DE10025368A1 - dimmer - Google Patents

Abstract

Dimmer for adjusting the brightness of lighting devices with a circuit breaker (7) for switching a load circuit within a dimming phase angle range, an adjusting device (14) for setting a dimming phase angle and with a control device (12) for controlling the circuit breaker (7) as a function of one set by the adjusting device (14) dimming phase angle or a transmitted dimming control command.

Description

The invention relates to a dimmer for controlling a load, especially for brightness control of lighting equipment exercises.

Dimmers are brightness controls for lighting fixtures. Dim mer allow the setting of many different technical facilities, especially lighting directions connected to an AC mains voltage are. In the case of lighting devices, an adjustable one Brightness value used to at least one semiconductor scarf to control. It is either by phase control or  A desired rms value of the voltage posed. With the leading edge and with the leading edge incision control method is e.g. B. the respective zero crossing the AC line voltage is detected and used to control the half ladder switch.

For simultaneous dimming of several separate lights tion load circuits, for example for different rooms mer, or for driving a load with a very high Consumer power, it is necessary to use one dimmer Connect dimmer systems in parallel. Conventional dimmersys systems work as master-slave dimmer systems, in which ei the settings are made and the master dimmer slave dimmers connected to the master dimmer in their Follow the function of the master dimmer.

A disadvantage of such conventional dimmer systems is in that the master dimmer and the slave dimmer one under have different circuit design, so that the Master dimmers and slave dimmers during installation are not are interchangeable. This will complete the installation considerably more difficult and installation errors occur more frequently on.

Another disadvantage of such dimmer systems is that that the settings are made centrally on the master dimmer so that if the master dimmer fails, the entire dim system fails.

In addition, the dimmer settings can only be made on the Mas ter dimmer and not on the other dimmers the.  

Since different dim unit types are manufactured, the unit costs are also Production of the dimmers relatively high.

It is therefore the object of the present invention, a Dimmer to adjust the brightness of lighting fixtures create that avoids the disadvantages mentioned above and with other identical dimmers to increase performance to a common load or for simultaneous dimming of separate load circuits can be connected in parallel.

This object is achieved by a dimmer with the Features specified in claim 1 solved.

The invention creates a dimmer
a circuit breaker for switching a load circuit within a dimming phase angle range,
an adjusting device for adjusting a dimming phase angle, and with
a control device for controlling the circuit breaker as a function of a dimming phase angle set by the setting device or a transmitted dimming control command.

Preferred embodiments of the dimmer according to the invention Brightness settings are specified in the subclaims.

Preferred embodiments of the invention are described below dimmers according to the invention to explain more essential to the invention Features with reference to the accompanying figures wrote.

Show it:  

Fig. 1 shows a first embodiment of the dim mer according to the invention for brightness adjustment as a two-wire dimmer with a phase input connection and a phase output connection;

Fig. 2 shows a second embodiment of the dimmer according to the invention as a three-wire dimmer with a phase input, a phase output and a zero lead;

Fig. 3 is a parallel connection of several erfindungsge MAESSEN two-wire dimmers for power extension;

Figure 4 is a parallel connection of several erfindungsge MAESSEN two-wire dimmers for dimming of separate load circuits.

FIG. 5 shows the second embodiment tung Enhancements a parallel connection of a plurality of three-wire dimmer according to Leis;

Fig. 6 shows a parallel connection of several fiction, contemporary three-wire dimmers for dimming several ge separate load circuits.

Fig. 1 shows a first embodiment of the dimmer 1 according to the invention as a two-wire dimmer with a phase input terminal 2 and a phase output terminal 3rd

The phase input connection 2 is connected via a line 4 to a power supply device 5 , which is connected via a line 6 to the phase output connection 3 . At the phase input terminal 2 and the phase output terminal 3 , a circuit breaker 7 is also connected, which is connected to the line 4 via a power line 8 at a node 9 . Furthermore, the circuit breaker 7 is connected to the phase output terminal 3 via a line 10 . The power switch 7 can be controlled via a control line 11 by a control device 12 . Depending on the control signal applied to the control line 11 , the power switch 7 switches the AC voltage present at the phase input terminal 2 to the phase output terminal 3 . The power switch 7 is a controllable semiconductor switch, in particular a MOSFET, an IGBT or a triac. The control device 12 contained in the dimmer 1 is provided by the power supply device 5 via a line 13 with current ver. The power supply device 5 preferably contains a phase-zero crossing detection circuit which detects a zero crossing of the applied AC voltage. The detected phase zero crossing is evaluated for triggering the control device 12 . The power supply device 5 also contains a capacitor in which an electrical charge for generating the power supply for the control device 12 is stored.

