AT500924A1 - BRIGHTNESS CONTROL OF LIGHTING DEVICES THROUGH MAIN AND SUB-POSITIONS - Google Patents

Description

Brightness control of lighting equipment via main and auxiliary stations

The invention relates to a brightness control according to the preamble of claim 1.

The main point HST of an installation is that point which is connected to the L-conductor of a mostly single-phase mains voltage and to the supply line to the lighting device, which is connected in series with the brightness control to the neutral conductor N. The extension NST is usually connected to the main station HST via the L-line and a further extension line NL. In pressure-change circuits main and extension are connected to each other via two corresponding lines. Examples of a lighting device are general-purpose incandescent lamps, HV halogen incandescent lamps or LV halogen incandescent lamps with electronic or conventional ballasts.

State of the art are brightness controls, in particular of lighting devices, which are equipped at the main and extension with a rocker switch, the type of control is determined by the operating length. Short actuation lengths from 0 ms to 50 ms are suppressed for noise suppression reasons. Operating lengths of 50 ms to 400 ms z. B. for alternating switching on and off of the operating state and operating lengths greater than 400 ms in contrast lead to a continuous dimming process. The dimming position z. B. monotonically increased until the maximum brightness is reached, there persisted for a short period of time before the dimming position is reduced until the dark position is reached and there after a likewise introduced retention time, the dimming direction is reversed again. However, the dimming direction and speed can not be influenced. Main and extension have the same functionality for the user. Offered, for example, as the main office of "Tast-dimmer for incandescent lamps", Article no. 245.07 of the company Albrecht Jung GmbH & Co. KG, PO Box 1320, 58569 Schalksmühle, Germany in the picture price list 99/1, page 7. As an extension, for example, the "extension for Tast-Dimmer", Article no. 231.07, ibid.

Furthermore, from DE 298 17 814 Ul private branch method known that fall back on a two-surface actuation and thus the dimming direction is clearly defined. The touch surface is divided into two areas. When the upper half is actuated, it is dimmed until the maximum brightness is reached. When the lower half is actuated, it is dimmed until the dark position is reached. The functional difference between dimming and switching is again achieved by the above-mentioned operating lengths. But even with double-surface actuation, the dimming speed is predetermined by the electronics.

In addition, dimmers are known with rotary actuator, which adjust the brightness with the help of a potentiometer. These devices are usually equipped with a pressure changeover switch to turn the lights off and on. The switchability of these devices is expandable by further pressure change and cross switch, which can turn on and off the lighting in cross and alternating circuits. A dimming process can only be performed by the main office.

In contrast, the object of the invention is to develop a more comfortable brightness control, which has the same operating functionality at the main and extension and which clearly defines the dimming direction, and determines the dimming speed variable. This object is achieved by the characterizing features of claim 1. Furthermore, according to the object, a remote control can be provided.

By experience with the handling of brightness controls of lighting devices, it has been found that the operation of the brightness control is advantageous to perform by a rotary actuator, since the operation is self-explanatory and the visual feedback by the lighting device is immediate and clear. Since the operation of a knob can be unambiguous and gross motor, while an operation of a split touch surface for direct Dimmrichtungsvorwahl must be fine motor and must pay attention to the control panel and the lighting device. To realize this one must ensure that the rotary actuator is no longer directly connected to a dimming position, as is the case with today's rotary dimmers with potentiometer and in which a certain position of the potentiometer always has a certain dimming position of the lighting device result. By way of illustration, a controller is assumed in which potentiometers with stops on the dimming position act on a main station and an extension. For example, if you dimmed at the extension, the entire position range would no longer be accessible with the potentiometer of the main station.

In the following, the function and operation of the invention will be described in more detail with reference to schematic representations:

FIG. 1 shows a lighting device with an incandescent lamp GL exemplified between the terminals LAST and N, a main point HST shown between the terminals L and LAST and an extension NST. The extension NST is connected to the main station HST via an extension line NL. Furthermore, the extension NST is connected depending on the embodiment with the phase L and / or the neutral conductor N of the low-voltage network as a reference conductor. When using the neutral conductor N as reference conductor, a multi-phase operation of main and extension is possible.

