EP2591640A1 - Control of operational parameters of operational devices for led's - Google Patents

Abstract

The invention relates to a method for defining an operational parameter of an operational device for lighting means. Said method consists of the following steps: the voltage supply of the operational device is preferably switched on/off manually, the on/off switching is evaluated by the operational device as to whether at least one first predetermined criterion is fulfilled, for example, time constants or repetition rates, in this is the case, a continuous, preferably cyclic change of the predetermined operational parameters is switched on by the operational device, the changed operational parameter is returned to the user directly or indirectly, optically and/or acoustically, and the actual value of the changed operational parameters is maintained at a moment in time for a subsequent operation of the lighting means to which an additional on/off switching of the voltage supply fulfills at least one second criterion.

Description

 Control of operating parameters of operating devices for LEDs

Field of the invention

The present invention relates generally to the field of controlling operating parameters of lighting apparatus such as LED, gas discharge lamps or halogen lamps. In particular, the invention can be applied in the field of so-called retrofit LED lamps, which are substituted for e.g. used by incandescent or halogen lamps. Retrofit lamps accordingly have connection pedestals with which they are incorporated into known lamp holders, e.g. screwed or plugged, can be.

In the following, "LED" is also understood to mean "OLED ^" .

Background of the invention

In the following, the invention is described above all with regard to retrofit lamps, in particular retrofit LED lamps. However, it is to be understood that other, appropriately designed operating devices for lighting means should be included. For retrofit lamps, it is important that they essentially reproduce the functionalities known from incandescent lamps. One of these known functionalities is the dimming function. Conventionally, a Dimming is performed as a phase dimming, which brings in particular when using retrofit LED lamps various problems. With common LED lamps, dimming usually takes place via separate control lines by transmitting dimming information, eg a dimming level value, to the LED lamp. In the retrofit area, this is not possible, since already the necessary control lines are not available, but there is only a two-wire connection to the lamp.

Lamps are known which can be switched by means of certain on / off switching sequences of an operating or mains voltage into two discrete lighting modes. Such a lamp according to the prior art can be switched by simply turning it into a first lighting mode, in which the lamp is operated until it is switched off at full power. By a series of successive on / off operations, e.g. On-Off, the lamp can be switched to a second lighting mode in which the lamp is e.g. is operated with a predetermined lower power, ie dimmed. Switching off brings the lamp back to the initial state, from which again either the first or the second lighting mode can be selected.

This functionality is also known under the term "double click", in which the lamp evaluates fast, repeated (for example, two times) switching on and off of the operating voltage as information, in particular as dimming information Operating voltage evaluates the ballast Electronics of the bulb so to the effect that the lamp with reduced power (dimmed) is operated.

In the case of the known lamps, however, only two predefined light modes are available and the user can only choose between these light modes (for example 100% power or 80% power). If a dimming to another level is desired, then another lamp must be selected and / or the lamp replaced.

Object of the invention

It is therefore an object of the invention to provide an alternative control method for illuminants, such as, for example, for LED lamps, and in particular, but not exclusively, retrofit LED lamps without the disadvantages described above.

This object is achieved by the features of the independent claims. The dependent claims further develop the central idea of the invention.

Summary of the invention

The invention solves the problem with a method for vorgäbe an operating parameter of an operating device for a light source, such as an LED as, wherein the bulbs are controlled via a single-stage or multi-stage power converter, which is clocked (high) frequent, comprising the the following steps: preferably manual switching on / off of the power supply of the operating device, evaluation by the operating device, whether switching on / off meets at least a first predetermined criterion, such as time constants or repetition rates, in the positive case, Triggering a discrete or a continuous, preferably cyclical change of the operating parameter to be specified by the operating ^device , wherein the changing operating parameter is reproduced to the user directly or indirectly optically and / or acoustically, and wherein the current value of the changing operating parameter is for subsequent operation the lighting means is held at the time at which further switching on / off of the power supply satisfies at least a second criterion and wherein the changing operating parameter preferably influences the frequency or the duty cycle of the power converter.

The method may comprise the following steps: feeding the current value in a memory to the detection of further switching on / off, and operating the lighting means, for example LED (s) with the value stored in the memory for the operating parameter. The LED as lighting means may be replaced by an optical and / or acoustic signaling means.

