DE2702490A1 - Brightness control for fluorescent lamps - has parallel switch with diac and triac controlling operation time and heating current - Google Patents

Abstract

The device comprises a series impedance limiting the lamp current, and an electronic switch in parallel with the lamp, periodically opened and closed for control of its burning time and heating current. The parallel switch (P) comprises a triac with a series impedance (R1), a diac (D) and an RC circuit (C1, R3, R4) for generation of the ignition voltage for the diac (D) or the triac (T). The parallel switch (P) has further a starter circuit (ST), consisting of an RC circuit (R2, C2) in parallel with the triac (T) and its series impedance (R1) and a glow discharge lamp (G) between the junction point of resistor (R2) and capacitor (C2) and diac (D). Resistor (R4) generating the diac ignition voltage is a potentiometer mounted together with a switch (N) in a separate control unit (S) and connected by a wire (Vd) to the switch (P).

Description

Brightness control device for

Fluorescent lamps The present invention relates to a brightness control device for fluorescent lamps, containing a series impedance to limit the lamp current and a periodically opening and closing electronic switch in parallel to the fluorescent lamp to control the lighting time and the heating current of the lamp.

The disadvantages of conventional brightness control devices for fluorescent lamps, which belong to the case discharge lamps are known. The main disadvantage of this Devices consisted of the lamp electrodes having separate heating transformers had to be externally heated. The electrodes were at full lamp brightness overheated, underheated at minimum lamp brightness, as the external heating is not regulated and was set to a medium value.

There has therefore been no lack of attempts to resolve the difficulties of the known Dealing with devices with new solutions. One such new solution is, for example described in DT-OS 23 32 682 or in the magazine "LICHTTECHNIK", No. 8, 1974, pages 343 to 347, which are, however, at least for small systems as well as for the application in the House installation could not enforce.

A problem with brightness control systems in house installations is in that the control units are housed in a single flush-mounted box if possible should be; because of the poor heat dissipation from flush-mounted boxes, it remains As a rule, the controllable power is unsatisfactorily small, since it is converted into heat Power loss in a conventional control device approximately proportional to the controlled one Performance is.

The aforementioned known solution used for a group of fluorescent lamps a longitudinal actuator and a parallel switch, which are controlled by a common control part can be controlled. Longitudinal actuator and parallel switch are used as phase control switches executed. With the parallel switch, the one emitted by the lamp group is switched off The brightness is regulated with the longitudinal actuator during the lamp dark phase the heating current is regulated to a constant value. Longitudinal actuator and parallel switch are traversed by the total current of all connected fluorescent lamps, whereby the power loss occurring in the switches is relatively high.

In addition, a comparatively complex control part is required, the time-shifted control pulses of different lengths to the Outputs longitudinal actuator and the parallel switch. In addition, this known Circuit at least for the parallel switch, the usual inexpensive power semiconductor switch like thyristors or triac are not used because they are caused by control pulses not only have to be able to be switched on but also switched off.

The present invention is therefore based on the object To simplify known circuit in such a way that in particular on that of the total current flow-through longitudinal actuator and the separate control part, in which the ignition pulses for the parallel age can be dispensed with, and to keep the number of components so small that they are in the fluorescent lamp itself as well as in conventional flush-mounted boxes. In particular, the Invention housing circuit without major changes to the existing house installation can be used compared to uncontrolled lamps.

This object is achieved in that the parallel switch has a Triac with an impedance in series, a diac and an RC element for generation the ignition voltage for the diac or the triac contains that the parallel switch continues a starter circuit is provided, consisting of an RC-Clied in parallel to the Triac and its series impedance and a glow lamp from the connection point between Resistor and capacitor to the diac, and that the resistor that sets the diac ignition voltage generated, designed as a potentiometer, together with the on-off switch in one separate control unit and arranged via a connecting wire with the parallel switch connected is.

