CS258093B1 - Three-state staircase automat - Google Patents

Abstract

A time-based automaton is solved with the introduction of a third state, when the user is notified by blinking of the approaching light turning off. The automaton is connected to the circuit of the light bulb and the switch. A triac is connected in parallel to the switch, to which the switch state identifier is connected in parallel. The identifier output is connected to the input of the light bulb switching generator, whose output is connected to the first control input of the electronic key. The output of the synchronization pulse generator is connected to its second control input. The output of the electronic key is connected to the control electrode of the triac. The identifier, the light bulb switching generator, the synchronization pulse generator and the electronic key are connected to the power supply.

Description

BACKGROUND OF THE INVENTION The present invention relates to a three-state staircase machine, the third state of which signals the approaching switching off of light by repeated switching off. and switching on the light.

The known connections of staircase machines are two-state or three-state.

For two-state automatic machines, one state is off and the other is on. The disadvantage of these two-state automatic machines is that the user is not notified in advance of the impending light switch-off, which reduces his / her safety when moving on an unlit staircase.

Known connections of three-state staircase machines eliminate this disadvantage by introducing a third state with reduced illumination as light is approaching, but these connections include mechanical moving parts that reduce their service life and reliability.

One type of these three-state staircase automation draws attention to the imminent switching off of light by continuously diminishing illumination. Their disadvantage is the necessity of using filter circuits to filter out the resulting harmonic components.

The second type of these automata signals the approaching switch-off of the light by a jump in the light intensity. The disadvantage of these wiring is that the intensity drops only once, which the user may not always notice. In addition, these connections include a current transformer, which makes their construction more demanding.

The above-mentioned drawbacks are overcome by the three-state staircase automat according to the invention, connected to the circuit of a bulb and a switch, in which a triac is connected in parallel to the switch. The essence of this three-state staircase automat is that a circuit breaker status identifier is connected in parallel to the triac, the output of which is connected to the input of the light-generator. The output of this bulb switching generator is connected to the first control input of the electronic key. The output of the synchronization pulse generator is connected to the second control input of the electronic key. The electronic key output is connected to the triac control electrode. the circuit-breaker status identifier, bulb switching generator, synchronization pulse generator and electronic key are connected to the power supply.

The circuit breaker status identifier can be created by inputting a series combination of the first capacitor, the first resistor, and the first Zener diode. The cathode of the first Zener diode is connected via a first diode connected in the forward direction to the parallel combination of the second capacitor and the second resistor, and through an inverter and a second diode connected also in the forward direction to one end of the third capacitor, identifier output. The other end of this third capacitor is connected to the anode of the first Zener diode.

The synchronization pulse generator may be formed by providing a series combination of a third resistor and a second Zener diode connected to the third resistor by its cathode at its input. A parallel combination of the fourth capacitor and the fourth resistor is connected in parallel to the second Zener diode. The cathode of the second Zener diode is connected to the base of the transistor via a fifth resistor.

^P The collector of this transistor is connected via the sixth resistor to the positive pole of the power supply and through a series combination of the fifth capacitor and the seventh resistor connected to the emitter of the transistor and at the same time to the anode of the second Zener diode. The common point of the fourth capacitor and the fourth resistor is connected through the third diode in the forward direction to one end of the eighth resistor, which is also the output of the synchronization pulse generator.

A common point of the fifth capacitor and the seventh resistor is connected to this end of the eighth resistor via the fourth diode in the forward direction. The other end of the eighth resistor is connected to the anode of the second Zener diode.

The main advantage of the three-state staircase automat according to the invention is that this wiring signaling the approaching switch-off of the light by flashing, which enables the light to be easily switched on again. Another advantage is that the wiring is fully electronic without any mechanical components, which increases its service life and reliability. The triac used does not need to be sized for the high incandescent lamp currents, since these are wired when the lamp filaments are heated and have a relatively high resistance. Due to the fact that the triac switching on occurs at approximately zero line voltage, the wiring does not need to include anti-interference filters.

An example of a three-state staircase automat according to the invention is shown schematically in Fig. 1. 2 shows the circuit-breaker status identifier connection and FIG. 3 the synchronization pulse generator connection, where these blocks are part of the basic circuit.

A serial combination of Bulb 2 ® switch 4 is connected to the network between the first and second terminals 1 and 2. Switch 4 is bypassed by triac 6 and switch 7 status identifier 4, which are connected between the second and third terminals 2 and 2. · Identifier j is longer connected to the bulb switch generator 8, the output of the bulb switch generator 8 is connected to the first control input of the electronic key 10, to whose second control input the output of the synchronization pulse generator 2 is also connected. The output of the electronic key 10 is connected to the triac control electrode

6. Parallel to the serial combination of the bulb 2 ^{and the} switch 4, a power supply 11 for the switch 7 status identifier 4 is connected. generator 8 switching on the bulb 5 »synchronization pulse generator 2 and electronic key 10.

The circuit breaker status identifier 7 consists of a triac protection

6, which is connected at the input, between the third and second terminals J and 2

- a 4 series combination of the first capacitors 21, the first resistors 22 and the first Zener diode 23, which is actually connected in parallel to the triac 6. The common point of the first resistors 22 and the cathode of the first Zener diode 23 is connected through the first diode 24 in forward direction to one end. a parallel combination of the second capacitor 25 and the second resistors 26, the other end of which is connected to the anode of the first Zener diode 23 and hence to the second terminal 2 of the first diode 24 and hence the first end of the parallel combination the second capacitor 25 - the second resistor 26 Inverter 27 may be used as an inverter 27 with a CMOS gate. Negation of the input signal can also be obtained by a transistor in common emitter connection. The output of the inverter 27 is connected through the second diode 28 in the forward direction to one end of the third capacitor 29 ' which is also the output of the identifier 2. The other end of the third capacitor 29 is connected to the second terminal 2.