The AC voltage applied to the power supply device 5 via the line 4 preferably has a frequency of 50 Hz, this corresponding to a period of 20 ms. The AC voltage applied to the phase input terminal 2 is sinusoidal, with a half-wave being divided into a phase residual angle range and a dimming phase angle range. The dimming phase angle range preferably extends from a lower phase angle, which is, for example, 35 °, to an upper phase angle, which is, for example, 152 °. The dimming phase angle range lies approximately in the middle of a sinusoidal half wave of the mains voltage, the first section of the sinusoidal half wave, which for example ranges from 0 ° to 35 °, and the third section of the sinusoidal half wave, which is for example from 152 ° to 180 ° is sufficient to generate the supply voltage by the power supply device 5 . The middle dimming phase angle range, which for example ranges from 35 ° to 152 °, is used to adjust the brightness using the dimmer. The dimming phase angle is set within the dimming phase angle range. The minimum adjustable dimming phase angle is, for example, 35 °, while the maximum adjustable dimming phase angle is 152 °. The higher the dimming phase angle is set, the brighter a lighting fixture shines, which is connected to the phase output connection 3 .

The dimming phase angle is set by an adjusting device 14 , in which the phase angle is preferably manually adjustable by means of a potentiometer 15 . Alternatively, the setting can also be made by a rotary pulse generator or capacitively. The setting device 14 is connected via a line 16 to a first input of the control device 12 . The control device 12 is preferably a microcontroller with multiple inputs. By setting the potentiometer 15 , for example, the charging time of a capacitor within the setting device 14 is influenced, which is read out by the microcomputer 12 . The control device 12 converts the set potentiometer terwert into a brightness value, which is given as a control signal via the line 11 to the circuit breaker 7 .

The setting device 14 is also connected via a line 17 to a sensor surface, for example a metallic sensor surface 18 . When touching the sensor surface 18 he follows the dimming process cyclically, ie the dimmer increases the brightness up to a maximum value and lowers the brightness after reaching the maximum value until reaching a minimum brightness value.

The control device 12 is connected at a second input via a line 19 to a protective circuit 20 , which in turn is connected via a line 21 to a control input 22 of the dimmer 1 .

At a third input, the control device 12 is connected via ei ne line 23 to a further protective circuit 24 which is connected via a line 25 to an extension input 26 of the dimmer 1 . Via the extension input 26 , the dimmer 1 can be connected to an extension for operating the dimer 1 .

The protective circuits 20 , 24 serve to protect the control device 12 against overvoltages or excessive currents which are present at the control input 22 or the extension input 26 . In addition, the protective circuits 20 , 24 perform signal adjustments for the control circuit 12 . The protective circuits 20 , 24 preferably also contain filter circuits for signal interference suppression.

The control device 12 controls the circuit breaker 7 as a function of a dimming phase angle set by the setting device 14 or a transmitted dimming control command. If the setting of the dimming-phase angle occurs at a remote dimmer connected to the dimmer 1 , the dimmer 1 receives at its control input 22 a dimming control command which is sent via line 21 , protective circuit 20 and line 19 to the control device 12 will wear. The received dimming control command is preferably a digital control command that is decoded by the control device 12 . The circuit breaker 7 is controlled as a function of the decoded dimming control command.

If the setting of the dimming phase angle is carried out by an adjusting device 14 of the dimmer 1 , the control device 12 generates a corresponding dimming control command by changing the set phase angle, which is transmitted via the control input 22 to the other connected dimmers. Dimming control commands are exchanged bidirectionally with other dimmers via the control input 22 of the dimmer 1 . The various dimmers have equal rights and can send and receive dimmer control commands. The brightness can be set on any dimmer that sends the corresponding dimmer control commands to the other dimmers. The dimmer control commands contain information data regarding the desired phase angle.