This has the advantage that the material costs are substantial are reduced, since only weakly resilient circuit breakers are required, that no additional radio interference suppression means are needed, that also the heating transformers omitted and that the installation costs and the installation effort are considerable is decreased. Further advantages result from the fact that the parallel switch here is partly controlled by the lamp itself, creating an automatic adjustment in particular to the phase shift between mains voltage and mains current, which is caused by the respective ballast impedance used, and that the external control device continues to be extremely simple will and in particular just a lightly loaded potentiometer and an on-off switch can exist because the control pulses in the parallel switching device itself and not in the control device be generated. These control pulses must also occur during the mains voltage zero crossing are available, which is a comparatively low value when a pulse is generated in the control unit requires a lot of phase shifters or storage capacitors because at conventional installation in a flush-mounted box that houses the control unit not both power lines are available.

Due to the assignment according to the invention, one parallel switch to each Each fluorescent lamp is also an individual starter circuit for each lamp easy to implement. The ones proposed in the literature references mentioned at the beginning central starter circuit that uniformly preheats all lamp electrodes through the central parallel switch, the individual starting properties Each lamp does not take into account individually, so that either a relatively long start-up phase must be provided or individual lamps of the centrally controlled lamp group only ignite when the brightness control has been set to the lowest brightness for some time is provided.

Preferably the series impedance connected in series with the triac is an ohmic resistor. Instead of an ohmic resistor, a choke, the primary winding of a transformer or a combination of these components be used. Due to this series impedance, the Heating current flowing through lamp electrodes is limited to the nominal value. An essential one There is an advantage in arranging this series impedance in series with the circuit breaker but in that control pulses can be picked up here, with which further passive parallel switches without their own brightness control potentiometer can be controlled synchronously. It is therefore with the brightness control device according to the invention also possible to control whole groups of lamps, but the installation Every single lamp is practical compared to the installation of uncontrolled lamps does not have to be changed. There is just a single control line between to lay the individual lamps in addition.

The series connection is preferably a triac and series impedance bridged with an interference suppression capacitor. Such interference suppression capacitors are for example also contained in conventional glow starters for uncontrolled lamps.

Preferably, the control device consists essentially of the on-off switch as well as the potentiometer determining the ignition point of the parallel switch, in a commercially available flush-mounted box instead of the light switch, uncontrolled Arrangements housed. This can be done without difficulty because the potentiometer is only lightly loaded, since it only has to control a single parallel switching device.

Parallel switch and starter circuit are preferably in one housed housing similar to conventional glow starters and with connecting pins that allow assembly in conventional starter mounts. One Such miniaturization is only possible because each lamp has its own Parallel switching device is assigned and the services to be switched thereby accordingly are small.

Using the drawings, the invention is intended to be in the form of exemplary embodiments are explained in more detail.

Fig. 1 shows the complete installation as well as the internal circuit the parallel switching device with starter circuit and the control device. One recognises the power lines R, Mp.

A series reactor V is connected to one of the power lines Mp a heating electrode H1 connected. The other heating electrode H2 is over one in the external control device S arranged on-off switch N with the other power line R connected. In addition, a compensation capacitor CK is arranged parallel to the lamp. Parallel to the lamp L is at the connections 1, 2, at which usually the conventional Starter circuit is switched on, the parallel switching device P according to the invention with his starter circuit ST turned on. First you can see an interference suppression capacitor CE.

A triac T with a resistor in series can also be seen Ri. The ignition voltage for the triac T is supplied via a diac D by an RC element, that from the capacitor C7, the resistor R3 and the hub of the connecting wire Vd connected potentiometer R4, which is housed in the external control unit S. is, is formed.

The mode of operation of the circuit according to the invention is as follows: As long as the ignition voltage at the capacitor C7 has not yet been reached, the triac T is blocked and the full voltage is applied to lamp electrodes H1 and H2. The lamp L lights up. As soon as the ignition voltage is reached, the triac T switches through. This goes out the lamp L. At the same time the mains current flows through the heating electrodes H7 and H2, whereby these are preheated as required during the dark phase of the lamp. As soon the mains current through the triac T has dropped to zero, the triac blocks again.

