KR920009161B1 - Transmitter for remote ac power controller - Google Patents

Abstract

The device is for transmitting three control signals with different pulse widths from each other to a receiving device to control AC electricity remotely. It includes an oscillator (1), a rectangular wave generator (2), a counter (3) for counting the rectangular signal from the generator (2) and generating rectangular signal, 1st, 2nd and 3rd switching sections (4,5,6), a combiner (7) with an OR gate (OG2) combining the outputs of the three switching sections (4,5,6), and an ultra-reproducing signal generator (8) for generating sine wave having constant frequency when the output signal of the combiner (7) is at high level.

Description

Transmission device of remote AC power controller

1 is a circuit diagram showing an apparatus for transmitting a remote AC power controller according to an embodiment of the present invention.

2 and 3 are waveform diagrams of respective parts of the remote AC power controller.

The present invention relates to a remote AC power controller, and more particularly, to a transmitter of a remote AC power controller for transmitting remote control signals of three states having different pulse widths.

Remote AC power controller to control AC power remotely is widely used for the prevention of industrial accidents and convenient use of electrical appliances.

The remote AC power controller is composed of a receiving device which receives a control signal transmitted from the transmitting device of the transmitting device which transmits the control signal, converts it into a digital signal, and supplies it to the power control circuit.

The present invention relates to a transmitter of the remote AC power controller, and the transmitter is basically required a power on signal, a power rising and falling signal in order to remotely control the AC power.

It is an object of the present invention to provide a transmitter of a remote AC power controller for transmitting three control signals having different pulse widths to a receiver for remote AC power control.

The present invention for achieving the above object is an oscillator for oscillating a signal having a constant frequency, a square wave generator for outputting a square wave signal to the oscillation signal of the oscillator and the square wave generator to count the square wave signal output A counter for outputting a square wave signal to a terminal, a first switching unit for outputting a signal by combining the square wave signal of the counter and a signal according to the on / off of the first switch, the square wave signal of the counter and the on of the second switch A second switching unit for outputting a combination of signal paths according to on / off and a third switching unit for combining and outputting one output signal of a signal output from the output terminal of the counter with a signal according to on / off of the third switch A combining unit comprising an unit, an oragate combining the outputs of the first switching unit, the second switching unit, and the third switching unit, and an output signal of the combining unit Seven days is configured a certain frequency portion crude reproduction signal to output a sine wave having belil time.

Hereinafter, an embodiment of a transmitter of a remote AC power controller according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a circuit of a transmitter of a remote AC power controller according to the present invention.

As shown in FIG. 1, an oscillator 1 oscillating a signal having a constant frequency is connected to the square wave generator 2 so as to convert the output signal of the oscillator 1 into a square wave. Then, the square wave generator 2 is connected to a counter 3 having an N bit value, the square wave signal input to the counter 3 is counted, and the output terminal of the counter 3 is counted according to the counter value. A square wave signal is output through (TD _{1 to} TD _n ). This square wave signal is shown as TD ₁ to TD _n in FIG. 2 and will be described later.

The first switching unit 4 for outputting a combination of output signals output to the output terminals TD _{1 to} TD _n of the counter 3 and other signals on / off of the first switch S ₁ may be used. The output terminals TD _{1 to} TD _n of the counter 3 are connected to the input terminals of the gate AG ₁ .

And the AND gate connected to the first switch (S ₁₎ to the AND gate (AG ₂₎ for applying the output to the AND gate (AG ₂₎ while configured to be connected to the power supply (VCC) of the AND gate (AG ₁₎ The output signal of AG ₁ and the signal according to the on / off of the first switch S ₁ may be combined in the AND gate AG ₂ .

The second switching unit 5 which combines the output pulses of the counter 3 and other signals on and off of the second switch S ₂ outputs the output terminals TD _{1 to} TD _n of the counter 3. It is configured by connecting to the OA gate (OG ₁ ).

