• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    An operating circuit for operating LED lines is provided, comprising at least two parallel LED lines, the LED lines being designed to emit light in the white spectrum, the LED lines differing from one another in terms of the color temperature of their spectrum, and one with an AC voltage supply control circuit which is designed to supply the LED lines with a rectified AC supply voltage and a preferably adjustable total current, and wherein the control circuit is designed to evaluate the AC voltage and depending on phase information , such as phase control or phase control and / or a sequence of phase control signals and / or phase control signals of the AC voltage to set a distribution of the total current to the parallel LED lines.
    公开号:AT17005U1
    申请号:TGM390/2015U
    申请日:2015-12-22
    公开日:2021-02-15
    发明作者:
    申请人:Tridonic Gmbh & Co Kg;
    IPC主号:
    专利说明:

    description
    COLOR TEMPERATURE DIMMING OF AC-SUPPLIED LED LINES USING PHASE INFORMATION
    The invention relates to an operating circuit and a method for operating at least two parallel LED lines, a color temperature preferably being set based on phase information. The invention also relates to a lamp, an LED lamp or an LED module with such an operating circuit. The phase information is evaluated by a control circuit which, depending on the evaluation, carries out a color or color temperature dimming with the at least two parallel LED lines.
    [0002] In the following, dimming or the setting of a dimming value primarily relates to the setting or regulation of a color temperature, with the emitted color also being able to change in principle. In addition, the brightness can be dimmed, with which the overall brightness of the light emitted by the LED lines is regulated.
    It is known that mixed light of a predetermined color temperature or color can be generated by mixing the light emitted by at least two LED lines, the light emitted by a first LED line and the light emitted by a second LED line have at least portions of different wavelengths. For example, in an undimmed state, white mixed light can be emitted from the first LED segment, which has a higher longer-wave component, while white mixed light is emitted from the second LED segment, which has a higher shorter-wave component. The proportion of the respective white mixed light is then set depending on a degree of dimming. A limit between longer-wave and shorter-wave light can be, for example, 500 nm.
    In this case, for example, warm white light ("warm white") can also be generated in an LED path by mixing at least one red light emitting LED and a color-converted blue light or UV light LED For example, it can be a chip that generates blue light or UV light and is covered with a phosphor layer that converts the blue light or UV light into longer-wave light with a correspondingly different color can be generated by red, green and blue (RGB) light, which can be emitted by at least one LED path with corresponding colored LEDs.
    In the present invention, it is assumed that the at least two LED lines differ from one another in terms of the color temperature of the emitted spectrum.
    The first LED segment of the at least two LED segments can emit white light of a first temperature, for example warm white ("warm white", ww) light, while the second LED segment of the at least two LED segments white light a second temperature emitted, for example cold white ("cold white", cw) light.
    With conventional incandescent lamps, users are used to perceiving a change in the color temperature, i.e. the spectral distribution of the emitted light, when they are dimmed. In the case of incandescent lamps, there is usually a shift towards warmer white light as the degree of dimming increases. It is also known to use LED light sources instead of incandescent lamps, which have a higher energy efficiency and that a phase control can encode dimming information in order to dim a brightness of LEDs according to dimming information defined by the phase control.
    It is also known to operate LEDs starting from an AC voltage. A suitable circuit therefore has a rectifier which generates a rectified AC voltage from the AC voltage, which is then fed to the LEDs. The LED lines also each have at least one switching element that bridges at least one LED in the respective LED line. Depending on the course of the rectified AC voltage or the
    According to the amplitude value or amplitude swing of the rectified AC voltage, LEDs in the LED paths are switched on or off, i.e. activated or deactivated. In particular, LEDs can be switched on when the amplitude of the rectified AC voltage increases, while LEDs can be switched off or the LEDs can be bridged if the amplitude of the rectified AC voltage drops. This operating principle is also referred to as "AC-LED".
    The invention now develops the idea further that a phase information is evaluated as a dimming signal, for example a phase angle or phase section or a sequence of phase control signals and / or phase section signals, with regard to a color temperature dimming, so as information that a desired Color temperature or a color location to be set is defined. In particular, the phase information can be used to define a setting for white mixed light.
    A signal transmission by means of phase information to an electrical consumer supplied with AC voltage, in particular an LED lamp or LED module, can take place in that at least the signal states "presence of a phase control signal / phase control signal" and "non-presence of a Phase control signal / phase control signal "or" rectified AC voltage "and" non-rectified, i.e. bipolar AC voltage "are present.
