CS265612B1 - Three-state staircase automat - Google Patents

Abstract

A three-state staircase automaton is designed, the third state of which signals the approaching switching off of the light by cyclically switching it off and on. The automaton is connected to the circuit of the light bulb and the switch. In parallel to the series combination of the light bulb and the triac, a source is connected that supplies the single-pulse generator, the light bulb switching generator, the synchronization pulse generator and the electronic key. The input of the single-pulse generator is connected to a monostable switch and the output to the input of the light bulb switching generator. The output of the light bulb switching generator is connected to one of the two inputs of the electronic key. The output of the synchronization pulse generator is connected to the second input of the electronic key.

Description

The invention relates to a three-state staircase machine, the third state of which signals the approaching switch-off of 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 alerted in advance of the impending light switch-off, which reduces his 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 life and reliability. One type of these three-stage staircase automa- tors draws attention to the imminent switching off of light by continuously diminishing illumination. Its disadvantage is the necessity of using filter circuits to filter out the resulting harmonic components.

The second type of three-state staircase automata signals the approaching light switch-off by a drop in light intensity. The disadvantage of these wiring is that the intensity drops only once, which the user may not notice.

There are also connections that blink to alert you when lights are coming off. According to AO No. 258 093, these circuits consist of a circuit breaker status identifier, a bulb switching generator, a synchronization pulse generator, an electronic key and a power supply. The power electronic element is a triac, which is connected in series with the bulb and in parallel with the circuit breaker and circuit breaker status identifier. The disadvantage of this type of staircase automat is that when the switch is permanently blocked, the light is always on.

The above-mentioned disadvantages are overcome by the three-state staircase automat connected to the bulb circuit connected in series with the triac according to the invention. The automat is also made up of a power supply connected in parallel to a serial combination of a bulb and a triac, where the power supply is connected to a bulb switching generator, a synchronization pulse generator and an electronic key. . It is an object of the invention that a single pulse generator is connected to the source, to which an monostable switch is connected and the output of which is connected to the input of the bulb switching generator.

The single pulse generator is preferably formed by an inverter having an input connected via a first resistor to the positive pole of the source and through a series combination of the first capacitor and a monostable switch to the negative pole of the source. The first capacitor is bridged by a second resistor. The inverter output is connected via a first diode to a first pole of a second capacitor whose second pole is connected to the negative pole of the source.

The main advantage of the three-state staircase automat according to the invention is that this connection signals the approaching switching off of the light by flashing, which enables easy reconnection of the lighting. Another advantage is that the wiring is fully electronic without any mechanical components, which increases its service life and reliability. Due to the fact that the triac is switched on at approximately zero mains voltage, the circuit does not need to contain anti-interference filters. Another advantage is that blocking the switch on the staircase does not cause the light to be permanently switched on because the circuit is pulsed. The advantage of connecting a single pulse generator according to the invention is its simplicity.

An example of connection of a three-state staircase automat according to the invention is shown in Fig. 1. Fig. 2 shows a particular connection of a single pulse generator, Fig. 3 shows one embodiment of the synchronization pulse generator and Fig. 4 shows one embodiment of the switching generator light bulbs.

A serial combination of bulb 2 and triac 6 is connected between the first terminal 2 ^{and the} third terminal 3 to which the mains voltage is connected. At the same time, a power supply 11 is connected to the first and third terminals 1 and 3. The pulse generator 7 has a monostable switch 4 connected at the input between the second and third terminals 2 and 3, and its output is connected to the input of the lamp switching generator. The light switch generator 2 is connected to the first input of the electronic key 10. To its second input a synchronization pulse generator 9 is connected. The output of the electronic key 10 is connected to the triac control electrode 6.

The single pulse generator 7 in this case is composed of an inverter 24 formed by a CMOS type NE gate. A first resistor 21 is connected to the input of the inverter 24, the other end of which is connected to the positive supply pole. At the same time, a series combination of the first capacitor 23 and the monostable switch 4 is connected to the input of this inverter 24, which is connected to the negative supply pole, that is to say the whole block connection to the third terminal 3. is connected via a first diode 25 to one pole of the second capacitor 26, the other of which is connected to the negative supply pole, i.e. the third terminal 3.

For example, the synchronization pulse generator 9 can be built using a CMOS type NE gate 33 NE. The input of gate 33 is connected to the common point of the cathode of Zener diode 32 whose anode is connected to the third terminal 2 ^and the third resistor 31, whose other end is connected to the first terminal 2 · ^The input of gate 33 is also connected a serial combination of the fourth capacitor 36 and the fifth resistors 37. The common point of the third capacitor 34 and the fourth resistors 35 is connected via the second diode 39 to the sixth resistor 40, to which the common point of the fourth capacitor 36 and the fifth resistors 37 is connected via the third diode 38. output of the synchronization pulse generator 9.

One possibility of creating the generator 2 of switching on the bulb 5 is a circuit, constructed by means of two NAND gates of the CMOS type. The first input of the first NAND gate 44 is connected to a fifth capacitor 41, the second pole of which is connected to the negative supply pole, i.e. the third terminal 2. This first input is also connected via the seventh resistor 42 and the fourth diode 43 to the eighth resistors 52 At the output of the generator 2, switching on the bulb 2. ^A second resistor 46 connected ^{to the} second input of the first NAND gate 44 is connected via the tenth resistor 48 and the fifth diode 47 to the first NAND gate output £ 4 connected to both inputs of the second NAND gate.

45, on the one hand through the eleventh resistor 49 with the inputs of the second gate NAND 45 and on the other hand through the sixth capacitor 50 with the output of the second gate NAND 45. The output of the second gate NAND 45 is connected via the sixth diode 51 to the eighth resistor 52.

The three-stage staircase automat described above operates as follows. Pressing the monostable switch 4; causes the pulse to be generated by a single pulse generator 7. This pulse causes the fifth capacitor 41 of the generator 2 to turn on the bulb 2 which is put into operation. This lamp switching generator 2 generates one long pulse of about 1 minute and several short pulses of about 1 second, with an interval of 0.2 seconds between them. These pulses turn on the first input of the electronic key 12 · ^D ^ Uhy input of the electronic key 10 is actuated by pulses from the generator 9 of sync pulses. This synchronization pulse generator 9 generates pulses when the grid voltage reaches a value close to zero. The electronic key 10 turns on the triac ^{at the} moment of the presence of two pulses at both inputs. The bulb 2 is also switched on at the mains voltage when the mains voltage is approximately zero. Thus, at the beginning, the bulb 2 lights continuously and then briefly with an intermittent light, which indicates that the illumination is approaching.

Claims (2)

SUBJECT OF THE INVENTION 1. A three-state staircase controller connected to a bulb circuit to which a triac is connected in series, where the three-state staircase controller is a source connected in parallel to a serial light bulb / triac combination connected to a bulb switching generator the bulb switching generator is connected to the first input of the electronic key, the second input of which is connected to the output of the synchronization pulse generator and the output of the electronic key is connected to the triac control electrode, characterized in that a single pulse generator (7) is connected , the input of which is connected to the monostable switch (4) and whose output is connected to the input of the generator (8) of switching on the bulb (5). 2. The three-state staircase automat according to claim 1, characterized in that the single pulse generator (7) is formed by an inverter (24) having an input connected via a first resistor (21) to the positive pole of the source (11) and through a series combination of the first capacitor. 23) and a monostable switch (4) to the negative pole of the source (11), the output of the inverter (24) being connected via a first diode (25) to the first pole of the second capacitor (26), the second pole of which is also connected to the negative pole of the source (11). 11) and a second resistor (22) is connected in parallel to the first capacitor (23).