RU2266613C1 - Electronic switch - Google Patents

Abstract

FIELD: remote commutation in alternating or direct current grids.

SUBSTANCE: electronic switch has receiver for remote receipt from external control panel of encoded signal and transformation of it to pulse series, delay device, input of which is connected to output of receiver, first pulse counter, force block in form of one or more force keys for commutation, of appropriately one or more loads, power source and generator of signal of starting setting. Also provided is second pulse counter, connected by counting input to output of first pulse counter, and by outputs to inputs of appropriate force keys, while first pulse counter by its counting input is connected to output of receipt device, by zeroing input - to output of delay device, by count forbidding input - to own output, and zeroing input of second counter is connected to output of signal generator of starting setting.

EFFECT: higher reliability and broader usability range.

11 cl, 1 dwg, 1 tbl

Description

The invention relates to the field of electrical engineering and can be used for remote load switching in AC or DC networks using a remote control (RC), for example, on infrared (IR) rays. It seems possible to use the remote control of commercially available household equipment.

Known electronic switches [1] - [3] containing a power source, IR receiver, logic elements and power block. A common disadvantage of the known devices is their low reliability, which is caused to one degree or another by: complexity, the absence of an appropriate initial installation when turned on, low noise immunity, high level of generated interference, high heat dissipation.

The closest in technical essence to the claimed one is an electronic switch [4] selected as a prototype, containing a receiving device capable of remotely receiving an encoded signal from an external control panel and converting it into a pulse sequence, a delay device whose input is connected to the output of the receiving device, a counter pulses, a power unit in the form of one or more power switches for switching, respectively, one or more loads, a power source and a signal conditioner Primer installation.

The disadvantages of the known electronic switch are as follows.

The pulse counter actually counts the bursts of pulses, while not taking into account the pulsed nature of the received command and does not take into account the fact that, firstly, the command sent from the remote control of real household equipment may contain not one burst of pulses, but, for example, two, and secondly, a relatively short press of a button on the control panel practically generates several bursts of pulses. These two circumstances create very uncertain conditions for transferring the pulse counter to the required state, which forces the user, giving one command after another, to carefully monitor the load being switched on, in order not to skip the necessary moment. Therefore, before receiving the next command, the pulse counter may have several possible states, and the transition to the required state is not uniquely determined and strongly depends on the control panel used, which reduces the reliability of the functions performed by the known electronic switch and narrows its scope. The power unit has a common rectifier diode bridge and one or more field effect transistors for switching the corresponding number of loads, which, in relation to the AC network, creates excessive heat generation on the diode bridge and, in addition, does not allow the use of this electronic switch for a load requiring power alternating current, which also narrows the scope of its application. The known electronic switch does not provide special measures to reduce electromagnetic interference.

The aim of the invention is to increase reliability and expand the scope.

This goal is achieved by the fact that an electronic switch containing a receiving device capable of remotely receiving an encoded signal from an external control panel and converting it into a pulse sequence, a delay device, the input of which is connected to the output of the receiving device, a first pulse counter, a power unit in the form of one or more power switches for switching, respectively, one or more loads, a power source and a driver of the initial installation signal, a second pulse counter is introduced, knitted by a counting input with the output of the first pulse counter, and outputs with inputs of the corresponding power switches, and the first pulse counter with its counting input is connected to the output of the receiving device, the input of zeroing is connected to the output of the delay device, the input of prohibition of counting is connected with its own output, and the input of zeroing of the second a pulse counter is connected to the output of the driver of the initial setup signal.

The receiving device can be made in the form of an IR receiver.

In order to increase noise immunity and reduce sensitivity to the signal reflected from surrounding objects, the receiving device may be equipped with a protective mask having an opening for the directional reception of infrared rays.

Power keys can be made in the form of alternating current keys, for example, on triacs.

In order to increase reliability and reduce emitted noise, the power unit can be equipped with a circuit that provides switching power switches at the moment of passage of the switched voltage through zero.