The method may further comprise a step for detecting a third switching sequence, with which again the continuous changing of an operating parameter with which the lighting means are operated is initiated. ,.

After a predetermined switch-off time, the operating device can be reset to an initial state.

After detecting a further switching sequence, the operating device can be reset to an initial state. The switching sequences can be performed with a switching element.

The change of the operating parameter can be done using voltage cycles.

The zero crossings of the voltage can be determined and used as a time base to synchronize the operating parameter change.

The duration of the change between the first value and the second value of the operating parameter may be defined to a predetermined number of voltage cycles. The stored value for the operating parameter may correspond to the current value at which the operating parameter is changed.

The operating parameter may be a mode selection, a dimming level and / or a power with which the light sources are operated.

 In a further embodiment, the invention provides a control circuit comprising a microcontroller and / or an application-specific integrated circuit (ASIC) for operating light-emitting means, such as, for example, one or more LEDs with the inventive method.

Next, the invention solves the problem with a lamp consisting of a control gear and lighting means, with a connection via which the operating device is connected to a power supply, a preferably high-frequency clocked power converter for operating the light source, a manipulation sequence detector for detecting at least a switching sequence, a modulator which varies an operating parameter with which the lighting means is operated between a first and a second value, a memory which stores a value which corresponds to the operating parameters set by the modulator at a time, to that of the manipulation sequence Detector detects a second switching sequence.

Further advantageous embodiments of the invention will be described below with reference to the drawings.

DESCRIPTION OF THE DRAWINGS FIG. 1 shows a schematic representation of a lamp according to the invention consisting of an operating device and a lighting device. The dashed area indicates that the illuminant can be provided either with or separate from the operating device.

Fig. 2 shows a temporal sequence of manipulation sequences and a resulting emission.

Fig. 3 shows schematically a synchronization of a

 Operating parameter change with voltage cycles.

Detailed description of the invention

With reference to FIG. 1, a schematic structure of a retrofit lamp according to the invention will now be described. The retrofit Lamp consists of a control gear 10 and a lighting means 15, such as an inorganic LED or OLED bulbs. Other lamps, such as, for example, halogen lamps or gas discharge lamps, can also be operated by the operating device.

The operating device 10 is connected via conductor 1 to a voltage source 2. The operating device 10 can be separated from the voltage source 2 and connected to it by at least one (one-pole or two-pole) switching element 3. Instead of the lighting means 15, another operating means can also be used which generates an optical or acoustic emission. The operating device 10 comprises a manipulation sequence detector 11, e.g. a switching sequence detector, a modulator 12, a memory 13 and a power converter 14. The lighting means 15 can be connected either directly or via conductor 16 to the operating device 10. The LED 15 is driven via the power converter 14, which is clocked at high frequency.

The power converter 14 may be formed by a switching regulator and has at least one power switch, which is clocked at high frequency. The power converter 14 can be, for example, an inverter (buck-boost converter), a buck converter (buck converter), an isolating flyback converter (flyback converter) or else an insulated or non-isolated half-bridge converter. The power converter 14, shown schematically as a block, may be single-stage or multi-stage. One or more stages can be actively clocked by one or more control circuits by means of one or more switches. An example of a multi-stage design is a two-stage design in which the first stage is an actively clocked PFC (Power Factor Correction) circuit that provides a DC output voltage, which is preferably regulated. The DC output voltage of the PFC circuit is used to supply a second converter stage as an intermediate circuit voltage or bus voltage, which is a DC / DC converter (eg in the case of LEDs as lamps) or a DC / AC converter (eg an inverter in the case of LEDs) of gas discharge lamps). Likewise, the second converter stage can also be actively clocked by one or more switches. For example. For example, the second stage may be a PWM (Pulse Width) modulator.

The manipulation sequence detector 11 is configured to recognize manipulation sequences or switching sequences that are generated by switching the switching element 3 on / off. The manipulation sequence detector 11 monitors criteria such as time constants and / or repetition rates in order to discriminate different sequences.

