DE102011086446A1 - User controller for e.g. organic LED in LED illumination system for colored illumination of rooms, has sensor device connected with driver circuit for LED by interface and enabling contact-less control of brightness and color of LED - Google Patents

Abstract

The controller has a sensor device connected with a driver circuit for an LED by an interface i.e. Digital Addressable Lighting Interface. A color-changing LED is controlled by the driver circuit. The sensor device enables contact-less control of brightness and color of the LED by evaluating capacitive coupling, and the brightness and color of the led are adjusted based on the coupling. The driver circuit comprises a control circuit (U1) that changes frequency and/or switching characteristics during control of a switch (S1). An independent claim is also included for a method for controlling an LED.

Description

The invention relates to a user control for an LED via a driver circuit according to the preamble of patent claim 1 and a method for driving an LED according to the preamble of patent claim 19.

Technical area

Such driver circuits are used in lighting systems to achieve a colored or flat lighting of rooms, paths or escape routes. Usually, the bulbs are driven by operating devices and activated as needed. For such illumination, organic or inorganic light emitting diodes (LED) are used as the light source.

State of the art

For lighting, instead of gas discharge lamps and incandescent lamps, light-emitting diodes are also increasingly being used as the light source. The efficiency and luminous efficacy of light-emitting diodes is being increased more and more so that they are already being used in various general lighting applications. However, light emitting diodes are point sources of light and emit highly concentrated light.

However, today's LED lighting systems often have the disadvantage that the color output or the brightness can change as a result of aging or by replacement of individual LEDs or LED modules. In addition, the secondary optics has an impact on the thermal management, as the heat radiation is hindered.

In addition, it may come due to aging and heat to a change in the phosphor of the LED.

A change in brightness is often only possible with a complex control circuit, or it is not readily possible to influence brightness and color.

Presentation of the invention

It is the object of the invention to provide a luminous means and a method which enables a trouble-free and energy-saving operation by a light emitting diode with light-emitting diodes without the above-mentioned disadvantages or with a significant reduction of these disadvantages.

This object is achieved according to the invention for a generic device by the characterizing features of claim 1. Particularly advantageous embodiments of the invention are described in the subclaims.

The solution according to the invention for a device for operating LEDs (organic or inorganic light-emitting diodes) is based on the idea that a driver circuit for an LED has a connection for a mains voltage, a filter circuit and a rectifier, an inductance and a switch.

The inductor is magnetized when the switch is closed, and the inductor is demagnetized when the switch is open, and at least during the demagnetization phase, the current through the inductor feeds the LED.

The solution according to the invention relates to a user control for an LED, comprising a sensor device which is connected to a driver circuit for a LED via an interface,
wherein at least one color variable LED is driven by the driver circuit,
wherein the sensor device enables non-contact control of the brightness and the color of the LED.

The solution according to the invention also relates to a method for driving an LED, wherein the LED is driven via a driver circuit and the driver circuit receives signals from a sensor device via an interface,
wherein a touch-free control of the brightness and the color of the LED is made possible by means of a sensor device.

The solution according to the invention also relates to a luminous means for an LED, with a base for the use of the luminous means in a commercial lamp base, comprising a driver circuit according to the invention are formed.

In this way, it is possible to achieve a very consistent and uniform illumination of a surface by means of a luminous means with light-emitting diodes, which is controllable in a simple way in the brightness.

Description of the preferred embodiments

The invention will be explained in more detail with reference to the accompanying drawings. Show it:

1 shows a first embodiment of a device according to the invention

2 shows a second embodiment of a device according to the invention

3 shows a further embodiment of a device according to the invention

The invention is based on a first embodiment according to 1 explained with a driver circuit for an LED.

The driver circuit has a connection for a mains voltage, which is followed by a rectifier GR1 and a filter circuit L1 and a buffer element. This is followed by an inductance L2 and a switch S1.

The inductance L2 is magnetized when the switch S1 is closed, and the inductance L2 is demagnetized when the switch S1 is opened, and at least during the demagnetization phase, the current through the inductance L2 feeds the LED.