In order to increase reliability and reduce radiated interference, each power switch can be equipped with a circuit that provides switching at the moment of passage of the switched voltage through zero.

In order to simplify, power keys can be made in the form of keys with optical isolation between inputs and outputs, for example, on optosymistors.

In order to reduce the required power of the power source, the inputs of the power switches can be connected in series with each other and connected to a power source through a common current-setting resistor, and the outputs of the second pulse counter are connected to the inputs of the power switches through buffer switches, for example, transistors connected in parallel to the mentioned inputs power keys.

In order to ensure the initial inclusion of only part of the power switches when power is applied, the corresponding buffer transistors may have opposite conductivity with respect to other buffer transistors.

In order to reduce heat generation, the power source can be made transformerless with a quenching condensate.

In order to reduce ripple of the output voltage of the power source and dimensions, the output filter of the power source can be made in the form of a U-shaped CRC filter.

The drawing shows a diagram of an electronic switch.

The electronic switch contains a receiving device in the form of an IR receiver 1, capable of remotely receiving an encoded signal from an external control panel and converting it into a pulse sequence, a delay device 2, the input of which is connected to the output of the IR receiver 1, the first pulse counter 3, the power unit 4 in the form two power switches 5 and 6 for switching loads 7 and 8, a power source 9, a driver of the initial setup signal 10, a second pulse counter 11, connected by a counting input to the output of the first pulse counter 3, the outputs with the inputs of the corresponding power switches 5 and 6, through transistors 12 and 13 connected in parallel to the mentioned inputs of the power switches 5 and 6. The first pulse counter 3 is connected to the output of the IR receiver 1 by its counter input, and the zeroing input to the output of the delay device 2, input prohibition of counting - with its own output, and the input of zeroing of the second pulse counter 11 is connected to the output of the driver of the initial setting signal 10. Power switches 5 and 6 are made on opto-sims, each of which is equipped with a circuit 14 and 15, providing switching at the moments of passage of the switched voltage through zero. The inputs of the power switches 5 and 6 are connected in series with each other and are connected to a power source 9 through a common current-carrying resistor 16. The power source 9 is transformerless with a quenching condensate 17. The output filter 18 of the power source 9 is made in the form of a U-shaped CRC filter.

The electronic switch operates as follows.

If there are no signals from the outside, the output of IR receiver 1 contains a unit (positive voltage close to the supply voltage), which, through the delay device 2, affects the zeroing input of the first pulse counter 3 (the delay device’s capacitor is charged), which resets the first pulse counter 3. Thus, in the initial state, before the receipt of the next command, the first pulse counter 3 is always reset. In this case, the second pulse counter 11 can be in any state, but the information is taken only from the two least significant bits, the state of which ultimately determines the state of the power switches 5 and 6.

The table shows the possible states of the electronic switch depending on the states of the second pulse counter 11, buffer transistors 12, 13 and power switches 5, 6.

Table Electronic switch status Second pulse counter 11 Buffer Transistor 12 Buffer Transistor 13 Power key 5 Power key 6 top exit bottom exit 1 0 0 Closed Open Switched on Switched off 2 1 0 Open Open Switched off Switched off 3 0 1 Closed Closed Switched on Switched on 4 1 1 Open Closed Switched off Switched on

As a result of the receipt of a command from the remote control of any household equipment, for example, a TV (by pressing any of the remote control buttons), a packet of 10 or more pulses with a frequency of the order of 500-1000 Hz is formed at the output of the IR receiver 1, and the duration of the positive and zero phases do not differ from each other by more than 3-4 times.

A few pulses are required in order for the capacitor of the delay device 2 to be discharged, ensuring that the signal is removed from the zeroing input of the first pulse counter 3, and only after that the first pulse counter 3 begins to count the pulses coming from the IR receiver 1. A few more pulses of the command pack are required for translation the output of the first pulse counter 3 (this can be the output, for example, of the third bit of a binary number) to the state of a unit, which, upon entering the prohibition input of the account of the same pulse counter, will prohibit further e change in his condition. At the same time, the second pulse counter 11 will go into the next state, which will ultimately change the state of the power switches 5 and 6 in accordance with the above table.

