CS257958B1 - Staircase machine connected - Google Patents

Abstract

The aim is to create a simple, cheap and maintenance-free adjustable staircase automatic device made exclusively of electronic elements with a longer service life, which does not exhibit unwanted radio interference and does not require changing the existing installation of the staircase lighting distribution and in which the lighting cycle can continue for a certain period of time before turning off, weakened, while allowing for simple means of setting longer times of both lighting modes without increasing its volume. The stated goal is achieved by a connection controlled by a power button, with a triac, thyristors and transistors. The solution can be used for automatic control of single-phase staircase lighting and the like.

Description

The invention relates to the connection of a staircase machine for the automatic control of single-phase staircase lighting.

The well-known staircase controller according to AO 249 403 uses exclusively electronic components with significantly longer service life, is simple, cheap and maintenance-free. The illumination cycle can be set so that the bulbs shine in both half-cycle and dimmed for one half-period before switching off. The times of both lighting modes can be set separately. Changes to the lighting mode are made by jumping, so there is no unwanted interference to radio and television. There is no need to change the existing staircase lighting distribution. The disadvantage of this connection is the practical possibility to set relatively short times after which the staircase is illuminated.

Longer times could be achieved by using enormously large capacities, but this would mean an undesirable increase in the volume of the entire staircase automat and an increase in its cost, since electrolytic capacitors are disproportionately expensive compared to semiconductors.

This drawback eliminates the connection of the staircase automat according to the invention, the principle being that the first switching terminal is connected via a second limiting resistor to both the input of the first rectifier and the input of the second rectifier whose output is connected via the second filter capacitor to the anode of the first polarizing diode. first through the second collector resistor to the collector of the second transistor, the output of the first rectifier is connected through the first collector resistor to the collector of the first transistor, the output of the first rectifier is further connected through the first filter capacitor to the first input terminal; a first transistor-based discharge resistor whose emitter is connected to the first excitation thyristor control electrode and through the first transistor-based base resistor, the cathode of the second charging diode is further connected via the second? a second transistor-based control discharge resistor whose emitter is connected to the second drive thyristor control electrode and through a second base transistor-based resistor.

The advantage of connecting the staircase automat according to the invention is that it makes it possible by simple means to set longer times of both lighting modes, while its volume remains the same.

An example of a staircase automat according to the invention is shown schematically in the attached drawing.

The second anode A2 of the triac TK is connected to the first input terminal 2 for connection to the mains voltage. The first anode AI triac TC is connected to the second output terminal 4. The first output terminal 2 connected to ^te first switching terminal 2 ^and a second input terminal 2 for connection to the mains voltage. The second switching terminal 2 is connected via the charging resistor R1 to the anode of the first charging diode D1 and to the anode of the second charging diode D2, the cathode of which is connected via the second timer capacitor C2 to the anode of the first polarizing diode D5. A switch button TL is connected between the first switch terminal 5 and the second switch terminal <>.

A bulb 8 is connected between the first output terminal 2 ^{and the} second output terminal 8. The cathode of the first charging didode D1 is connected via the first timer capacitor C1 to the first input terminal 2. The anode of the first excitation thyristor T1 is connected via the first limiting resistor R2 to the triac control electrode TK and to the cathode of the second polarizing diode D6 the cathode of the second excitation thyristor T2 and the anode of the first polarization diode D5.

The cathode of the first polarizing diode D5 is connected to the first input terminal 2 · The anode of the second excitation thyristor T2 is connected to the first input terminal 2 · The cathode of the first excitation thyristor T1 is connected to the first input terminal 2 ^and TI. The control electrode and cathode of the second excitation thyristor T2 are connected by a second damping resistor R4.

The control electrode and the first anode of the triac TK are connected by a third damping resistor R5. The first switching terminal 5 is connected via a second limiting resistor R6 to both the anode of the first rectifier diode 133 and to the anode of the second rectifier diode D4 whose cathode is connected via the second filter capacitor C4 to the anode of the first polarizing diode D5 on the collector of the second transistor Tr2 of the npn type.

The cathode of the first rectifier diode D3 is connected via the first collector resistor R9 to the collector of the first transistor Tri of the npn type. The cathode of the first rectifier diode D3 is further connected via the first filter capacitor C3 to the first input terminal 11.