Fig. 2 shows a second embodiment of the dimmer 1 according to the invention for adjusting the brightness. In the embodiment shown in FIG. 2, the dimmer 1 has, in addition to the phase input terminal 2 and the phase output terminal 3, a neutral conductor connection 27 . The neutral conductor connection 27 serves to connect the dimmer 1 to a mains neutral conductor. The neutral conductor 27 is connected via a line 28 to the power supply device 5 . Furthermore, the power switch 7 is connected via a line 29 at a node 30 to the Lei device 28 .

Since the power supply device 5 can be connected to the mains AC voltage via the phase input terminal 2 and the neutral conductor 27 , the possible dimming phase angle range in the embodiment shown in FIG. 2 can be used as a three-wire dimmer compared to the first embodiment shown in FIG. 1 as Two-wire dimmers are expanded. In contrast, the embodiment shown in FIG. 1 of the dimmer 1 according to the invention has the advantage that it has only one phase input connection 2 and one phase output connection 3 and is therefore particularly suitable for retrofitting. An already installed button for controlling a lighting device can be easily replaced by the two-wire dimmer shown in FIG. 1.

Fig. 3 shows an interconnection of several two-wire dimmer according to the first embodiment for performance enhancement. With their phase input connections 2, the dimmers 1 rest on a mains phase line 32 via phase lines 31 . At the extension inputs 26 of the dimmers 1 , a control button 34 is connected by means of a line 33 , which is applied to the line phase line 32 via a line 35 . The phase output connections 3 of the dimmers are connected in parallel via lines 36 to a common voltage node 37 . Between a net neutral conductor 38 and the node 37 is a load 39 , which can be, for example, a lighting body. The control inputs 22 of the dimmers 1 are connected to one another via control lines 40 . Via the control lines 40 , the dimmers 1 exchange control commands for adjusting the brightness of the lighting fixture 39 . The brightness can be set on any of the n two-wire dimmers.

The individual dimmers are actuated by the control buttons 34 . In this case, the dimmer 1 detects the duration of an actuation signal present at the auxiliary input 26 . In a preferred embodiment, the duration of the actuation signal is less than 50 ms, the dimmer ignores this signal as an interference signal. If the duration of the actuation signal is in a range between 50 ms and 400 ms, the dimmer 1 carries out a switching process. When the dimmer 1 is in its switched on state, it switches on due to the actuation signal present. If the dimmer 1 is in the switched-on state and the duration of the applied actuation signal is between 50 and 400 ms, the dimmer switches off. If the actuation signal is present at the extension input 26 of the dimmer 1 for more than 400 ms, the dimmer performs a dimming process, for example the brightness of the connected lighting device 39 being increased for the duration of the applied actuation signal until a maximum brightness value is reached.

Through the parallel connection shown in FIG. 3 different ner similar dimmers 1-1 to 1-n, it is possible to dim a lighting device 39 , the power consumption of which is above the power of the individual dimmers 1 . In a preferred embodiment of the dimmer 1 according to the invention, this is constructed as a flush-mounted dimmer with an output of 400 watts. By connecting n dimmers in parallel, it is possible to dim lighting devices with a power consumption of up to n × 400 watts.

Fig. 4 shows a further connection possibility of the two-wire dimmer 1 according to the invention, as shown in Fig. 1. In the parallel connection shown in Fig. 4, it is possible to have different separate load circuits with different lighting devices 39-1, 39-2,. , , 39-n to dim at the same time. For example, the various lighting devices 39-1 to 39-n are located in different rooms of a building, the brightness of the various rooms being adjusted by adjusting the phase angle of one of the dimmers 1-1 to 1-n. The dimmer 1 , at which the phase angle or the brightness is set, generates dimmer control commands and emits these control commands via the control lines 40 to the other dimmers in the other rooms of the building. These dimmers then dim the corresponding lighting device.