The switch S1 is always opened only when the current through the switch S1 has reached a predetermined threshold. The current through the switch S1 can be detected by means of a current detection Ip (for example, a current shunt).

The turn-off duration of the switch S1 may be dependent on the detected amplitude of the current through the LED.

The switch-off duration of the switch S1 can be dependent on the degaussing current.

The driver circuit may optionally be additionally connected to a commercially available dimmer, and the switch S1 may be closed during the phases in which the dimmer cuts off a portion of the phase to carry a residual current through the inductor and the switch S1 and thus the dimmer to charge.

The switch S1 can be switched on whenever a demagnetization of the inductance is detected. However, it is always possible to switch on only when the inductance has been de-magnetized, and it may also take a certain amount of time between the time of demagnetization and restarting.

The inductance may be a transformer that serves as a potential-separating member. The predetermined threshold may depend on the current amplitude of the supply voltage. In a simple variant, for example, if the supply voltage exceeds a certain value, an increase of the threshold value can take place.

The inductance can feed a smoothing circuit during its demagnetization, this smoothing circuit can be, for example, a capacitor or an LC or CLC filter.

Thus, a light source for an LED can be formed, with a base for use of the light source in a commercially available lamp base, comprising a driver circuit according to the invention.

The buffer element can be implemented by a valley fill circuit or else by a smoothing capacitor C1 (FIG. 1 ) are formed.

The switch S1 can be switched on whenever a demagnetization of the inductance L2 is detected. However, a switch-on can always take place only when the inductance L2 is de-magnetized, and a certain period of time can also be between the time of demagnetization and the restarting.

The switch S1 can be driven, for example, by an integrated circuit for a power factor correction. The monitoring circuit U1 may include a power factor correction control circuit.

The inductance L2 may be a transformer L2p, L2s, which serves as a potential-separating member. In this case, the primary winding L2p of the transformer is connected in series with the switch S1. The secondary winding L2s magnetically coupled to the primary winding L2p is connected to a rectifier (D2) and a smoothing circuit (C2) to which the LED can be connected. The rectifier (D2) on the secondary winding L2s of the transformer can be formed by a diode D2 or by a full-wave rectifier.

The on and / or off duration of the switch S1 may be dependent on the detected amplitude of the current through the LED. Preferably, however, the switch-on and / or switch-off duration of the switch S1 does not decrease to zero or close to zero.

In a simple variant, for example, a limitation of the current through the LED can be done by limiting the duty cycle.

The inductance L2 can feed a smoothing circuit (C2) during its demagnetization, this smoothing circuit (C2) can be, for example, a capacitor C2 or an LC or CLC filter.

The invention will be described with reference to a further embodiment according to 3 explained.

Thus, a light source for an LED can be constructed, with a base used of the luminous means in a commercially available lamp cap, comprising a driver circuit according to the invention.

In 2 Another driving option for a driver circuit for an LED is shown. Here, alternatively (or additionally) to the grid-connected control by means of a dimmer, a non-contact control.

A driver circuit for an LED is provided, comprising a connection for a mains voltage, a rectifier (GR1) and a filter circuit (L1), a buffer element, an inductance (L2) and at least one switch (S1, S2), the inductance ( L2) by high-frequency clocking of the switch (S1, S2) is up-demagnetized and the inductance (L2) feeds the LED, the switch (S1, S2) is controlled by a control circuit (U1), wherein the control circuit (U1) via an interface is coupled to a sensor device, and the sensor device enables non-contact control of the brightness and the color of the LED.

The change in the color of the LED can also mean the color temperature of the LED. For example, you can switch between a cold white and a warm white tone. The color-changeable LED can be, for example, a multi-chip module which has at least two LEDs of different colors. However, the color change can be done, for example, by activating filters or phosphor layers in the light exit region of the LED or by a mixed control of different LED and color filters. But it can also be adapted to the operation of a single LED, for example, can be changed between an amplitude modulation and pulse modulation.

The contactless control of the sensor device can be done by an inductive coupling or a distance measurement according to the radar principle.