The synchronization pulse generator 2 is formed at the input by a series combination of the third resistors 21 and a second Zener diode 32 connected to the third resistor 31 by its cathode, the series combination being connected to the network, i.e. between the first terminal 1 and the second terminal 2. 31 and the cathodes of the second Zener diode 32 is connected to one end of the fourth capacitor 22, which in turn is connected via the fourth resistor 21 to the second terminal 2 and thus to the anode of the second Zener diode 32 and connected to the base of the transistor 22 the emitter of transistor 37 is connected to the second terminal 2 and the collector coupled via the sixth resistor 36 is connected to the positive pole of the power sources 11. At the same time it is also a collector connected via the sixth capacitor 38 and a seventh resistor to the second terminal 39 of the second common »dot as the fourth capacitors 22 ^and the fourth resistor 34 is coupled to the one through the third diode 41 in the forward direction m at the end of the eighth resistors 42, to which at the same time a common point of the fifth capacitors 38 and the seventh resistors 39 is connected via the forward diode 40 and the node is the output of the synchronization pulse generator 2. The other end of the eighth resistors 42 is connected to the second terminal 2. Instead of transistor 37, 258093 can be used

- 5 hours to use an inverter specially built using a CMOS circuit.

The three-state staircase automat described above operates as follows. Pressing the switch 8 causes the current to pass through the bulb 2 which lights up and the resistance of its filament increases. The second capacitor of the circuit breaker status identifier 2 discharges through the second resistor 26. This causes a rapid charge of the third capacitor 29 "The voltage of this third capacitor 29 is controlled by the lamp 8 generator 8", preferably composed of CMOS gates for example. At the same time, the sync pulse generator 2 generates pulses when the mains voltage passes zero, so that the rectangular pulses generated by the second Zener diode 32 and their negations are derived by the fourth capacitor 21 and the fourth resistor 34 and by the fifth capacitor 38 Positive pulses are output by means of the third and fourth diodes 41 and 40. The synchronization pulses and the pulses generated by the lamp switch-on generator 8 are applied to the input of the electronic key 10, which, when both pulses exist, The ronic key IQ pulses energizing the triac 6. The generator 8 turns on the bulb 2 at the beginning of the bulb to be permanently lit and after a certain time, for example after a minute, starts to flash continuously, which takes about 15 seconds. Pressing the switch 8 will further charge the third capacitor 29 and repeat the entire cycle described. The discharge time constant of the second capacitor 25 is determined such that the third capacitor 29e only charges when the circuit breaker 8 is closed. Upon turning it off, regardless of the condition of the triac 6, whether or not it is conducting, the second capacitor 25 is charged and the third capacitor 29 can discharge.

For smaller powers of the switched-on heat sources, the synchronization pulse generator 2 can be omitted. The function of the staircase machine does not change. Triac 6, however, will be connected at different values of the sine wave and its control electrode will still flow current while the bulbs are on.

Claims (3)

A three-state staircase automatic circuit-breaker connected to a light-breaker circuit to which a triac is connected in parallel, characterized in that a circuit breaker status identifier (7) connected to the generator input is connected in parallel to the triac (6). (8) switching on the bulb (5), whose output is connected to the first control input of the electronic key (10), to whose second control input is connected the output of the synchronization pulse generator (9) and the output of the electronic key AO 6, wherein the circuit breaker status identifier (7), the bulb switching generator (8), the synchronization pulse generator (9), and the electronic key AO () are connected to the power supply (11). 2. Three-state staircase automat according to item 1 _; characterized in that the circuit breaker status identifier (7) is formed at the input by a series combination of a first capacitor (21), a first resistor (22), and a first Zener diode (23), the cathode of which is in the passage through the first diode (24) connected to a parallel combination of the second capacitors (25) and the second resistor (26) and through the inverter (27) and the second diode (28) in the forward direction to one end of the third capacitor (29), which is also the identifier output (7) and the second end of the third capacitor (29) is connected to the anode of the first Zener diode (23). 3. Three-state staircase automat according to items 1 and 2 _; characterized in that the synchronization pulse generator (9) is formed at its input by a series combination of a third resisor (51) and a second Zener diode (32), wherein a series combination of a fourth capacitor (33) is connected in parallel to the second Zener diode (32); the fourth resistor (54) and the cathode of the second Zener diode (52) is further coupled via the fifth resistor (35) to the base of the transistor (37), the collector of which is connected via a sixth resistor (56) to the positive pole of the power supply (11) and serial kombinaqii fifth køndjødT7ra / 48 · / ^ seventh rezis258093 - 7 tor (39) is connected to the emitter of the transistor (37) and also to the anode of the second Zener diode (32), the common point of the fourth capacitor (33) and the fourth resistor (34) being connected through the third diode (41) in the forward direction to one end of the eighth resistor (42), which is the output of the synchronization pulse generator (9) and to which at the same time a common point of the fifth capacitor (38) and the seventh resistor (39) and the other end of the eighth resistor (42) is connected to the anode of the second Zener diode (32).