At the end of the command burst of pulses, the output of the IR receiver 1 will go to one, which will charge the capacitor of the delay device 2 and thereby zero the first pulse counter 3, which will prepare the circuit for receiving the next command.

The introduction of the second pulse counter 11 made it possible to separate the function of command execution from the function of identifying the command burst of pulses among the signals received at the input of IR receiver 1. In this case, the first pulse counter 3 detects the command pulse train, and the second pulse counter 11 gives the signal for switching loads 5 and 6 in accordance with the above table only after the appearance of the unit at the output of the first pulse counter 3. This significantly increased the reliability of the electronic switch.

Arrivals from outside of interference causing the output of the IR receiver 1, the appearance of single pulses or series of pulses that are not connected in a single burst by certain relationships (the number of pulses is more than 10, the frequency is 500-1000 Hz, the durations of the positive and zero phases do not differ from each other by more than 3 -4 times), will not lead to the passage of the command, because, firstly, too few pulses will not be able to discharge the capacitor of the delay device 2 with the subsequent transfer of the output of the first pulse counter 3 to the unit state, and secondly, too short a sharp zero phase (compared with the positive phase) in the pulse sequence will not provide a discharge of the delay device capacitor 2 to output the first pulse counter 3 from the zeroing state, and, thirdly, an excessively low frequency of pulses in the packet cannot support the discharged state of the delay device capacitor 2 without zeroing the first pulse counter 3 with virtually every positive phase of the pulse sequence.

The commands of individual remote controls may contain not one but several bursts of pulses separated by a pause relative to each other. This circumstance requires that the discharge branch of the capacitor of the delay device 2 have a resistance of at least an order of magnitude lower than the resistance of the charging branch. This will not allow during the pause to charge the capacitor of the delay device 2 and, having reset the first pulse counter 3, take the second packet of pulses as the next command.

When the remote control command button is held for a long time, command bursts of pulses are generated continuously after a pause, but longer than the one mentioned above.

In order for the circuit to react only to the first packet of pulses, the ratio of the resistances of the charge and discharge branches of the capacitor of the delay device 2 should differ from each other even more significantly, for example, by two orders of magnitude.

The initial installation of the circuit when power is supplied is provided by the signal conditioning instrument 10, while at the input of the zeroing of the second pulse counter 11, a unit is maintained during the entire period of increase in the supply voltage. Thus, the initial state of the electronic switch when power is supplied is always characterized by the on state of the power switch 5 and the off state of the power switch 6 (see the table above), since when the signal at the outputs of the zeroed second pulse counter 11 is zero, the buffer transistor 12 is closed and the buffer transistor 13 having a different conductivity, is open and therefore shorts the input of the power switch 6.

This measure, namely, ensuring the initial switching on of one of the power keys 5 and 6, is justified by the fact that switching on, for example, a chandelier, in which the inventive electronic switch is integrated, with a conventional wall switch, should not introduce inconvenience in finding the remote control in the dark. Therefore, after the wall switch is closed, the electronic switch built into the chandelier must turn on the chandelier or its individual lamps, thereby not revealing itself and not violating our habits. And further control of the chandelier can be done using the remote control.

Power switches 5 and 6 directly switch AC loads 7 and 8, which can be not only chandelier lamps or sconces, but some other household appliances that require only alternating current for power, for example, a fan or air conditioning, which significantly expanded the scope of the claimed electronic switch, and since it does not require additional diodes and diode bridges, heat loss is minimal.

Since the power switches 5 and 6 are equipped with circuits 14 and 15, which provide switching at the moments when the switching voltage passes through zero, the claimed electronic switch practically does not emit interference, and due to the absence of extra currents through the power elements, the reliability of the device as a whole is increased. In addition, the absence of extra currents favorably affects loads 7 and 8 (increases their service life).