The contactless control of the sensor device can be carried out by an evaluation of a capacitive coupling and depending on the capacitive coupling, the brightness of the driver circuit by changing the drive signal of the switch (S1, S2) by the control circuit be adjustable.

The capacitive coupling can be done by a hand movement, preferably in the vicinity of the driver circuit or the LED light.

The sensor device (SV) may have a first capacitance that can change its charge due to a capacitive coupling (to change the brightness).

The sensor device (SV) evaluates the capacitive coupling based on a comparison measurement between the first capacitance and a reference capacitance.

Depending on the comparison measurement between the first capacitance and a reference capacitance, the sensor device can output the capacitive coupling an evaluation signal, which is evaluated by the control circuit (U1).

Depending on the monitored evaluation signal of the sensor device, the control circuit (U1) can change the frequency and / or the duty cycle when the switch (S1, S2) is activated.

By means of the evaluation of the capacitive coupling, the sensor device can evaluate a (detected) hand movement as a control signal.

The detected hand movement can be evaluated in terms of their duration and this period can be evaluated as information for the desired change in the brightness of the LED.

The detected hand movement can be evaluated in terms of its intensity (the movement) and this intensity can be evaluated as information for the desired change in the brightness of the LED. The detected hand movement can alternatively or additionally be evaluated as information for the desired change in the color of the LED.

The interface can be designed as a digital interface, in particular DALI interface, or as a wireless interface. The inductance (L2) can feed a smoothing circuit (C2) during its demagnetization. The inductance (L2) may have a secondary winding. The clocked inductor L2 of the driver circuit has a secondary winding L2s which is magnetically coupled to the primary winding L2p of the inductor L2.

The driver circuit can be designed as isolated flyback converter. The driver circuit can also be designed as a resonant and isolated half-bridge converter having two controllable switches S1 and S2.

Thus, a light source for an LED can be constructed, with a base for the use of the light source in a commercially available lamp base, comprising a driver circuit according to the invention.

Thus, a method for driving an LED is made possible, wherein the LED is controlled by a driver circuit, wherein a sensor device, a non-contact control of the brightness of the driver circuit is made possible.

The contactless control can be carried out by an evaluation of a capacitive coupling and depending on the capacitive coupling, the brightness of the driver circuit be adjustable.

A driver circuit for a luminous means, preferably for an LED, comprising a connection for a mains voltage, a rectifier GR1 and a filter circuit, a buffer element (C1), an inductance L2 and a switch S1 can also be formed, wherein the high-frequency clocking of the Switch S1 energy can be transmitted via the inductance to the lamp, and at the output of the rectifier GR1 may be a bridging circuit (R40, Q4) is present, which is activated when the lamp (LED) is not in operation. This may be the case, for example, when no mains voltage is applied. The bridging circuit (R40, Q4) can thus be designed so that it is only deactivated when the light source (LED) is operated. In this way, a better compatibility with so-called Netzfreischaltern can be achieved.

In addition, during operation of the light source, the bypass circuit (R40, Q4) can only be deactivated in the phases when a current flow through the current detector is detected.

In the following example, the setting of the brightness and color (color temperature) of a white light lamp, for example, with white light LED will be explained, 3 shows by way of example a possible a control element for lighting control according to the invention.

The operating element as a sensor device is attached to the wall like a light switch. The user positions one of his hands centrally in front of the control element, thereby activating the adjustment process.

The top / bottom position determines the brightness:
The more the hand is moved up, the brighter the light becomes.
The more the hand is moved down, the darker the light becomes.

In addition, the right / left position determines the color temperature:
The further the hand is moved to the left, the colder the light color becomes.
The further the hand is moved to the left, the warmer the light color becomes.

When the desired setting is found, holding the position for an adjustable duration causes the setting in the lighting control system to be stored (i.e., transmission of the detected information via the interface). Then the hand can be removed from the detection area without changing the lighting.

As soon as the sensor device has detected a new specification or change by the user, it transmits a corresponding signal to the at least one driver circuit via the interface, whereupon the color-changeable LED is activated in a modified form by the driver circuit. It can also be switched off or bypassed individual LED.

