CS240913B1 - Connection for continuos regulation of number of fluorescents lamps intensity - Google Patents

Abstract

The purpose of the connection is the possibility of regulation more light bulbs, one element and very a wide range, i.e., 45 to 100 µl. The stated purpose is achieved by the output a common control circuit including control potentiometer are connected inverter control circuits and output fluorescent lamps are connected to these inverters.

Description

The object of the invention is a circuit for continuous regulation of the light intensity of wolf lamps supplied from an inverter.

The control of fluorescent light intensities is not carried out at all in the hitherto known circuits, or it is performed by stepping by shifting the capacitors or resistors into the electric circuit of the lamp.

Continuous regulation is also carried out using suitable control resistors connected either to the fluorescent lamp circuit or to the base circuit of the switching transistor of the inverter. All these connections have disadvantages either in step control, or in a small control range - maximum 100 ° C to 70%, and also in the unreliability of ignition of the lamp in the non-set minimum control.

In the case of the use of control resistors, complications arise in the control of multiple fluorescent lamps due to the disproportionately increasing dimensions and the number of control elements, which are then time-consuming to operate.

The above drawbacks are overcome by a circuit for continuously controlling the light intensity of multiple fluorescent lamps according to the invention, which is based on the fact that the inverter control circuits are connected to the output of the common control circuit and fluorescent lamps are connected to the inverter output.

Furthermore, the circuit according to the invention is also characterized in that the common control circuit is a series combination of a fifth resistor with a collector-emitter transition of the fourth transistor and a sixth resistor connected between the first power terminal and the second power terminal, and one end of the path connected and a potentiometer slider that is connected to its first power evolution at its other end.

The principle according to the invention is also based on the fact that the control circuitry 8 consists of a switch which is connected to a second node to which a fourth capacitor is connected. This capacitor is connected by its second terminal between the third resistor and the base of the second transistor. A third capacitor is connected between the second node and the third node, on the one hand, the collector-emitter series of the second transistor, the first resistor and the first capacitor, and the series combination of the primary transformer β

- 2 240 913 of the collector-emitter of the first transistor. The start of the transformer feedback winding is connected between the first resistor and the first capacitor, the end of this winding being connected via the second resistor based on the first transistor. The second and third secondary wires of the transformer are connected with fluorescent lamps of the individual controllers. The first transformer secondary winding is connected at one end via a second capacitor to the second transformer secondary winding.

It is also an object of the invention that the first pole of the inverter switches is connected to the first node in the common control circuit, the third node of the inverter is connected to the fourth node in the common control circuit, and the fifth node of the inverter common control circuit is connected to third nodes which are part of the inverter ·

The advantage of the circuit according to the invention is that, IB is possible to control the intensity of light and the plurality of fluorescent lamps only nevýkonovým element (potentiometer), a very wide range, I 4541100%, wherein the 8QUČasn $ _t .mQŽné zgpnuti and off the lamps even in low regulation.

The wiring diagram according to the invention is shown in the attached drawing for two controlled fluorescent lamps. The inverter is shown only in block at the rest, as the first inverter is absolutely identical.

The circuit consists of a common control circuit 4, which is a series combination of the fifth resistor 30 with the collector-emitter transition of the fourth transistor 29 and the sixth resistor 31 connected to the power terminals 5,6. Based on the fourth transistor 29, one end of the path is connected and the slider of the potentiometer 28 is connected to the first power terminal 5 by the other end. Inverters 1. The control circuits 2 consist of a switch 20 which is connected to the second node 24. a fourth capacitor 22 is connected, with its second pole connected between the third resistor 23 and the base of the second transistor 21¾. A third capacitor 11 is connected between the second node 24 and the third node 25 and a serial collector-emitter junction of the second transistor 21. 12 and the first capacitor 9 as well as a series combination of the primary

240 913 of the winding 15 of the transformer 14 with the collector-emitter transition of the first transistor 8. The start of the feedback winding 19 of the transformer 14 is connected between the first resistor 12 and the first capacitor 9, the end of this winding being connected via a second resistor 13 based on the first transistor 8. the third secondary windings 17 and 18 of the transformer 14 are connected to the fluorescent tubes 3 of the individual inverters 1. The first secondary winding 16 of the transformer 14 is connected at one end via the second capacitor 10 to the second secondary winding 17 of the transformer 14. The first pole of the switches 20 which are part of the controller 11 is connected to the first node 7 in the common control circuit 4. The third node 26 is connected to the fourth node 26 and the fifth node 27 is connected by β to the third nodes 25.

When the supply voltage of the switches 20e is connected, the inverters 1 oscillate, energize the glow current in the secondary windings 17, 18 and the voltage peaks in the secondary winding 16 and the fluorescent lamp 3. of the transistors 8 and hence the frequency of the transducers. The fourth capacitors 22 improve the ignition of the lamps 3 in a minimum of regulation, as well as the smoothness of the light intensity control over the entire range.

The wiring can be used for all instruments and devices where a continuous change in the intensity of the illumination by fluorescent lamps is necessary, such as the negatoecope - a device for illuminating radiograms and the like.

Claims (4)

SUBJECT OF THE INVENTION 1. Circuit for continuous regulation of light intensity of multiple fluorescent lamps, characterized in that the control circuits (2) of the shifters (1) are connected to the output of the common control circuit (4) and to the output of the shifters (1) are connected fluorescent lamps (3). Continuous control circuit according to claim 1, characterized in that the common control circuit (4) consists of a series combination of the fifth resistor (30) and the collector-emitter transition of the fourth transistor (29) and the sixth resistor (31) connected between the first a power supply terminal (5) and a second power supply terminal (6), and based on the fourth transistor (29), one end of the track and a potentiometer slider (28) are connected to the first power supply terminal (5) at the other end. Continuous control circuit according to claim 1, characterized in that the inverters (1) with the control circuits (2) consist of a switch (20) which is connected to a second node (24) to which the fourth capacitor (22) is connected. ), which is connected by its second terminal between the third resistor (23) and the base of the second transistor (21), between the second node (24) and the third node (25) is connected the third capacitor (11) and serial collector-emitter second a transistor (21), a first resistor (12) and a first capacitor (9), and such a series combination of the primary winding (15) of the transformer (14) and the collector-emitter transition of the first transistor (8). The start of the feedback winding (19) of the transformer (14) is connected between the first resistor (12) and the first capacitor (9), the end of this winding being connected via a second resistor (13) based on the first transistor (8) to the second and third secondary windings (17) and (18) the fluorescent tubes (3) of the individual inverters (1) are connected to the transformer (14), the first secondary winding (16) of the transformer (14) being connected at one end via the second capacitor (10) not the second secondary winding ( 17) a transformer (14) and a second end on the third secondary winding (18) of the transformer (14), Continuous control circuit according to Claims 1, 2 and 3, characterized in that the first pole of the switches (20), which is part of the shifters (1), is connected to the first node (7) in the common control circuit (4). fourth node (26) in the common control circuit (4) 240 913 are connected third resistors (23) which are part of the inverter (1) and the fifth node (27) which is part of the common control circuit (4) is connected by 8 third nodes (25) which are part of the inverter (1) ).