    On the basis of these two logical states, any complex analog or digital signal protocols can be implemented. Thus, for example, digitally coded sequences of phase control signals and / or phase control signals can be transmitted as phase information. Analog is, for example, an evaluation by a control unit of the duration and / or a repetition rate of the respective logic state. The two named physical states can be used as logical "1" and "0" for digital signal transmission.
    [0012] This protocol can be addressed or unaddressed. In the case of addressing, data or signals can be part of the protocol.
    Said communication technology through a sequence / sequences of selective phase control and / or phase section or selective rectification does not fundamentally rule out the possibility that further logic states in addition to the two states mentioned may be present on the AC supply line. These can be, for example, a PLC modulation (power line carrier, high-frequency modulation with preferably low amplitude) or a temporary suppression of the AC voltage.
    Phase sections or phase sections can also be implemented in combination with selective rectification, and there are further possible combinations such as additional amplitude modulation.
    In principle, it is also possible that, for example, in addition to the signal transmission mentioned, a further wireless (e.g. radio, optical, IR, ...) or wired medium (e.g. digital and / or analog bus) is provided.
    The control circuit is able to control the at least two parallel LED routes, on the one hand according to the AC LED principle described above, in which the load follows gradually in the course of the rectified AC voltage, and on the other hand according to a mixing ratio , which is set depending on the color temperature specification defined by the phase information.
    [0017] The invention therefore provides an operating circuit and a method according to the independent claims. Developments of the invention are the subject of the dependent claims.
    In a first aspect, an operating circuit for the operation of LED routes is provided, having at least two parallel LED routes, the LED routes are designed to emit light in the white spectrum, the LED routes with respect to each other
    the color temperature of their spectrum differ from one another, and a control circuit which can be supplied with an AC voltage and is designed to supply the LED lines with a rectified AC supply voltage and with a preferably adjustable total current, and wherein the control circuit is designed to provide the Evaluate AC voltage and, depending on phase information, such as phase control or phase control and / or a sequence of phase control signals and / or phase control signals of the AC voltage, set a division of the total current to the parallel LED lines.
    The control circuit can distribute the total current to the at least two parallel LED lines simultaneously or alternately.
    The control circuit can control at least two adjustable current sources depending on the evaluation of the phase information and define the distribution of the total current to the at least two parallel LED lines. The at least two adjustable current sources are preferably part of the operating circuit.
    [0021] An adjustable current source can be assigned to at least one LED path. The LED lines can also be supplied from a common adjustable power source. The current sources can be constant current sources.
    The operating circuit can have an adjusting circuit. The control circuit can control the actuating circuit. In particular, the control circuit can adjust the switch-on duration of the two different LED paths by means of different pulse duty factors.
    The control circuit can adjust the distribution of the total current on the parallel LED routes.
    The control circuit can output a control signal to the actuating circuit. Depending on the control signal, the setting circuit can set a switch-on duration of the at least two different LED strings in a changeable, and in particular alternating manner.
    The control circuit can output the control signal with different pulse duty factors. The setting circuit can adjust the switch-on duration of the at least two parallel LED segments depending on the duty cycle.
    [0026] Each of the at least two parallel LED lines can have one or more LEDs and one or more switching elements. In each case, at least one of the LEDs of an LED path can be bridged by a switching element controlled by the control circuit.
    The control circuit can detect a profile of the rectified supply voltage and, depending on this, selectively activate and / or deactivate the switching elements.
    Each LED path can only have LEDs of one type.
    At least one LED path can have LEDs of different types, in particular LEDs that emit light of different color temperatures.
    In a further aspect, a luminaire, an LED lamp or an LED module with an operating circuit is provided, as described above.
    In yet another aspect, a method for operating LED lines is provided, wherein at least two parallel LED lines emit light in the white spectrum and differ from one another in terms of the color temperature of their spectrum, and wherein one can be supplied with an AC voltage Control circuit supplies the LED paths with a rectified AC supply voltage and a preferably adjustable total current, and the control circuit evaluates the AC voltage and depending on phase information, such as phase control or phase control and / or a sequence of phase control signals and / or Phase section signals of the AC voltage, a distribution of the total current to the parallel LED lines.
    The invention will now also be described with a view to the figures. Show it:
    [0033] FIG. 1 schematically shows a first example of an operating circuit; Fig. 2 schematically shows a further example of an operating circuit;
    Fig. 3 schematically shows an operating circuit which represents a starting point of the invention;
    4 schematically shows an embodiment of an operating circuit according to the invention; and
    5 schematically shows a further embodiment of an operating circuit according to the invention.