The control element may be attached to a wall or integrated there, for example.

It can therefore be integrated into a control element for light control, which is equipped with a microcontroller, the above-mentioned sensor device and evaluated on the hand position of the user.

The position evaluation can be done in three dimensions:
Vertical (Y)
Horizontal (X)
Distance to the operating element (Z)

From the relationships between the three dimensions, the microcontroller calculates the position of the hand, including the severity, and converts the position information into light control commands that are sent to the luminaires with digital bus interface via the light control system (the interface).

However, the light source can also be a combination of different light sources such as LED and gas discharge lamps are formed.

The driver circuit, which controls the connected lighting means, such as one or more LEDs, may also be spatially separated from the lighting means. For example, the operating device is arranged with one or more driver circuits in a housing and connected via a wiring to the lighting means.

It can thus be formed according to the invention, a light source for an LED, with a base for using the light source in a commercial lamp base, controllable by a user control according to the invention.

Claims (18)

User control for an LED, comprising a sensor device which is connected to a driver circuit for a LED via an interface, wherein at least one color variable LED is driven by the driver circuit, characterized in that the sensor device allows non-contact control of the brightness and the color of the LED , User control for an LED, according to claim 1, characterized in that the non-contact control of the sensor device is carried out by an evaluation of a capacitive coupling and depending on the capacitive coupling, the brightness and the color of the LED is adjustable. User control for an LED, according to claim 2, characterized in that the capacitive coupling can be done by a hand movement, preferably in the vicinity of the sensor device or the LED lamp. User control for an LED, according to claim 2, characterized in that the sensor device has a first capacitance, which can change its charge due to a capacitive coupling (to change the brightness). User control for an LED, according to one of claims 1 to 4, characterized in that sensor device evaluates the capacitive coupling based on a comparison measurement between the first capacitance and a reference capacitance. User control for an LED, according to one of claims 1 to 5, characterized in that sensor device outputs the capacitive coupling depending on the comparison measurement between the first capacitance and a reference capacitance, an evaluation signal, which is transmitted via the interface to the driver circuit. User control for an LED, according to one of claims 1 to 5, characterized in that the driver circuit comprises a control circuit (U1) and the control circuit (U1) depending on the transmitted evaluation signal of the sensor device, the frequency and / or the duty cycle in the control of the switch (S1, S2) changes. User control for an LED, according to one of claims 1 to 7, characterized in that the sensor device by means of the evaluation of the capacitive coupling can evaluate a (detected) hand movement as a control signal. User control for an LED, according to one of claims 1 to 8, characterized in that the detected hand movement can be evaluated in terms of their duration and this time period can be evaluated as information for the desired change in the brightness of the LED. User control for an LED, according to one of claims 1 to 9, characterized in that the detected hand movement can be evaluated in terms of their intensity (the movement) and this intensity can be evaluated as information for the desired change in the brightness of the LED. User control for an LED, according to one of claims 1 to 10, characterized in that the detected hand movement can be evaluated alternatively or additionally as information for the desired change in the color of the LED User control for an LED according to one of claims 1 to 11, characterized in that the driver circuit is designed as an isolated flyback converter. User control for an LED, according to one of claims 1 to 12, characterized in that the driver circuit is designed as a resonant and isolated half-bridge converter. User control for an LED, according to one of claims 1 to 13, characterized in that the interface is designed as a digital interface, in particular DALI interface. User control for an LED, according to one of claims 1 to 14, characterized in that the interface is designed as a wireless interface. User control for an LED, with a socket for use of the illuminant in a commercial lamp base, comprising a driver circuit according to one of the preceding claims. Method for driving an LED, wherein the LED is driven via a driver circuit and the driver circuit receives signals from a sensor device via an interface, wherein a touch-free control of the brightness and the color of the LED is made possible by a sensor device. The method of claim 17, wherein the non-contact control is performed by an evaluation of a capacitive coupling and depending on the capacitive coupling the brightness and the color of the LED is adjustable.

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