KR950008178Y1 - Line interface devices for the remote controlling system - Google Patents

Abstract

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Description

Line interface device of remote meter reading system

1 is a diagram illustrating a line interface device of a remote meter reading system according to the present invention.

* Explanation of symbols for main parts of the drawings

11: central processing unit 12: memory (EEPROM)

13: line transformer 14: relay

16: high input impedance holding resistance 23: dual tone multi-frequency receiving circuit

24: modulator 30: reed switch

The present invention relates to a remote metering system for remotely reading power gas, water or calories, and more particularly, to easily transfer the accumulated amount read by a control signal from a remote metering center to a remote metering center. A line interface device of a system.

In general, the method of measuring usage such as electric power, water, gas, etc. is a method in which the meter reader directly visits the Gagaho Lake and reads the pulse, and detects the rotation of the numeric dial of the gas meter, water meter, or electricity meter to generate a predetermined pulse signal. Remote metering control command input through the interface from the remote metering center while counting and generating the pulse generator circuit and the pulses outputted from the pulse generator circuit to accumulate the gas, water, or power usage and saving them in memory. And a central processing unit for transmitting the accumulated amount of water, battery, or electricity to the remote meter reading center through an interface, and a power control unit for supplying power to each of these circuits.

However, in such a remote metering system, the function of the line interface is very important when transmitting the accumulated usage to the remote metering center according to the command signal received from the remote metering center. If noise occurs in the system, it may cause a problem that the remote metering center cannot accurately read it.

Accordingly, an object of the present invention is to provide a line interface device using a relay method in which the impedance of a transmission control signal to be input is kept very high and the current of the output signal is limited in view of such a situation.

The present invention for achieving this purpose is a pulse generator which is mounted to the numerical dial of the meter to generate a predetermined pulse signal in order to measure the amount of use, such as water, gas or electricity, and counts the above-mentioned pulse A central processing unit for generating a signal for saving and integrating the memory and transmitting the accumulated power data to the remote metering center according to a predetermined control; and receiving the control signal transmitted from the remote metering center, and receiving the central processing unit. A line interface device of a remote meter reading system having a dual tone multi-frequency receiver and a modulator for modulating and demodulating the integrated data according to a control signal input from the dual tone multi-frequency receiver, and transmitting the data to a remote meter reading center. It receives the control signal from the remote metering center and receives the dual tone multi-frequency. And a line transformer for transmitting the accumulated data output from the above-described demodulator to the remote meter reading center, and a signal generated from the central processing unit at the time of transmitting the integrated data as input. A relay for controlling the line transformer to transmit to the meter reading center, a high input impedance holding unit for maintaining a high input impedance of the line transformer when a control signal is received, and a current for limiting the current when transmitting the accumulated data It is made up of limited parts.

According to the present invention, it is preferable that the high input impedance holding unit is configured to be connected to the primary winding of the line transformer so that the capacitor for removing the residual voltage when receiving the control signal and the high input impedance holding resistor are connected in series. It is preferable that the resistor and the capacitor for constituting the current when transmitting the accumulated data are connected in parallel to the primary winding of the line transformer.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a circuit diagram of a remote meter reading system incorporating a telephone line interface device according to the present invention. The DC voltage (+ Vcc), which may be rectified by DC in a rectifier circuit or supplied from a battery, may be It is supplied to the circuit of each part as a power supply.

In the state in which the power supply (+ Vcc) is supplied, when the rotation of the numeric meter (not shown) or the numeric dial of the gas meter or water meter is stopped, the signal through the resistor 1 is transferred through the resistor 2 to the condenser 3. ) Is applied to the inverter 5 via the resistor 4.

At this time, the inverter 5 inverts the input high state signal to the low state to the inverter 10 through the differential circuit consisting of the capacitor 6 and the resistor 7 and the rectifying diode 8 and the resistor 9. to provide.

Then, the inverter 10 inverts the low state signal to a high state so that the interrupt request terminal of the central processing unit 11 ( To provide. In this case, the central processing unit 11 recognizes this signal and does not perform counting of the pulses to maintain the standby state.

However, when the magnet attached to the numeric dial of the meter (not shown) rotates together when the numeric dial is rotated to operate the reed switch 30, the reed switch 30 is turned on. The voltage signal that was charged in the capacitor 3 is discharged at the moment when is turned on, and when the reed switch 30 is turned off again, the capacitor 3 charges the voltage.

However, when the discharge voltage of the condenser 3 drops below a predetermined voltage level, the output of the inverter 5 becomes high, and when the voltage charged to the condenser 3 increases to high, the output of the inverter Outputs a low state signal, and as a result, the inverter 5 outputs one pulse signal.

At this time, the signal output from the inverter 5 is differentiated by the differential circuit composed of the capacitor 6 and the resistor 7. In this case, the diode 8 detects only the positive (+) part of the differential signal and the resistor 9. It is applied to the inverter 10 through.