    First of all, a possible circuit structure of an operating circuit and a basic mode of operation will be explained with reference to FIGS. 1 and 2. A more detailed embodiment of the invention is then to be described particularly with reference to FIGS. 4 and 5. Technically identical elements are designated as largely the same as possible.
    In order to create, for example, an LED lamp that emits a "warmer" light with increasing dimming or that allows a color location to be set, a further LED path with a first spectral characteristic is used in addition to an LED path with a first spectral characteristic In particular, the LED lines differ from one another with regard to the color temperature of their spectrum.
    For example, an LED path can only have LEDs of one type, while the second LED path can use LEDs of another type. The first LED segment can, for example, emit cold white light, the second LED segment then e.g. warm white (ww) light.
    However, it is also possible that one LED path emits white light and the other LED path, for example, emits amber-colored light. Of course, instead of white light emitting LED lines, colored LED lines can also be used (for example red, yellow, blue and / or green LEDs). The LED segments can of course also have LEDs of different types, for example in order to set a specific tint value or to produce a specific color impression. For example, one or more yellow, red or other colored LEDs can be used together with white LEDs.
    It is also possible to connect white LEDs with different color temperatures in series in an LED path, and then to achieve the mixing by selectively activating / deactivating the different white LEDs, with the AC LED operating principle continuing, as I said is retained. For this purpose, the switching elements are switched to be conductive / non-conductive by the control circuit.
    1 now schematically shows a block diagram of an operating circuit. A rectifier module 20 is supplied with an alternating voltage 10. The rectifier module 20 generates a rectified alternating voltage 11. The rectified alternating voltage 11 then supplies a current source 21, in particular a direct current source, which is preferably designed as a direct voltage converter. The DC voltage converter can be implemented as an isolating flyback converter. The direct current source then generates a total current Ic, which is fed to the at least two LED paths 22. An LED path here is to be understood as meaning that the LED path has at least one LED, but preferably a plurality of LEDs connected in series. The power source 21 can also be combined with the rectifier module 20 in a single module. A dimming device 24 generates a dimming signal 15a which is fed to the operating circuit. The power source can generate the total current Ice as a function of the dimming signal 15a.
    Thus, the signal 15a can cause the first current source 21 to generate a constant direct current Ic of an adjustable current intensity in order to operate the light source 22. The dimming device 24 preferably determines that the signal 15a is determined as a function of a dimming value which, for example, is set by a user on a dimmer.
    will provide. In particular, a phase control or a phase control, which is often generated by phase control or phase control dimmers, can be evaluated as the dimming signal. The AC alternating voltage that is fed to the rectifier 20 then accordingly has a phase control and / or a phase portion which is also present in the rectified AC voltage after rectification by the rectifier 20.
    Another example is shown in FIG. The structure largely corresponds to the structure from FIG. 1. In addition, the circuit here contains a control circuit 23, which processes a signal 13, which draws conclusions about the current color temperature of the light coming from the at least two parallel LED lines or the light source 22 is generated, allows. Here, a dimming signal 15b is fed to the control circuit 23. The control circuit 23 can generate a control signal for controlling the LED segments from the dimming signal 15b and / or the signal 13. In addition to the dimming signal 15b and the signal 13, further signals from the control circuit 23 can be provided for controlling the LED lines 22. For example, it is conceivable that an additional temperature signal is processed. Since the LEDs have a temperature characteristic, it is helpful to consider the current temperature to control the LEDs. The use of a temperature signal is particularly advantageous in order to keep the color temperature constant at a certain dimming value. LEDs of different types and therefore different wavelengths often have different temperature characteristics. This means that if the temperature changes, the mixing of the light from the light source 22 is adjusted by the control unit 23.
    The dimming in Figs. 1 and 2 can relate to brightness dimming and / or color temperature dimming.
    FIG. 3 now shows an operating circuit which represents the starting point of the present invention. Starting from input connections E1, E2, an alternating voltage AC is fed to the rectifier module 20, which is converted by the rectifier module 20 into a rectified alternating voltage. A control circuit SS evaluates the rectified AC voltage. For this purpose, the control circuit SS can have an adaptive detection circuit 1 and an evaluation circuit 2. Depending on the rectified AC voltage, the control circuit SS controls switching elements S1, S2, S3, which are set up to selectively bypass LEDs L1, L2, L3 provided by way of example in an LED path 5. To bypass the switching elements S1, S2, S3 are switched on and activated. Of course, the circuit can have fewer but also significantly more switching elements and LEDs. The switching elements are opened or closed depending on the current value of the voltage amplitude of the rectified AC voltage in order to guarantee a specified operating point of the load (AC-LED).