In addition, the output of the OG ₂ is applied to the AND gate AG ₃ while the second switch S ₂ configured to be connected to the power supply VCC is connected to the AND gate AG ₃ to connect the AND gate. The output of AG ₃ and the signal according to the on / off state of the second switch S ₂ are configured to be combined in the AND gate AG ₃ .

The third switching unit 6 which combines and outputs one of the output signals output from the output terminals TD _{1 to} TD _n of the counter 3 to the signal according to the on / off of the third switch S ₃ is provided. The third switch S ₃ configured to be connected to the power supply VCC is connected to a timer TM that outputs a square wave pulse of the high bell for a predetermined period when the power supply is input. The third switching unit 6 outputs one of the output signal of the timer TM and the output signal output from the output terminals TD _{1 to} TD _n of the counter 3 to the AND gate AG ₄ . It is configured to be combined by applying to.

The combination unit 7 for ORing the outputs of the first switching unit 4, the second switching unit 5, and the third switching unit 6 is composed of an oragate OG ₂ .

The super reproduction signal generator 8 is connected to the rear end of the ora gate OG ₂ , and the super reproduction signal generator 8 is an input signal, that is, an output signal of the ora gate OG ₂ is high level. In this case, a sine wave having a corresponding frequency is output.

Reference numerals a-j denote respective output stages, and the output signals of the output stages are shown in FIGS. 2 and 3 by the same reference numerals.

The operation of the transmitter of the remote AC power controller configured as described above will be described with reference to the respective waveform diagrams of FIGS. 2 and 3.

In order to control AC power remotely, this transmitter basically sends control signals in three states. That is, the power on signal, the power rising and falling signals. This signal is the output signal j of the super reproduction signal generator 8 of FIG. These are represented by j respectively in the reference numerals of FIGS. 3A to 3C.

First, the oscillator 1 outputs a signal having a constant frequency, that is, a signal having a waveform as shown in FIG.

The square wave generator 2 receiving the oscillation signal a converts the oscillation signal a, which is a sine wave, into a square wave signal b and outputs the square wave signal b. The oscillation unit 1 and the square wave generator 2 are generalized blocks.

The counter 3 that counts the square wave signal b as a clock signal outputs the countered signal through its output terminals TD _{1 to} TD _n . The counter 3 is an N-bit down counter whose initial state starts at (1,1,1 ... 1). The output terminal signals of this counter 3 are shown in FIG. ₂ by reference numerals TD ₁ , TD ₂ , and TD _n , respectively.

The counter 3 an output signal _{(TD 1, TD 2, TD} n ) of the AND gate for logic multiplying the first switching combining unit (4) (AG ₁₎ is the output signal _{(TD 1, TD 2, TD} n of ) Is outputted in the high level state, so the output signal of the AND gate AG ₁ is equal to that of FIG.

The oragate OG ₁ of the second switching 5 for ORing the output signals TD ₁ , TD ₂ , and TD _n of the counter 3 has the output signals TD ₁ , TD ₂ , and TD _n . Since all of the low level signals are output when the low level state is input, the oA gate OG ₁ outputs a signal as shown in FIG.

In this state, for example, when the third position P3 is pressed, the timer TM outputs a signal as shown in FIG. 2E which maintains a high level state for a predetermined time. The signal shown in FIG. 2 (f) is output through the AND gate AG ₄ of the third switching unit 6.

In the same manner, the signals shown in FIGS. 2C and 3D are respectively transmitted through the AND gate AG ₃ and AG ₄ by the first switch S ₁ and the first switch S ₂ , respectively. Signals such as (c) and (h) of FIG. 3 are outputted.

By turning on the first, second and third switches S ₁ , S ₂ , and S ₃ of the first, second and third switching parts 4, 5, and 6. The output signal is a falling, rising and power on signal.