Inverter 10 then inverts the signal in the high state to the low level so that the interrupt request terminal of the central processing unit 11 ( ). Therefore, the central processing unit 11 recognizes this and performs a counting operation of the pulse. The counted data can be stored in the memory 12 (EEPROM) and transmitted to the remote meter reading center as described later. .

If there is a command control signal for transmitting the accumulated data from the remote meter reading center, the transmission command control signal is transmitted through the tip / ring terminal (TIP / RING) of the telephone line (Lp) of the line transformer 13. In this case, the current through No. ① of the winding Lp is applied to the condenser 15 through the relay switch 14A constituting the relay 14.

The capacitor 15 removes the DC voltage so as to pore the input signal (starting voltage signal) to the resistor 16 and the capacitor 17 connected in series, where the resistor 16 maintains a high input impedance. It is for.

However, upon receiving such a control command, the relay 14 receives the high output of the relay drive 18 operating by receiving a signal generated from the central processing unit 11 and maintains the state shown in FIG.

On the other hand, a signal 1: 1 induced in the winding Ls of the line transformer 13 is applied to the relay switch 14B, where the zener diodes 19A and 19B serve to remove the ring signal. .

The signal from which the ring signal is removed is applied as a predetermined frequency signal to the dual tone multi-frequency receiving circuit 23 through the relay switch 14B, the coupling capacitor 20, and the resistors 21 and 22.

Then, the dual tone multi-frequency receiving circuit 23 transmits the binary code signal corresponding to the control command signal input through its output terminals Q _{0 to} Q ₄ ) to the address terminals A ₀ to of the central processing unit 11. A ₄ ).

In response to these address signals A _{0 to} A ₄ , the central processing unit 11 provides a chip select signal to the memory 12 to read accumulated data that has been saved in the memory 12. The accumulated data thus read is provided to the demodulator 24 through the transmission data output terminal TDO.

In this case, the central processing unit 11 controls the relay drive 18 to transmit accumulated data so that the low signal output from the output terminal Y ₁ thereof is provided to one terminal of the relay coil 14c.

As one terminal of the relay coil 14c goes low, a current flows in the relay coil 14c, and accordingly, an electromagnetic force is generated, so that the relay switches 14A and 14B have a lower contact point opposite to that shown in FIG. It is moved in contact with.

As the relay switches 14A and 14B are moved downward in contact with each other, the integrated data signals output from the modulator 24 are provided to the line transformer 13 through the resistors 25 and 26 and the relay switch 14c.

At this time, the current of the winding Lp induced by the winding Ls of the line transformer 13 is limited by the resistor 27 and the condenser 28 connected in parallel, so that the integrated data transmitted can be stabilized.

When the transmission of such data is completed (that is, there is no control command signal from the remote detection center), the central processing unit 11 turns the relay 14 off by relaying the output of the relay drive 18 high. The switches 14A and 14B are switched to the position shown in FIG. 1 to wait for the control command signal from the remote metering center and perform counting of normal pulses.

The present invention operates as described above, while maintaining the high input impedance while waiting for the meter data transmission command signal from the remote metering center, and limiting the current when transmitting the accumulated data, thereby providing accurate accumulated data to the remote metering center. Will have.

Claims (3)

In order to measure the amount of use such as water, gas, electricity, etc., a pulse generator is mounted on the numeric dial of the meter to generate a predetermined pulse signal, and the power is counted in the memory by counting the pulses and accumulated and simultaneously controlled. A central processing unit for generating a signal for transmitting the accumulated power amount data to a remote metering center, a dual tone multi-frequency receiver for receiving a control signal transmitted from the remote metering center and providing the signal to the central processing unit; Claims [1] A line interface device of a remote meter reading system having a modulator for modulating and demodulating the integrated data according to a control signal input from a dual tone multi-frequency receiver of the present invention to a remote meter reading center. A line transformer 13 for providing a control signal from the remote meter reading center to the dual tone multi-frequency receiver 23 and transmitting accumulated data output from the modulator 24 to the remote meter reading center; ; Relay 14 for controlling the above-mentioned line transformer 13 to transmit the integrated data output from the modulation / demodulator 24 to the remote meter reading center by inputting a signal generated from the central processing unit 11 when transmitting the integrated data. )Wow; A high input impedance holding part connected to the relay switch 14A of the relay 14 to maintain a high input impedance of the line transformer 13 when the control signal is received; A line interface device of a remote meter reading system, characterized in that it is connected to a relay switch (14A) of a relay (14) and configured with a current limiting unit for limiting a current induced in the winding (Lp) during the integrated data transmission. 2. The capacitor according to claim 1, wherein the high input impedance retainer is connected to the primary winding of the line transformer 13 through a relay switch 14A to remove the DC voltage when receiving a control signal. Line interface device of a remote meter reading system, characterized in that the resistor 16 is connected in series. The current limiter of claim 1, wherein the resistor 27 and the condenser 28 for limiting the current when transmitting the accumulated data are connected in parallel with the line transformer 14 to the primary winding through a relay switch 14A. Line interface device of a remote meter reading system, characterized in that.