The use of optocouplers 5 and 6 as power switches simplified the construction of the power element control circuit, and by connecting the control inputs of the power switches 5 and 6 in series through a common current-carrying resistor 16 and introducing buffer transistors 12 and 13, it reduced the required power of the power supply 9.

The power source 9 is made transformerless with a quenching capacitor 17, which reduced heat dissipation.

And finally, the implementation of the output filter 18 of the power source 9 in the form of a U-shaped CRC filter reduced the ripple of the output voltage of the power source 9 and the dimensions of the device.

Tests of the prototype of the inventive electronic switch were carried out in relation to an alternating current network using remote control from various household appliances of different companies and when giving different commands. With the corresponding separation in the space of the control objects, the electronic switch reliably worked only when directed with the help of the remote control. Moreover, interference from turning on and off household appliances, as well as exposure to bright daylight and artificial light, did not cause the operation of the claimed electronic switch. To increase noise immunity and reduce sensitivity to the signal reflected from surrounding objects, the IR receiver 1 can be equipped with a protective mask having an opening for the directional reception of infrared rays.

Tests of the inventive electronic switch showed its high performance, namely, high noise immunity, low heat, the absence of interference, the ability to switch not only light bulbs, as in the known device, but also any loads that require alternating current to power.

Thus, the set of distinctive features of the claimed electronic switch makes it a complete, highly reliable and very compact device with high performance, especially when implemented on open-frame and SMD components.

Sources of information:

1. Biryukov S. TV remote control controls the chandelier. // Radio, 1999, No. 12. - S. 32-33.

2. Rusin A. Lighting switch on infrared rays. // Radio, 2004, No. 2. - S. 47-48.

3. Bannikov V. The remote control controls the lamp. // Radio amateur, 1998, No. 12. - S.30-31.

4. Filipovich A. Electronic lighting switch. // Radio amateur, 2003, No. 5. - S.12-13.

Claims (11)

1. An electronic switch containing a receiving device capable of remotely receiving an encoded signal from an external control panel and converting it into a pulse sequence, a delay device whose input is connected to the output of the receiving device, a first pulse counter, a power unit in the form of one or more power switches for switching, respectively, of one or more loads, a power source and a signal shaper of the initial installation, characterized in that a second counter is introduced into the electronic switch pulses associated with the counting input with the output of the first pulse counter, and the outputs with the inputs of the corresponding power switches, and the first pulse counter with its counting input is connected to the output of the receiving device, the input of zeroing - with the output of the delay device, the input of the prohibition of counting - with its own output, and the input zeroing of the second pulse counter is connected to the output of the driver of the initial setting signal. 2. The electronic switch according to claim 1, characterized in that the receiving device is made in the form of an IR receiver. 3. The electronic switch according to claim 2, characterized in that the receiving device is equipped with a protective mask having a hole for directional reception of infrared rays. 4. The electronic switch according to claim 1, characterized in that the power switches are made in the form of alternating current switches, for example, on triacs. 5. The electronic switch according to claim 4, characterized in that the power unit is equipped with a circuit that provides switching power switches at the moments of passage of the switched voltage through zero. 6. The electronic switch according to claim 4, characterized in that each power switch is equipped with a circuit that provides switching when the switching voltage passes through zero. 7. The electronic switch according to claim 1, characterized in that the power keys are made in the form of keys with optical isolation between the inputs and outputs, for example, on opto-sims. 8. The electronic switch according to claim 7, characterized in that the inputs of the power switches are connected in series with each other and are connected to a power source through a common current-setting resistor, and the outputs of the second pulse counter are connected to the inputs of the power switches through buffer switches, for example, transistors connected in parallel mentioned power key inputs. 9. The electronic switch of claim 8, wherein the respective buffer transistors have opposite conductivity with respect to other buffer transistors. 10. The electronic switch according to claim 1, characterized in that the power source is transformerless with a quenching capacitor. 11. The electronic switch according to claim 1, characterized in that the output filter of the power source is made in the form of a U-shaped CRC filter.