First, when the first switch S ₁ is turned on, as shown in FIG. 3A, when the output signal c of the AND gate AG ₁ is in a continuous state, the first switch S ₁ is turned on. The signal S ₁ is outputted. The AND gate AG ₂ which logically multiplies the signals c and S ₁ outputs a signal g. The signal g outputs the power drop control scene j through the super reproduction signal generation stage 8.

Next, when the second switch S ₂ is turned on, when the output signal d of the orifice OG ₁ is continuous, as shown in FIG. 3B, the second switching S ₂ is turned on. The signal S ₂ is output. The AND gate AG ₃ which logically multiplies the pulses d and S ₂ outputs a signal h. The signal h outputs a power increase control signal j through the super reproduction signal generator 8.

When the third switch P ₃ is in the on state, as shown in FIG. 3C, the tire TM has a high level for a predetermined time according to the on of the third switch P ₃ . Will print The signal (e) and output signals (TD ₂₎ of the output terminal (TD ₂₎ of the counter 3 and outputs a signal (f) is multiplied by a logic AND gate (AG _4). This signal f also outputs the power-on control signal j via the fraudulent super reproduction signal generation stage 8.

In this way, the remote control signals generated by the operation of the first, second and third switches, that is, three status signals of the power on signal, the power up and the down signal, should not be generated at the same time. Therefore, the first switch (S ₁ ), the second switch (S ₂ ) and the third switch (S ₃ ) is a push button (Push button) so as not to be turned on in the city to indicate the switch on state while being pushed It can be configured to.

In this configuration, when one of the first, second and third switches is on, the other signal is kept off. Therefore, the oA gate OG ₂ of the combination portion 7 which combines the outputs of the first switching portion 4, the second switching portion 5 and the third switching portion 6, has only one signal selected among them. The super reproduction signal generator 8 is applied.

The present invention combines the signal applied by the operation of the switch with the oscillating square wave signal to transmit a signal having a different pulse width according to the switch, so that the receiver can output a control signal according to a signal having a different pulse width to be transmitted. To be.

Claims (4)

The oscillation unit 1 receives a signal having a constant frequency, a square wave generator 2 for outputting a square wave signal as the oscillation signal of the oscillator 1, and the square wave signal of the square wave generator 2 to count The counter 3 outputs a square wave signal to the output terminals TD ₁ , TD ₂ , and TD _n , and the square wave signal of the counter 3 and the signal according to the on / off of the first switch S ₁ are combined. A first switch unit 4 for outputting a signal, a second switching unit 5 for outputting a combination of square wave signals of the counter 3 and signals according to on / off of the second switch S ₂ , and Third switching unit 6 for combining and outputting one of the signals output from the output terminal (TD ₁ ~ TD _n ) of the counter 3 to the signal according to the on / off of the third switch (S ₃ ) ), A combination unit 7 composed of an oA gate OG ₂ combining the outputs of the first switching unit 4, the second switching unit 5, and the third switching unit 6, and And a super reproduction signal generator (8) for outputting a sine wave having a predetermined frequency when the output signal of the combination unit (7) is at a high level. The first switch 4 of claim 1, wherein the first switching unit 4 includes an AND gate AG _{1 which} multiplies the output signal of the counter 3, an output of the AND gate AG ₁ , and the first switch S. ₁ ) Transmitter of the remote AC power controller, characterized in that it consists of an AND gate (AG ₂ ) to multiply the signal according to the on / off. According to claim 1, wherein the second switching unit (5) is an OR gate (OG ₁ ) for ORing the output signal of the counter 3, the output of the OG gate (OG ₁ ) and the second switch (S ₂₎ Transmitter of the remote AC power controller, characterized in that it consists of an AND gate (AG ₃ ) to multiply the signal according to the on / off. According to claim 1, The third switching unit 6 is a timer (TM) for outputting a high level signal for a predetermined time when the third switch (S ₃ ) is turned on, and the output of the timer (TM) And an AND gate (AG ₄ ) which is ANDed with a signal and one of the output signals of the counter (3).

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