The cathode of the first charging diode D1 is further connected via a first control discharge resistor R7 based on transistor Tri, whose emitter is connected to a control electrode of the first excitation thyristor T1 and through a first base resistor R11 based on the first transistor Tri. The cathode of the second charging diode D2 is further connected via a second regulating discharge resistor R8 based on the second transistor Tr2, whose emitter is connected to the control electrode of the excitation thyristor T2 and through a second resistor R12 based on the second transistor Tr2. In series with a triac TK, a fuse (not shown) is normally used to protect the TK tirac against the effects of shocks or overloads.

If necessary, additional lamps can be connected in parallel to the bulb Z and additional buttons can be connected in parallel to the switch button TL,

At rest, the first filter capacitor C3 is charged via the second limiting resistor R6 and the first rectifier diode D3, and the second filter capacitor C4 is charged through the second rectifier diode D4. The lighting cycle is started by briefly pressing the on / off button TL. The first timer capacitor C1 is charged via the charging resistor R1 and the first charging diode D1 and the second timer capacitor C2 is charged through the second charging diode D2. The second timer capacitor C2 is further provided via the first polarizing diode D5.

At this point, both transistors Tri and Tr2 also open. Through the first collector resistor R9 and the first transistor Tri, the first excitation thyristor T1, which is in series with the first limiting resistor R2 in the triac excitation circuit TK, is energized for one half period of the line voltage.

At the time of the second half-period of the line voltage, the triac TK is excited via the first limiting resistor

R2 a second polarizing diode D6 and a reverse polarized second excitation thyristor T2. This is driven via a second collector resistor R10 and a second transistor Tr2. The first and second timing capacitors C1 and C2 discharge through the first and second regulating discharge resistors R7 and R8 into the excitation circuits of the first and second transistors Tri and Tr2 and the first and second thyristors T1 and T2 respectively.

The discharge time can be set individually to regulate independent lighting times in both half-periods using the first and second control discharge resistors R7 and R8. The Z lamp then lights up fully in both half-cycles for some time and remains dimmed in one half-cycle for the remainder of the cycle, alerting the user to press the TL button if necessary.

The invention can be used for automatic single-phase staircase lighting and the like.

Claims (1)

SUBJECT OF THE INVENTION Connection of a triac staircase automat whose second anode is connected to the first input terminal and whose first anode is connected to the second output terminal, the first output terminal is connected to the first switching terminal and to the second input terminal, the second switching terminal is connected via the charging resistor to an anode of the first charging diode and an anode of the second charging diode, the cathode of which is connected via the second timer capacitor to the anode of the first polarizing diode, the cathode of the first diode is connected via the first timer capacitor to the first input terminal; resistance to the triac control electrode, both to the cathode of the second polarization diode, the anode of which is connected to the cathode of the second excitation thyristor and to the anode of the first polarization diode, the cathode of the first polarization diode is connected to the first input terminal; to the first input terminal, the cathode of the first excitation thyristor is connected to the first input terminal and through the first damping resistor to the control electrode of the first excitation thyristor, the control electrode and the cathode of the second excitation thyristor are connected by a second damping resistor resistor characterized in that the first switching terminal (5) is connected via a second limiting resistor (R6) to both the input of the first rectifier diode (D3) and to the input of the second rectifier diode (D4) whose output is connected via the second filter capacitor ( C4) on the anode of the first polarizing diode (D5), first through the second collector resistor (R10) to the collector of the second transistor (Tr2), the cathode of the first rectifier diode (D3) is connected through the first collector resistor (R9) to the collector of the first transistor (Tri) , the cathode of the first rectifier diode (D3) is further connected via the first filter condensate or (C3) to the first input terminal (1), the cathode of the first charging diode (D1) is further connected via a first regulating discharge resistor (R7) based on a first transistor (Tri) whose emitter is connected to the control electrode of the first excitation thyristor (T1) ) and through a first base resistor (R11) based on the first transistor (Tri), the cathode of the second charging diode (D2) is further connected via a second control discharge resistor (R8) based on the second transistor (Tr2) whose emitter is connected to the control an electrode of the second excitation transistor (T2) and through a second base resistor (R12) based on the second transistor (Tr2).