    [0048] A stream | through the LEDs L1, L2, L3 is regulated by a current source 4 which is controlled by the control circuit SS. The control circuit SS can thus achieve a dimming of the LEDs in that they adjust an amplitude of the current provided by the current source 4 | changes. In FIG. 3, the current I is consequently only fed to the LED path 5 with the serial LEDs L1, L2 and L3.
    FIG. 4 shows an operating circuit which is based on the operating circuit from FIG. 3, but has two parallel LED lines 5a, 5b. The two LED lines 5a, 5b are also shown here with 3 LEDs L1a, L2a, L3a or L1b, L2b, L3b each. Also shown are corresponding switching elements S1a, S2a, S3a or S1b, S2b, S3b, which can each selectively bypass the LEDs of the LED segments 5a, 5b. Again, it should be understood that more or fewer LEDs and switching elements can be provided per LED path 5a, 5b. Furthermore, a switching element can selectively bypass several LEDs. Transistors (bipolar, FET, MOSFET) can be used as switching elements.
    A control circuit SS1, which in turn has an adaptive detection circuit 1 and an evaluation circuit 2, is also shown. The adaptive detection circuit 1 detects phase information of the rectified AC voltage, i.e. in particular phase and / or phase segment duration and / or a sequence of phase and / or phase segment signals.
    len, which can be transmitted according to a digital signal protocol. The phase information can also be acquired from the supplied AC alternating voltage itself. The phase information is then evaluated by an evaluation circuit 2. The control circuit SS1 also controls two controllable current sources 4a and 4b as a function of the phase information. In particular, one of the current sources 4a and 4b is provided for each of the at least two LED lines 5a, 5b. Several LED lines can also be assigned to a power source. The control circuit SS1 can thus set a current through each of the two LED lines 5a, 5b separately. A total current Ic supplied to the two LED lines 5a, 5b is thus distributed to the LED lines 5a, 5b. The first current source 4a regulates, depending on the activation by the control circuit SS1, e.g. a current I through the first LED path 5a. The second current source 4b regulates, depending on the activation by the control circuit SS1, e.g. a current lcw through the second LED path 5b.
    For example, if only warm-white LEDs are provided in the first LED path 5a and only cold-white LEDs in the second LED path 5b, a white mixed light can be generated by controlling the power sources 4a and 4b that lies between the color temperature point of the first LED segment 5a and the color temperature point of the second LED segment 5b.
    Also indicated is an input of the control circuit SS1 via which information can be fed to the control circuit SS1 from an input circuit 6. The input circuit 6 represents a possibility of supplying further inputs to the control circuit SS1. For example, a potentiometer can be provided that explicitly specifies a setting for the color temperature value or an additional brightness dimming value. A fuse and / or a resistor can also be connected to the control circuit SS1, which, depending on its fuse or resistance value, define a color temperature value to be set. A color temperature value can be set at the time of production by connecting a resistor or a fuse to the evaluation circuit. Other signals, which specify a color temperature, can also be fed to the control circuit via input 6, e.g. bus signals from a bus, in particular DALI bus.
    The control of the switching elements S1a, S2a, S3a or S1b, S2b, S3b by the control circuit SS1 is shown schematically by dashed lines starting from the control circuit SS1 and the evaluation circuit 2.
    As further shown with a view to FIG. 5, which essentially corresponds to FIG. 4, it is not absolutely necessary to provide separate power sources for each at least one LED path. As shown in FIG. 5, an adjusting circuit 7 can also be provided in series with the at least two LED lines 5a, 5b.
    5 again shows only a single current source 4 '. A control circuit 7 now regulates the degree to which the at least two LED segments 5a, 5b are controlled, or how a total current Ic is divided between the LED segments 5a, 5b. The LEDs and switching elements of the LED lines essentially correspond to those from FIG. 4 and are not designated separately. The setting circuit 7 can set the distribution of the total current Ic over the at least two LED paths 5a, 5b.
    In particular, a control circuit SS2, which essentially corresponds to control circuit SS1, can output a signal to actuating circuit 7, for example, which signal specifies the division of total current Ic. This signal can be, for example, a pulse-width modulated square wave signal (PWM signal). This signal has an essentially constant period and oscillates between two different voltage levels. In principle, the signal is switched on and off in quick succession. The ratio of switch-on time to switch-off time can vary and be set by the control circuit SS2. The ratio is called the duty cycle. For example, by specifying the duty cycle by the control circuit SS2 and via the signal fed to the setting circuit 7, a color temperature for the LED sections 5a, 5b can be set. The switch-off period can specify the degree of dimming for the one LED segment 5a, while the switch-on period
    specifies the dimming level for the other LED line 5b.
