KR910007399B1 - Device which transfers data inspected remotely - Google Patents

Abstract

The circuit transmits the measured data in serial to the receiver for checking the consumption of gas, water, or electricity of each home. The secret code of a central meter (6) is transmitted to a controller (4) at the home for driving a counter (2) and the data transmitter (3). Then the measured data is transmitted to the central meter through a switching circuit (5). The controller (4) comprises a decoder (DC) comparing the received secret code, flip-flops (FF1-4), a timer (TM), and a clock generator (CK).

Description

Remote meter reading data transmitter

1 is a block diagram of the present invention.

2 is a circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

1: display unit 2: display driving and counting circuit

3: detection signal switching and transmission circuit 4: control circuit

5: switching circuit 6: central meter reading part

DC: Decoder CK: Clock Generation Circuit

IN ₁ , IN ₂ : Inverter KE: Key Encoder

TM: Timer circuit FF ₁ -FF ₄ : Flip-flop

G ₁ -G ₈ : Gate

The present invention relates to a data transmission device for remote meter reading, and in particular, to transmit the data of the accumulated amount read from the water, electricity, gas meter, etc. so that the receiving side can read the accumulated amount so as to receive the usage or fee used at each customer. The main focus is on what can be calculated from the side.

In general, in order to read the amount of water, electricity, gas, etc., the meter reads the usage amount by visiting each receiver directly, and then calculates the usage fee according to the amount of usage. Therefore, there was a problem that the meter reader had to visit each day to grasp the usage of each customer. Therefore, in order to solve the above problem, the applicant has been able to read the usage amount electronically in the patent application No. 87-3462 and Utility Model Registration Application No. 87-5100, which are filed by the applicant, but can transmit the data of the read usage amount. There was a problem that remote meter reading is impossible.

The present invention solves the above problems, and by sending the data read by the metering device in a time-division manner, it is possible to determine the amount of usage at the receiving side, so that it is possible to read the amount of usage without visiting each customer. As described, according to the accompanying drawings as follows.

As shown in FIG. 1, the output of the display driving and counting circuit section 2, in which the detection signal is inputted by the meta device, is connected to the inputs of the display section 1 and the detection signal switching and transmission circuit section 3, respectively. The circuit part 3 is connected to the output via the switching circuit 5 to the central meter reading part 6, and the output coded signal of the central meter reading part 6 is connected to the control circuit part 4 via the switching circuit 5. By driving the display driving and counting circuit unit 2 and the detection signal switching transmission circuit unit 3 to control the display driving and counting circuit unit 2.

FIG. 2 is a detailed circuit diagram of the apparatus of the present invention shown in FIG. ₁ , and the output of the display driving and counting circuit unit 2 in which the detection signal of the meta device is applied to the input terminal I ₁ with the adjusted signal of the train is shown in FIG. It is applied to each segment of the display unit 1 via an inverter IN ₁ (IN ₂ ), and the output terminals A, B, C, D of the counting circuit unit 2 are switched circuits SI ₁ (SI ₂ ). To be applied to the key encoder KE.

The output of the key encoder KE is detected by being switched to the telephone or the central metering section 6 via the switching circuit section 5 that constitutes the relay RY and the switching switches Y ₁ , Y ₂ , Y ₃ . Send a signal. In addition, the encryption corresponding to the control circuit unit 4 which connects the decoder DC, the flip-flops FF _1- FF ₄ , the clock generation circuit CK, the timer circuit TM, and the gates G _1- G ₈ . When a signal is applied from the central meter reading section 6, the counting circuit section 2 and the transmission circuit 3 are controlled.

Referring to Figures 1 and 2 the effects of the present invention configured as described above are as follows.

First, when the data of the amount of usage detected from the electronic meta-device (water, electricity, gas), not shown in FIG. 1, is applied to the display driving and counting circuit 1, the counting circuit 2 as shown in FIG. By using the integration factor, the accumulated usage amount is displayed on the display 1.

In this way, the display driving and counting circuit 2 executes a predetermined program relating to the meter reading from the host computer, not shown, of the central meter reading unit 6 set in the operating station to read the accumulated amount during the counting of the amount of usage. To transmit an encryption signal for the meter reading instruction. At this time, the encryption signal transmitted from the central meter reading unit 6 is loaded on the telephone line L ₁ (L ₂ ) as shown in FIG. ₂ and transferred to the decoder DC of the control circuit 4 through the switching circuit 5. do. In this case, the cipher signal transmitted from the central meter reading part 6 sets and transmits a signal of a frequency band which is not present in the dial of the telephone so as not to be affected by side sound from the external telephone, that is, to prevent frequency interference with the outside.