In Figure 2, the main point HST is explained and described in detail. The main station has a power supply unit SV, which supplies from the residual phase or section between the terminals L and LAST. For example, such a unit is described in DE 196 32 129 A1. The power unit LT contains at least one MOSFET, triac, thyristor or IGBT as a circuit breaker. The control unit SE includes at least the evaluation of the extension signal NL, the evaluation of the rotary actuator DBO and the control of the power unit LT. This can be done for example by a microcontroller. In the power unit LT and / or in the control unit SE, the radio interference suppression must also be realized. The rotary actuating element DBO according to the invention can be designed either as an incremental encoder or as an endless locomotive. The change of the switching state can then z. B. be executed by an additional tactile contact of a switching actuator SBO. Instead of using a Schaltbetätigungsorgans SBO and solutions are possible in which the rotary actuator is used in addition to off and on.

FIG. 3 explains the mode of operation of a preferred incremental encoder. Incremental encoders are actuators which have two or more switching outputs, which are further processed, for example, by means of microcontrollers. In one revolution, for example, 30 pulses are present at each switching output. Incremental encoders are available in latching and non-latching versions. Figure 3 indicates the signals of the switching outputs A and B over time with uniform rotational movement in a clockwise direction. From the fact that the signals at switching output A before the signal at switching output B changes, a microcontroller can determine that the incremental encoder is actuated clockwise. When pressed counterclockwise, the signal at the switching output A would change to the signal at the switching output B. The rotational speed of the incremental encoder can be determined by a microcontroller on the basis of the time between input and output of a switching output. In Figure 3 also detent positions 1 to 6 are shown in dashed lines.

The extension NST is executed with the same actuator as the main point HST and then transmits the information to be executed via the extension line. This can be realized by known signal transmission methods, in which the signal of the control line is clocked and / or encoded in current or voltage level. As information, the dimming direction and its speed change and the change of the switching state must be transmitted.

By a rotary actuation of the inventive Drehbetätigungsorganr DBO in the off state, it is possible to preset certain values during subsequent power-up. For example, by a defined small left rotation with subsequent switching on the minimum dimming value and called by a defined small clockwise rotation and subsequent switching the maximum dimming value called, while switching on without turning the dimming value is called again, which was set before the last power off.

Moreover, it is possible to remotely control the brightness control of lighting devices. This is possible in principle by an extension of the main station HST, by an extension of the described extension with rotary actuator or by introducing an independent remote control extension without manual control unit. To do this, the remote control receiver included in the remote control unit must evaluate the remote control signal. Both radio remote controls and infrared or ultrasonic remote controls are conceivable. In the case of a fembedienbaren extension this must convert the Fembedienungssignal in an extension signal NL, which can be evaluated by the main office. The parallel operation of manually operated and remote-controlled extensions is ensured with appropriate design of the telegram on the branch line NL.

Claims (6)

1. Brightness control of lighting devices by a phase or 10 phase control with Abstellenfahigkeit, characterized in that for brightness control at main office (HST) and extension (NST) a rotary actuator (DBO) is provided, which is executed as an incremental encoder or as Endlospotentiometer. 2. brightness control of lighting devices according to claim 1, characterized in that for the evaluation of the rotary actuator (DBO) preferably a microcontroller is used. 3. Brightness control of lighting devices according to claim 1, characterized in that the private branching capability is ensured by a single private branch line (NL) between the private branch exchange (NST) and the main branch (HST), the reference phase being the phase (L) or the neutral conductor (N). is being used. 4. Brightness control of lighting devices according to claim 1 and 3, characterized 25 characterized in that the operation of the main office and the extension or the extensions at different phases of the reference conductor between the main office (HST) and extension (NST) of the neutral conductor (N). 5. brightness control of lighting devices according to claim 1, characterized 30 characterized in that by a left-hand rotation of the rotary actuator (DBO) to a defined, small angle and subsequent switching on the lighting is turned on at minimum brightness, and that by a clockwise rotation of the rotary actuator (DBO) to a defined, small angle and then switching on the lighting is turned on at maximum brightness. 35 6. brightness control of lighting devices according to claim 1, 3 and 4, characterized in that a device is used as an extension (NST), which contains a receiver for a radio, infrared or ultrasonic remote control and which can be evaluated by the main office (HST) Extension signal (NL) generated. 40 45 50