Because of the phase shift between mains current and mains voltage by the series reactor V has the line voltage at this moment a value that is close to the maximum value; as a result, the fluorescent lamp L ignites as desired.

The starter circuit ST consists of an RC element C2, R2 and the Glow lamp C. The starting process proceeds as follows: After closing the power switch N in the control unit S is initially the full line voltage at the connections 1 and 2 of the still unignited lamp L. The voltage divider R2-C2 is dimensioned so that the voltage across the glow lamp G is higher than its ignition voltage, so that the glow lamp C ignites and part of the charge of the capacitor C2 is transferred to the capacitor C1 transmits. Thus, the breakdown voltage of the diac D is reached, so that in known Way the triac T is brought into the conductive state.

This means that a preheating current flows from the network through the series reactor V, the lamp electrodes H1, H2, the triac T and the heating current limiting resistor R1. When the preheating current crosses zero, the triac switches in a known manner automatically returns to the locked state. Due to the phase shift between This shutdown takes place with current and voltage through the inductive ballast V. close to the mains voltage peak value, so that at this moment a sufficiently high Ignition voltage is available at the electrodes of the lamp L to initiate the cas discharge stands. If the lamp L does not ignite, the process described is repeated, the current break because of the relatively low-resistance current path R2-G and the associated rapid re-ignition of the triac T remains so short that the preheating process is practically hardly interrupted.

If, when the power switch N is switched on, the control potentiometer R4 is at minimum (dark position) takes place the rapid charging of the capacitor C1 and thus the rapid re-ignition of the triac T essentially via the potentiometer R4. The resistor R2 is chosen so that when ignited Lamp L the ignition voltage at the glow lamp C is no longer reached, so that the Ignition time of the triac T is then only determined by the control resistor R4. the Short-term lamp ignition voltage impulses recurring in every mains current half-wave at the connections 1 and 2 are suppressed by the integrator R2-C2, see above that they do not lead to the glow lamp G igniting.

Fig. 2 shows how a parallel switching device according to the invention almost any number of other lamps with associated, now passively working parallel switching devices, which do not differ in their structure from the primary device can. For this purpose, the series impedance R1 of the primary parallel switching device P a control voltage is taken that corresponds to the switching state of the triac T, and a connection terminal 4 is supplied. A control line leads from this connection terminal 4 SL to connection 3 'of the passive parallel switching device P', at which otherwise the potentiometer R4 is connected. The input resistance R31 in the parallel control device P 'is large in relation to the resistor R1, so that the connection of switching devices P 'is negligible represents small load, so that further fluorescent lamps via further control lines SL can be controlled.

The function of the passive parallel switching devices P 'is as follows: As long as the triac T is blocked in the main unit P, the lamp Ll, and on the connection 2 of this lamp there is a certain voltage potential that is only slightly different from the potential of the power line R is. At the connector 4 is the same voltage, since Rl is de-energized. Since the lamp L2 is a similar Fluorescent lamp is like L1 and also burns when viewed from the outside the same potential appears at its connection 2 'as on the control line SL.

The capacitor C1 'is therefore not charged, and so does the triac T 'does not ignite. Manufacturing-related voltage tolerances at connections 2 or 2 'of the lances Ll and L2 of an interconnected group of lamps do not interfere, since they are certainly smaller than the breakdown voltages of the associated Diac D '.

If the capacitor C1 im The main unit is charged to the diac breakdown voltage via the control potentiometer R4 is triggered, the triac T. This breaks the voltage across the lamp L7 to values below their running voltage together and the lamp L1 goes out for the rest of the half-wave. At the same time, when the triac T is switched on, the voltage increases at the resistor R7, which is connected via the control line SL, the resistor R3 ', the capacitor C1 'and the diac D' also the triac T 'ignites, so that with a negligible delay (small time constant R3'-c11) also the lamp L2 and possibly other connected ones Lights go out. In the subsequent current zero crossing, elastic triac T, T 'back into the blocking state, so that all connected lamps Ll, L2 Ignite again and burn until after a time that can be specified with potentiometer R4 the triacs are switched on again.