When the encryption signal of the central reading unit 6 is transmitted to the decoder DC of the control circuit 4, the decoder DC of the control circuit 4 compares with the encryption signal of three units set in advance. Will be determined. At this time, if each encryption signal coincides with each other, the decoder (DC) outputs the data converted into the BCD code (binary code data), and the BCD output data is compared with the AND gate (G ₁ ) (G ₂ ) and logical sum. Input the high level to the first flip-flop FF ₁ to clear it, and at the same time, maintain the output terminal of the first flip-flop FF ₁ high to transmit the accumulated usage data in the display driving and counting circuit 2. Set up the preparation steps so that they can

That is, when the first flip-flop FF ₁ is cleared, the second and third flip-flops FF ₂ FF ₃ are cleared at the same high level, and the output terminal of the second flip-flop FF ₂ is cleared. Through this, a signal forcibly setting the scanning time of the display driving and counting circuit 2 is output. At this time, the counting circuit 2 by the scanning time setting signal starts scanning according to the set scanning time (100ms), and the counting circuit 2 in the state where the second flip-flop FF ₃ is operated by the above. When the one-digit digit signal output to the indicator 1 becomes low level to high level, the high level is output from the output terminal of the third flip-flop FF ₃ .

By the high level, the transistor of the switching circuit section 5 is turned on and the relay Ry is excited to switch its contacts Y ₁ -Y ₃ to a state in which the integrated data of the counting circuit 2 can be transmitted. Therefore, the flip-flop FF ₃ detects the unbalanced scanning of the counting circuit 2 and transmits the signal from the unit of one when one unit comes.

At the same time, through the NAND gates G ₅ -G ₈ connected to the output terminal of the clock generation circuit CK and the third flip-flop FF ₃ , a constant pulse is generated from the time when the display driving and counting circuit 2 scans. In this case, the timer circuit TM counts the number of pulses transmitted from the clock generation circuit CK to enable or disable the switching circuit SI ₁ (SI ₂ ) according to the pulse. To control.

By the control signal of the control circuit 4, the switching circuit SI ₁ (SI ₂ ) breaks down the values in the BCD of the counting circuit 2 one by one from six units in turn and inputs them to the key encoder KE. Done. At this time, the key encoder KE performs a time conversion of the time-divided data by converting the BCD data accumulated by the counting circuit 2 to the tone frequency so as to be carried on the carriers of the charge lines L ₁ and L ₂ . Step by step will be performed. Thereafter, the timer TM resets the flip-flop FF ₁ (FF ₄ ) by supplying a low pulse to the NOR gate G ₃ when 15 pulses are counted, and flip-flop FF ₁ (FF ₄ ). When is reset, the flip-flop FF ₃ (FF ₄ ) is reset at the same time, thereby completing the integrated data transfer.

At this time, since it is reset at the same time as the flip-flop (FF ₁ ) (FF ₄ ), the output of the flip-flop (FF ₁ ) becomes low, and the telephone line terminal relay is returned to the original state to enable the telephone call, and the counting circuit 2 is scanned. The time is restored to a steady state, and the water, electricity, and gas meters complete the integrated data transfer. Therefore, the signal transmitted on the carrier lines of the telephone lines L ₁ and L ₂ receives data from the central reading unit 6 of the operating station. The central reading unit 6 reads the received data by the host computer, not shown. The demodulated signal can be demodulated so that the demodulated signal is converted into a BCD code and stored in its memory, and the amount used is calculated by a predetermined fee calculation program.

As described above, according to the present invention, when the train control signal is properly inputted to the output signal of the meta device installed in each customer, the signal is displayed on the display so that the user of each customer can easily know the usage amount. By transmitting the data, it is possible to grasp the receiving unit, which is the central meter reading unit, so that the usage of each consumer can be grasped without visiting each customer, thereby reducing the manpower waste to the maximum, and the desired customer by the encryption signal of the central meter reading unit. The amount of electricity, water, and gas used in the bay can be read very dramatically.

Claims (3)

A signal detected by the gas, the water, and the electric meter installed in each consumer to be displayed on the display 1 through the display driving and counting circuit 2, and transmitted to the central metering section 6 for reading; When an encryption signal corresponding to the central meter reading section 6 is applied to the control circuit section 4, the counting circuit 2 and the detection signal switching and transmission circuit 3 are driven to output the switching circuit 3 to the switching circuit ( 5) remote meter reading data transmission device, characterized in that the connection configuration to transmit data to the central meter reading unit (6). 2. The control circuit (4) according to claim 1, wherein the control circuit (4) comprises a decoder (DC) for comparing the cipher signals of the central reading unit (6), flip-flops (FF _{1 to} FF ₄ ), a timer circuit (TM), and a clock generation circuit. And a connection control signal to the counting circuit (2) and the switching circuit (SI ₁ ) (SI ₂ ) of the transmission circuit (3) by connecting (CK). The detection according to claim 1 or 2, wherein the output data of the counting circuit (2) is connected to the switching circuit (SI ₁ ) (SI ₂ ) and the key encoder (KE) by the output signal of the control circuit (4). Remote meter reading data transmission device characterized in that the connection is configured to be transmitted to the central meter reading section through the signal switching and transmission circuit (3) and the switching circuit (5).

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