The manipulation sequence detector 11 can be combined with a circuit that is already used in so-called emergency lighting devices in order to detect an emergency light case, which now has no DC voltage but a DC voltage as the supply voltage for the operating device. Such a circuit is known from DE 10 2007 040555 AI, the disclosure of which is hereby incorporated by reference. On the one hand, therefore, such an AC / DC

Detection circuit can be used to implement the function of detection of the manipulation sequence alone. As an exemplary embodiment, the operating device is an emergency lighting device in which an AC / DC detection circuit is used both for detecting the AC / DC voltage and for detecting the temporary (not replaced by DC) switching off the AC supply.

The manipulation sequence detector 11 is connected to the modulator 12 and the memory 13. The modulator 12 is connected to the memory 13 and the power converter 14.

The modulator 12 is adapted to provide an operating parameter, e.g. a voltage for the lighting means 15 between a first value, e.g. a first dimming level, and a second value, e.g. a second dimming level, or to operate the power converter 14 with values between the first value and the second value or at these values. These values are converted by the power converter 14 such that the lighting means 15 connected to the power converter 14 generates a desired emission which lies between or the first and the second value or thereupon. In particular, the operating parameter affects the timing, for example the frequency or the Einschaltverhältni.s of the power converter 14th

The operating parameter, in the case of the multi-stage embodiment of the power converter, the timing of the / the switch be one of the stages or several stages. For example. For example, the operating parameter may be the timing of the switch of a PFC circuit (as first or only stage), wherein preferably the timing changes the DC output voltage of the PFC circuit, which preferably has an influence on the light output of the lighting means (dimming over amplitude). However, this dimmability can also be achieved by other dimming techniques or possibly combined with further dimming techniques of a further stage, such as PWM dimming (preferably for LEDs) or dimming over the frequency in the case of a half-bridge converter (for example for LEDs).

In one embodiment, the first value corresponds to 100% of the possible emission, e.g. 100% light emission, and the second value to a much lower percentage of the possible emission, e.g. a dimming to 5% light emission. However, for the first and second values, all values from 0-100% of the possible emission can be selected. It is also possible for the modulator 12 to detect a change in the values at the second value, e.g. at the second dimming level, begins.

The modulator 12 may be further configured to cyclically change the operating parameter between the first and second values, thereby causing a continuous change in the emission.

The modulator 12 may be further configured to change the operating parameter cyclically between the first and the second value, the first value being reached again at the end of the cyclical change, which can also be repeated several times. In this way, it is possible to ensure be set that an unwanted or faulty triggering of the cyclic change without influence on the continuous operation remains.

The memory 13 is connected to the manipulation sequence detector 11, the modulator 12, and the power converter 14. A value can be stored in it which indicates the current value for the operating parameter, e.g. a dimming level for a lighting means 15. With this value, it can be determined how the power converter 14 operates the lighting means 15, i. which emission is to be set on the illuminant 15. The operating parameter set by the manipulation of the power supply of the operating device by a user may also constitute a mode selection so that one of at least two modes of operation may be selected. Preferably, the plurality of operating modes are already stored in advance (for example, by the manufacturer) in the operating device.

In this case, an example set by the manufacturer default setting ("Default Setting"}, ie in the case of a standard run-up (without Betriebsartrwahl by a user) is the operating device (preferably software), for example. Configured so that it (light) Sensor reacts ("sensor mode"), that is, depending on the output signal of the sensor changes the operation of the lamps, in particular their brightness or light output adapts.

If, on the other hand, the user selects a mode of operation by a certain sequence (as described) by means of voltage nipulation is generated, the system changes to a mode deviating from the basic mode, called "user mode." This user mode can be an operating mode in which the lamps are operated with constant power.

The user can thus choose between an operating mode in which the operating device dims the lamps, and a operating bit, in which the lamps are always operated at a constant power ("fixed output").

It can also be provided that the user can selectively activate or deactivate certain operating blocks (for example heating of the filaments of a gas discharge lamp) in one of the operating modes by means of said supply voltage manipulation of the operating device.

This invention now allows e.g. a dynamic dimming according to the following principle (see Fig. 2):

The switching element 3, e.g. the power switch is actuated to turn on the lamp or the operating device according to the invention and cause a light emission at the lighting means.

