a quick exchange is possible without having to buy a new lighting device.

The invention provides an LED module that makes this possible.

Figure 2 shows a LED module according to the invention in more detail.

LEDs 9 are mounted on the PCB 1. Electric circuit 10 is also provided on the PCB and an additional feature 12, in this exemplary embodiment a PIR (PyroelectricInfrared) sensor 12 is provided. In this embodiment, the wall of a reflector cup is designed in such a way that a light beam of 17 ° or less, for example 12 ° (narrow spot), is created.

With a diffuser, if the beam width can be increased from 17 ° or 12 ° to 25-30 ° (spot) or from 17 ° to 50-60 ° (flood).

This widening of the bundle is accompanied by a light loss of less than 15%, preferably less than 10%; In addition, the diffuser ensures that the reflector cups and LEDs are hidden from view and creates a quiet, homogeneous circle of light.

Figures 3A and 3B show two examples of a reflector for an LED module according to the invention. The reflector 2 comprises a number of cup-shaped reflector cups 13 provided on the underside with an opening for an LED. The reflector also contains a 2nd common reflector space 14. This arrangement makes it possible to obtain a focused or more uniform light beam, whereby the LEDs and the reflector require fewer spaces. A space has been saved in the middle of the LED module. In this space a part of the electronics, which is normally in the power supply, can be placed. The released space can also be used to add an extra function to the LED module. The 2nd reflector chamber 14 also offers the possibility, in embodiments, to widen the light beam by placing the diffuser 5 on the transition from the reflector cups to the 2nd reflector space. Placing the diffuser in the common room reduces the risk of being blinded when looking obliquely at the lamp, it is preferable to place the diffuser as deep as possible in the reflector. The diffuser can also, in preferred embodiments, be placed at the front of the lamp so that the light can first be mixed in the common reflector space and then even further mixed by the diffuser 5. The distance is chosen so that the whole is exactly within the outlines of the existing ones halogen lamp remains. It is easier to stay within the outlines by not choosing the standard high power LEDs (> 1 W), but by taking a smaller smaller power LEDs (0.3 W-0.7 W). The reflector cups that could be placed around these smaller LEDs can then be smaller. Figures 3A and 3B show reflectors with a diameter of approximately 50 mm and approximately 100 mm, respectively. The number of reflector cups is about 12, for example 10 and 20. To make different beam widths, it is advantageous to design the reflector cups in such a way that a low-light beam (10-15 or 15-17 °) is made. The beam can be made larger via difluser.

It is possible to use 3 different reflector cups for different beam widths, but that would lead to an increase in stock and higher investments. The shape would then be different for all 3 and there might be a problem when gluing the reflector (cups) to the crown-shaped heat sink. The shape of the parabola of the 12 ° variant fits very well against the crown, creating a nice glue surface. Starting from a parabolic shape for a reflector cup, it is possible to experiment with the height of the wall (or reflector cup). It has been found that the higher the cup, the narrower the light beam became. Above the 9mm height, there is hardly any effect and that is why this size is preferably chosen.

To ensure that the user does not look into the annoying light, it is advantageous to place the ring of reflector cups as deep as possible without the test mark outside the lamp outlines. The height of the 2nd mixing chamber is then approximately 6 to 10 mm.

In order to generate as much light as possible, it is beneficial to place many LEDs in the circle. The inventor realized that by overlapping the reflector cups there was little influence on the total light beam, but the light output did increase, with the additional advantage that it became more of a connecting circle lamp instead of individual light points. Another advantage of using more LEDs is that the heat can then be dissipated better and more evenly to the heat sink 3.

To give the heat sink 3 as large a surface as possible, crown-shaped protrusions are provided around the reflector 2. The heat sink extends to the front so that the heat can also be dissipated via the lighting device, which is generally also made of metal. If the front side of the heat sink were made of plastic, this plastic acts as a bottleneck in the heat transfer to the lighting device to increase the heat transfer capacity.

An additional advantage is that it makes it possible to glue the reflector 2 properly at that location, so that the end user cannot open it and can reach parts carrying current.

The common annular reflector space 14 is provided with an outer wall 15a and an inner wall 15b. The inner wall 15b encloses a central space 16. The light from the LEDs does not enter into the central space 16 due to the screening effect of the inner wall 15b. In the central space 16 a part of the electronics, which is normally in the power supply, can be placed. The vacant space can also be used to add an extra function to the LED module, for example a sensor, speaker or camera.

The light from the LEDs does not enter this central space and cannot interfere with the components placed in the central space 16.

This is particularly advantageous if an optical sensor location is located in the recessed space. Optical sensors are, for example, a camera 12, FIR sensors, motion sensors, and some smoke sensors. The wall 15b shields the optical sensor from the light of the LEDs, so that the optical sensor 12 is not affected by this. Especially when using sensors for surveillance, such as surveillance cameras and / or motion sensors, great advantages are provided: - no separate sensor is required, the sensor is integrated in the LED module - the object or person to be monitored is always well lit - the presence of the sensor is, in use, not or very difficult to detect by person with the eye. To do this, one must look straight into the light. However, this dazzles the eyes, so that persons who want to approach an object with poor intention to be monitored cannot see in use whether the module, or if there are more, which of the modules, is provided with an optical sensor.

In embodiments, the LED module can be provided with both a motion sensor and a camera. It is also possible to use a system of LED modules, wherein at least one of the modules of the system is provided with a motion sensor and at least one with a camera. To prevent a fire hazard, it is also possible to use a system of LED modules in which one is provided with a smoke detector and at least one with a camera. In the event of a fire, you can immediately see where the fire is.