    However, the LED paths can also be operated alternately according to the duty cycle. The control circuit SS2 can control the setting circuit 7 with the signal and thus define the duration for which the at least two LED segments 5a, 5b are to be switched on in each case. In particular, the switch-on duration of the PWM signal can, for example, specify the switch-on duration of a first LED path 5a and the switch-off duration the switch-on duration of the second LED path 5b. A flicker effect can be avoided by using a high frequency of the signal (preferably 100 Hz or higher).
    In particular, the control circuit 7 divides the total current I @ dynamically on the at least two LED paths into the currents Icw and Iww. In turn, the total current Ic is controlled by setting the current amplitude of the current source 4 '.
    The control circuit SS1, SS2 can therefore be shown in FIGS. 4 and 5, on the one hand, set the color temperature by dividing the total current Ic over the LED sections 5a, 5b, in the area between the color temperatures of the at least two LEDs. In addition, the brightness can also be dimmed by regulating the total current Ic.
    权利要求:
    Claims (10)
    [1]
    1. Operating circuit for operating LED routes, having
    - At least two parallel LED lines (5a, 5b), the LED lines (5a, 5b) being designed to emit light in the white spectrum, the LED lines (5a, 5b) differing in terms of the color temperature of their spectrum differ from each other, and
    - a control circuit (SS1, SS2) that can be supplied with an AC voltage and is designed to
    the LED lines (5a, 5b) with a rectified AC supply voltage and with a
    to supply a preferably adjustable total current (le), and where
    the control circuit (SS1, SS2) is set up to evaluate the AC voltage and, depending on phase information, such as phase control or phase control and / or a sequence of phase control signals and / or phase control signals of the AC voltage, a division of the total current (Ic ) to the parallel LED lines (5a, 5b).
    [2]
    2. Operating circuit according to claim 1, wherein the control circuit (SS1, SS2) is set up to divide the total current (Ic) onto the at least two parallel LED lines (5a, 5b) simultaneously or alternately.
    [3]
    3. Operating circuit according to claim 1 or 2, wherein the control circuit (SS1, SS2) controls at least two adjustable current sources (4a, 4b) depending on the evaluation of the phase information and the distribution of the total current (Ic) on the at least two parallel LED lines ( 5a, 5b) for each of the at least two parallel LED lines (5a, 5b).
    [4]
    4. Operating circuit according to claim 3, wherein in each case a power source (4a, 4b, 4 ') is arranged in series with at least one LED path (5a, 5b).
    [5]
    5. Operating circuit according to one of the preceding claims, wherein an adjustable current source (4a, 4b, 4 ') is assigned to at least one LED path (5a, 5b).
    [6]
    6. Operating circuit according to one of the preceding claims, wherein the operating circuit has an adjusting circuit (7), wherein the control circuit (SS1, SS2) is set up to control the adjusting circuit (7).
    [7]
    7. Operating circuit according to claim 6 or claim 6 and one of the preceding claims, wherein the control circuit (7) is set up to set the division of the total current (Ic) on the parallel LED lines (5a, 5b).
    [8]
    8. Operating circuit according to claim 6 or claim 6 and one of the preceding claims, wherein the control circuit (SS1, SS2) is set up to output a control signal to the setting circuit (7), and wherein the setting circuit (7) is set up as a function thereof a switch-on duration of the at least two different LED segments (5a, 5b) can be changed, and in particular alternately.
    [9]
    9. Light, LED lamp or LED module with an operating circuit according to one of the preceding claims.
    [10]
    10. Method for operating LED lines, wherein
    - at least two parallel LED lines (5a, 5b) emit light in the white spectrum and differ from one another with regard to the color temperature of their spectrum, and where
    - A control circuit (SS1, SS2) that can be supplied with an AC voltage supplies the LED lines (5a, 5b) with a rectified AC supply voltage and with a preferably adjustable total current (lc), and the control circuit (SS1, SS2) the Evaluates AC voltage and depending on phase information, such as Pha-
    phase control or phase control and / or a sequence of phase control signals and / or phase control signals of the AC voltage, a division of the total current (Ie) on the parallel LED lines.
    In addition 5 sheets of drawings
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    优先权:
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