Fig. 5 shows a parallel connection of several three-wire dimmers according to the second embodiment of the inventive dimmer 1 , as shown in Fig. 2. The parallel connection of the three-wire dimmer 1 shown in FIG. 5 makes it possible to dim an illuminating device 39 , the power consumption of which is significantly higher than the power of an individual dimmer 1 . The circuit shown in Fig. 5 largely corresponds to the circuit shown in Fig. 3 for two-wire dimmers, but in addition, the Nulleiteran connections 27 of the different dimmers via connecting lines 41 are connected in parallel to the mains neutral 38 .

Fig. 6 shows a further parallel connection of several three wire dimmers 1 according to the second embodiment, as shown in Fig. 2. With the circuit shown in FIG. 6, it is possible to dim various separate load current circuits simultaneously by means of the three-wire dimmer 1 . The circuit shown in FIG. 6 largely corresponds to the parallel circuit shown in FIG. 4, but in addition the neutral conductor connections 27 of the dimmer 1 are present at the neutral conductor 38 .

The dimmer 1 according to the invention can be interconnected with other identical dimmers to build a dimmer system. The brightness can be adjusted on any dimmer. Since all dimmers are constructed identically and have identical connections, the installation of the dimmers is very easy. The parallel connection shown in FIGS. 4 and 6 makes it possible to control different separate load circuits by means of a single dimmer. If one dimmer fails, the remaining dimmers can continue to work, so that there is no failure of the entire dimmer system.

Claims (15)

1. dimmer with
a circuit breaker ( 7 ) for switching a load circuit within a dimming phase angle range,
an adjusting device ( 14 ) for adjusting a dimming phase angle, and with
a control device ( 12 ) for controlling the circuit breaker ( 7 ) as a function of a dimming phase angle set by the setting device ( 14 ) or a transmitted dimming control command. 2. Dimmer according to claim 1, characterized in that the control device ( 12 ) exchanges dimming control commands with further dimmers via a control input ( 22 ). 3. Dimmer according to claim 1 or 2, characterized in that the control device ( 12 ) generates a corresponding dimming control command when changing the set phase angle, which is transmitted via the control input ( 22 ) to other dimmers. 4. Dimmer according to one of the preceding claims, characterized in that a power supply device ( 5 ) for generating a power supply for the control device ( 12 ) is provided. 5. Dimmer according to one of the preceding claims, characterized in that the power supply device ( 5 ) has a capacitor for storing electrical energy. 6. Dimmer according to one of the preceding claims, characterized in that the dimmer ( 1 ) has an extension input ( 26 ) for connecting an operating button ( 34 ). 7. Dimmer according to one of the preceding claims, characterized in that the adjusting device ( 14 ) is connected to a sensor surface, a light barrier, a button or to a rotary pulse generator. 8. Dimmer according to one of the preceding claims, characterized in that the dimmer has a phase input connection ( 2 ) for connection to an AC voltage and a phase output connection ( 3 ) for connection to a load ( 39 ). 9. Dimmer according to claim 8, characterized in that the power supply device ( 5 ) to the phase input connection ( 2 ) and to the phase output connection ( 3 ) is connected. 10. Dimmer according to one of the preceding claims 1 to 7, characterized in that the dimmer ( 1 ) has a phase input connection ( 2 ) for connection to an AC voltage, a phase output connection ( 3 ) for connection to a load ( 39 ) and a neutral connection ( 27 ) for connection to a neutral conductor ( 38 ). 11. Dimmer according to claim 10, characterized in that the power supply device ( 5 ) to the phase input connection ( 2 ) and to the neutral conductor connection ( 27 ) is connected. 12. Dimmer according to one of the preceding claims, characterized in that the power supply device ( 5 ) has a circuit for triggering the control device ( 12 ). 13. Dimmer according to one of the preceding claims, characterized in that at the control input ( 22 ) and the extension input ( 26 ) in each case a limiting circuit ( 20 , 24 ) is provided to protect the control device ( 12 ) against overvoltages and excessive currents. 14. Dimmer according to one of the preceding claims, characterized in that the control input ( 22 ) and the extension input ( 26 ) each have an adaptation circuit for adjusting the voltage level for the control device ( 12 ). 15. Dimmer according to one of the preceding claims, characterized in that the power switch ( 7 ) is a MOSFET, an IGBT or a triac.