Figures 4A to 4C show different views of a reflector for a LED module according to the invention. In figures 4B and 4C it can be seen that the reflector cups overlap in overlap area 17. To ensure good heat transfer from the pcb to the heat sink, the pcb is screwed down with a number of e.g. 3 screws. By making an elongated recess 18, see figure 4C, on the underside of each reflector cup, the screw head fits neatly between any desired reflector cup.

Placing the screws between reflector cups has the advantage over the use of screws in the center of the pcb that valuable space for the electronic components has been lost.

Figure 5 is a sectional view of a reflector for an LED module according to the invention.

The dimensions are also shown schematically on this. I stands for the depth of the reflector, II for the size of the overlap and III for the height of the two-reflector space.

The total depth (I + III) is preferably between 15 and 19 mm, preferably about 17 mm, with a margin of about 0.5 mm. The ratio between sizes I and III is preferably between 0.7 and 1.5. The ratio of the depth of the reflector cup to the depth of the two reflector space is then between 0.7 and 1.5. In this example, about 9 mm and III are approximately 8.3 mm. The reflector cups provide a focused bundle, while the common second reflector space ensures a mixing of the light. A very short second reflector space produces too little mixing, a too long has the disadvantage that people come outside the lamp outlines. The ratio between the depth II of the overlap between reflector cups 13 and the depth I of the reflector cups is preferably between 0.2 and 0.4. In this example II is approximately 2.6 mm. Too large an overlap gives a greater spread of light. Both proportions in depth are preferably met.

The common reflector space is preferably designed as a gutter, the width IV of the gutter being between 12 and 18 mm. The diameter V of the reflector is preferably between 50 and 100 mm, depending on the type of LED module. These dimensions provide a good light image and sufficient space is saved in the middle of the LED module for electronics and / or extra features.

It will be clear that the invention is not limited to the embodiments of the invention given herein.

Figure 6 shows a further example of an LED module according to the invention. This module differs from the module shown in Figure 1 in that a wall of the heat sink serves as part of the common reflector space. The wall 15b is part of the heat sink in this example. The reflector space is formed by a wall of the heat sink walls of reflector 2. Reflector 2 lacks the outer wall 15a, but does have inner wall 15a, in this example.

The module can be provided with a temperature sensor, such as a thermistor. These can be used to keep the operating temperature below a certain temperature, for example, at the sensor site below 75 ° C, preferably below 70 ° C. A signal from the temperature sensor can be applied to a control circuit for the sensor. In an exemplary embodiment, the thermistor is provided between the LEDs. The signal from the thermistor is an indication of the temperature. This signal is applied to a control circuit for the sensor, for example a microprocessor. For example: The sensor 12 is a motion sensor. A motion sensor gives a signal. To prevent any movement, including that of a small object such as a flying fly or moth or circling mouse, from being reacted, the signal from the motion sensor is compared to a calibration signal, or a "threshold" in English. Only if the signal from the movement sensor is larger than the threshold is a movement recorded and can an action follow, such as switching on the lights and / or cameras or giving a signal to a monitoring center. The sensitivity of the motion sensor is temperature-dependent, wherein in one example a higher temperature gives a lower sensitivity, that is to say that the same movement of an object at a higher temperature gives a smaller signal from the motion sensor. The signal from the thermistor is applied to the control circuit, which sets the threshold as a function of the signal from the thermistor, that is, as a function of the temperature in the module, in which case the threshold is reduced as the temperature increases. This can be in hard-ware form, but also in the form of soft-ware.

In this example there is a motion sensor, but the same principle can be used for other sensors, such as smoke sensors or cameras.

Claims (15)

LED module comprising a number of LEDs (9) and a reflector (2) for reflecting light emitted by the LEDs, characterized in that the LED module comprises a ring of LEDs, the module comprising a reflector cup (13) for each LED and wherein a common annular reflector space (14) is placed in front of the collection of reflector cups, wherein such reflector space comprises an upstanding edge (15a) enclosing a central space (16), shielded from the light of the LEDs. LED module according to claim 1, characterized in that the module comprises a sensor (12) in or on decentralized space (16). 3. Led module according to claim 2, characterized in that the sensor is an optical sensor. LED module according to claim 3, characterized in that the optical sensor is a camera (12). 5. Led module according to one of the preceding claims, characterized in that the module is provided with a temperature sensor, wherein the signal from the temperature sensor is applied to a control circuit for the sensor. LED module according to claim 1, characterized in that the reflector cups overlap (17). LED module according to claim 5, characterized in that the ratio between a depth (II) of the overlap between reflector cups and a depth (I) of the reflector cups is between 0.2 and 0.4. LED module according to claim one of the preceding claims, characterized in that the module comprises a diffuser (5) between the reflector cups (13) and the 2nd reflector space (14) or in the reflector cups (13). 9. LED module according to claim 1, characterized in that the LED module comprises a heat sink (3) and a recess for a reflector cup. 10. LED module as claimed in any of the foregoing claims, characterized in that the LED module comprises a heat sink of metal that extends to the front. LED module according to one of the preceding claims, characterized in that a reflector cup has an elongated recess (16) on the side facing the LED. 12. LED module according to one of the preceding claims, characterized in that the ratio between a depth (I) of the reflector cups and a depth (III) of the 2 * reflector space is between 0.7 and 1.5. 13. LED module as claimed in any of the foregoing claims, characterized in that the second-reflector space is designed as a gutter, wherein the width (IV) of the gutter is between 12 and 18 mm A lamp comprising an LED module according to any one of the preceding claims. 15. Reflector apparently suitable for an LED module according to one of the preceding claims.