This switching on is detected by the manipulation sequence detector 11. If no further action takes place within a certain time after the voltage has been switched on, the activation of the manipulation sequence detector 11 is recognized, for example, as a normal switch-on (normal on, FIG. 2 above) and the light-emitting means at a predetermined power value, eg 100% power, operated. This can eg also be done so that in the memory 13, a certain default value {default) is present, which corresponds to the predetermined power value. However, if after switching on within the specific time another switching action, such as another switching off and on (sequence), this is also detected by the manipulation sequence detector 11 and interpreted as an instruction to switch to a dimming mode. If the manipulation sequence detector 11 detects the instruction to change to the dimming mode, it instructs the modulator 12 to cyclically control the power converter 14 with values between the first and the second dimming level. As a result, the light emission at the light source is continuously changed {up and down dimming).

Typical time constants for the downward or upward dimming flank are in the range of a few seconds, for example 2 to 10 seconds.

The predetermined time may be a threshold, which is usually well below one second. Thus, after the rapid restart, the operating device cyclically dimming from the nominal value 100% to a minimum dimming value of, for example, 5% and then dimming again upward (see FIG. 2 below).

This cyclic down and up dimming will. repeatedly until the user manually sets the current value by renewed rapid switching off and on (sequence) of the power supply, so to speak, freezes. In this case, a further switching sequence is detected by the manipulation sequence detector 11. Then the instantaneous modulation value is stored in the memory 13 and the light source is operated by the power converter 14 with the modulation value, with correspondingly reduced light emission. The further off / on sequence may correspond to or be different from the first switching sequence.

After switching off the voltage for a further predetermined period of time, in one embodiment the operating device is reset to an initial state (in the memory 13, for example, the default value is set). The memory 13 may also be arranged outside of the operating device 10. For example, the operating device 10 may be connected via an interface with the memory 13 arranged outside the operating device 10. Thus, it may also be possible that when replacing the operating device 10, the memory 13 is connected to the newly inserted operating device and the stored in the memory 13 modulation value is transmitted back to the newly used operating device. The memory 13 may be arranged, for example, in a sensor connected to the operating device 10.

If a sensor is connected to the operating device 10 and a memory 13 is present, then different modulation values can also be stored or also programmed in the memory 13 for different sensor values, such as brightness values in the case of a light sensor. Thus, according to an embodiment, even with different sensor values (for example brightness values), the method according to the invention (ie a manipulation sequence) can different modulation values are stored in the memory and these specify the respective modulation value for the power converter 14 as a kind of reference table. But it can also be provided to restore the Ausganszustand by executing a reset sequence. Thus, the specified operating parameter value (eg the dimming level) can also be kept above a normal switch-off (normal off). Only after executing the reset sequence is the initial state restored.

The invention is to be distinguished from the Switch-Dim (TRIDONIC®) or Touch-Dim technology in that the information, i. the manual actuation of a switch takes place directly via the power supply. In the case of touch dim or switch dim, the dimming information is preferably supplied from a pushbutton or switch via a signal input of the operating device (the actual voltage supply is independent of this).

The electronics required for realizing the invention, which discriminates the rapid switching on and off of the normal switching on and off operation, is preferably accommodated in the base region of the lamp (or the retrofit LED lamp).

Furthermore, an energy buffer can be provided, for example a capacitor which bridges at least one "power failure", a switch-off, in the area of rapid on / off switching, so that the electronics can evaluate the switching sequence. Thus, the user can set this setting by executing the second switching sequence at the time when a dimming setting desired by him is present. The sensory reproduction does not necessarily have to be done by the lamps themselves (color temperature change, dimming, etc.), but can also be done by other elements (other optical elements, acoustic elements, etc.). Thus, different operating parameter changes can take place by manipulations of the voltage supply, whereby these can be discriminated, for example, on the basis of different analysis criteria (manipulation or switching sequences).

Alternatively, also different operating parameter changes can alternate cyclically, so that, for example, a first manipulation sequence (double-click) changes a cyclic first operating parameter change, e.g. a Dxmmwert- change, which is then replaced by a second operating parameter change, e.g. a color location change in the next double click, etc.

Furthermore, it is possible to select another operating mode, eg the dimming mode, from the switched-on state by a manipulation sequence (eg, off-on or off-on-off on, in rapid succession, ie within a predetermined period of time). Especially when using several lamps on a power supply, it is important that all lamps are operated with the same modulation values, eg at the same dimming level, ie an equal (light) emission value exhibit. Normally different lamps will have a randomly distributed and therefore different time base. Thus, the bulbs behave differently in the modulation phase, resulting in a non-uniform light image.