In Fig.2 it is also shown that also in the passively working Parallel switching devices P 'have their own autonomous starter devices with the elements R2'-C2'-C 'are provided, which are independent of each other after switching on the Mains voltage come into operation until the corresponding fluorescent lamp has ignited.

In addition, it is shown in Fig. 2 how with two trimming resistors R5 and R6 in control unit S the setting range of potentiometer R4, i.e. the brightness and dark border to which the respective system can be adapted.

While in an arrangement according to FIG. 2, the parallel switches P and P 'are to be connected to the lamp connections 1 and 2 with the correct polarity, FIG. 3 shows an arrangement in which the secondary devices are independent of polarity. To this end the resistor R1, which is in series with the triac T, must be completely or partially through the primary winding of a transformer Tr can be replaced. The one in the secondary winding of the transformer Tr induced control pulses are from the terminals 5 and 6 via the control line SL to terminals 3 'and 7 of the passively operating parallel device P 'headed. There they switch the triac T ', as it is in connection with Fig. 2 has been described. It is possible to use the transformer Tr of the main unit with several Equip secondary windings in order to control several secondary devices P 'directly. However, each secondary device P 'is preferably given its own transformer Tr' assign, via which the next secondary device is then controlled.

From the above description it follows that the with so far known systems considerable installation effort when converting a switched Lighting system with fluorescent lamps on a brightness controllable on the following Work steps could be reduced: Replacing the one arranged in the flush-mounted box Power switch against the control unit S, Replacing the glow starter against a parallel switching device P or P 'according to the invention, connection of connection 3 of the parallel switching device P and the control device S via a connecting wire Vd, and, if necessary, attaching suitable capacitive starting aids to the fluorescent lamp (so-called ignition net stocking) or replacing the lamp with one for brightness controls suitable type, and if necessary laying the control lines SL between the Lamps in a lamp group.

Claims (8)

Claims brightness control device for fluorescent lamps, containing a series impedance to limit the lamp current and a periodic one opening and closing electronic switch parallel to the fluorescent lamp for controlling the lighting time and the heating current of the lamp, characterized in that that the parallel switch (P) is a triac (T) with an impedance in series (R1, Tr), a diac (D) and an RC-Clied (C1, R3, R4) to generate the ignition voltage for the diac (D) or the triac (T) contains that the parallel switch (P) continues a starter circuit (ST) is provided, consisting of an RC element (R2, C2) parallel to the triac (T) and its series impedance (R1, Tr) and a glow lamp (G) from the connection point between resistor (R2) and capacitor (C2) to the diac (D), and that the resistor (R4), which generates the diac ignition voltage, acts as a potentiometer formed with the on-off switch (N) together in a separate control unit (S) and connected to the parallel switch (P) via a connecting wire (Vd) connected is. 2. Brightness control device according to claim 1, characterized in that that the series impedance is an ohmic resistor (R7). 3. brightness control device according to claim 1, characterized in that that the series impedance is a choke. 4. sanctity control device according to claim 1 or 2, characterized by that the series impedance is the primary winding of a transformer (Tr). 5. brightness control device according to claims 1 to 4, characterized characterized that the series connection of triac (T) and series impedance (RI, Tr) is bridged with an interference suppression capacitor (CE). 6. brightness control device according to claims 1 to 5, characterized characterized in that a tap (4; 5, 6) for control at the series impedance (R1, Tr) further parallel switch (P ') is provided. 7. brightness control device according to claims 1 to 6, characterized characterized in that the control device (S) is arranged in a commercially available flush-mounted box is. 8. brightness control device according to claims 1 to 7, characterized characterized in that parallel switch (P, P ') and starter circuit (ST) in one housed housing similar to conventional glow starters and with connecting pins are provided that allow assembly in the conventional starter mounts.