According to the invention, any change in operating parameters (for example, down / up dimming) now takes place using an AC voltage, e.g. the mains voltage, as a time base. Preferably, the zero crossings of the voltage are the time base used to synchronize the operating parameter change.

More specifically, the gradient and thus also the time duration between the operating parameter values to be set, or the dimming levels, is defined to a predetermined number of voltage cycles and not over an absolute time duration such as "10 seconds". 3. Voltage cycles are shown in the upper part of Fig. 3. The lower part of Fig. 3 shows how the operating parameter change (down and up dimming steps) is generated depending on the voltage cycles As already mentioned, the invention has been mainly With regard to LED lamps, in particular retrofit LED lamps, it is to be understood that the invention can also be applied to appropriately designed operating devices for other lamps.

Claims

 claims

1. A method for specifying an operating parameter of a

 Operating device (10) for lighting means, in particular one or more LEDs (15), wherein the lighting means (15) are controlled via a power converter (14), which is preferably clocked high-frequency, comprising the following steps:

 preferably manual switching on / off of the power supply (1) of the operating device (10),

 - Evaluation by the operating device (10), whether the

 Switching on / off satisfies at least a first predetermined criterion, such as, for example, time constants or repetition rates,

 - In the positive case, triggering a discrete or continuous, preferably cyclic change of the operating parameter to be specified, wherein the changing operating parameter is the user directly or indirectly optically and / or acoustically reproduced, and

 wherein the current value of the changing operating parameter for a subsequent operation of the lighting means (15) is held at the time at which further switching on / off of the power supply (1) meets at least a second criterion, and

wherein the varying operating parameter preferably affects the timing, eg the frequency or the duty cycle of the power converter (14).

2. The method according to claim 1, comprising the following steps:

 - Save the current value in a memory (13} on the detection of further on / off, and

 - Operating the lighting means (15) with the value stored for the operating parameter in the memory (13).

3. The method according to claim 1 or 2, wherein

 - The optical and / or acoustic reproduction by an optical and / or acoustic signaling means in addition to or alternatively to the lighting means (15).

Method according to one of the preceding claims, with the further step:

 - Recognizing a third switching sequence, with which again the continuous change of an operating parameter is caused, with which the lighting means (15) are operated.

Method according to one of the preceding claims, wherein - after a predetermined switch-off time, the operating parameters of the operating device (10) is reset to an initial value.

Method according to one of the preceding claims, wherein - after detecting a further switching sequence of the operating parameters of the operating device (10) is reset to an initial value.

7. The method according to any one of the preceding claims, wherein - the switching sequences with a switch or button

(3) are executed.

Method according to one of the preceding claims, wherein the power supply is an AC voltage and the change of the operating parameter is synchronized with the course of the AC voltage.

The method of claim 8, wherein

 - The zero crossings of the AC voltage are determined and used as a time base for the synchronization of the operating parameter change.

A method according to claim 8 or 9, wherein

 - The duration of the change between the first value and the second value of the operating parameter is defined to a predetermined number of AC voltage cycles.

Method according to one of the preceding claims, wherein

- The operating parameters is a mode selection, a dimming level, the spectrum of the LED as a light source (15) influencing parameters and / or a power with which the lighting means (15) are operated.

Control circuit, in particular integrated circuit such as microcontroller and / or an application-specific integrated circuit (ASIC), which is designed for operating a lamp with the method according to one of claims 1 to 11. Lamp consisting of a control gear (10) and

 Bulbs such as e.g. at least one LED (15), with:

 - a connection (1) via which the operating device

(10) is connectable to a power supply (2),

 a power converter (14), which is clocked at high frequency, for operating the lighting means (15),

a manipulation sequence detector (11) for detecting at least one switching sequence,

a modulator (12) which changes an operating parameter with which the lighting means (15) are operated at least between a first and a second value,

 a memory (13) storing a value corresponding to the operating parameter set by the modulator (12) at a time when the manipulation sequence detector (11) detects a second switching sequence. 14. Lamp according to claim 13, which is designed as a retrofit LED lamp.