KR20000021492U - Calendar Functionated Wireless Building Meters Checking System - Google Patents

Abstract

The present invention is a wireless metering system that minimizes the battery power consumption by displaying the total meter reading value of water, electricity, gas meter and calorimeter on a monthly basis. In normal times, the microcomputer integrates the pulse value of the meter sensor part consisting of a Hall sensor or a photo sensor with a minimum power supply. The wireless meter receiver includes a transmitter / receiver and a meter signal filter unit. The wireless meter receiver waits with a minimum power and interrupts the microcomputer when a specific frequency of the external wireless meter is input. The microcomputer sends and receives monthly data according to the command of the wireless meter reader. The meter sensor unit, microcomputer and wireless meter receiver operate 2m / s every 2 seconds. Accurate reading of the desired month is possible, and the battery current consumption is reduced to 1 / 1,000.

Description

Calendar functionated wireless building meters checking system for various building meters with calendar function

The present invention relates to a wireless meter reading system capable of randomly accumulating and displaying the reading values of water, electricity, gas meter and calorimeter on a monthly basis, and in particular, a method of transmitting and receiving a radio meter and frequency while minimizing battery consumption. to be.

Existing counters integrate pulse values from water, electricity and gas meters and display only the final value. The display means is a mechanical counter attached to a meter, or an electronic counter of a radio frequency transmission / reception system installed at another place away from the counter, or a method of reading accumulated values (integrated values) through wired remote transmission and reception has been proposed. In this case, the flow rate is read as a pulse value through a sensor that attaches a magnet to the rotating plate of the meter and makes the reed switch connected with the magnetic force when making one revolution, and the pulse value is continuously integrated in the central processing unit for display or the data value is displayed. In addition, it will be transmitted to the remote terminal as it is to be stored. Therefore, on the same day of every month, the bill is charged with the current month minus the previous month's cumulative value.

In the above, the meter reading through the wired transmission and reception is a method of calculating the data stored in the terminal through a separate computer program, and various problems have occurred and have not been executed for a long time. The most reliable and realistic way to read the meter is to visit each building and read the accumulated value through a mechanical or electronic counter. For these visits, the meter should be read on the same day of the month by the meter to calculate the exact monthly fee.

However, it is practically impossible for a meter reader to read every user on the same day each month. Therefore, the situation is to charge a roughly calculated average. As a result, many complaints have occurred in the process of charging. In addition, even if a radio frequency transmission and reception method is employed, the counter consumes a lot of current, and therefore, when an AC power source is used, it is limited to an installation place or a metering place. In addition, since the sensor attached to the conventional meter is a reed switch contact method that allows the reed switch to turn on and off when the rotating plate is rotated, the microcomputer counts the number of revolutions.

The purpose of the present invention is to add a calendar function to the electronic counter to automatically display the cumulative value for every one month, and to read the specific data value displayed by the external wireless meter reader on the same day every month. It is to ensure that accurate reading of the desired month can be done by radio frequency transmission and reception without having to read the data.

Another object of the present invention is to maintain the electronic counter with a minimum current consumption while using battery power, and to filter the meter signal so that data can be transmitted and received only when necessary, and also has low current consumption and low defects. It is to be able to count the number of revolutions of the meter by the Hall sensor or photosensor method.

1 is an overall configuration of an embodiment of the present invention.

2 is a circuit diagram showing an embodiment of a meter sensor unit of the present invention.

3 is a circuit diagram showing another embodiment of the meter sensor unit of the present invention.

<Explanation of symbols for main parts of drawing>

1: Meter sensor part, 2: Real time clock (RTC), 3: Microcomputer (CPU + EPROM), 4: Meter reading signal filter part, 5: Transmitter / receiver part, 6: Hall sensor, 7: Photo sensor, 8: Meter, 12: display, 13: wireless meter reader

In order to achieve the above object, the present invention provides a meter sensor unit for detecting whether the meter rotating plate is rotated while only 2 m / s of power is supplied to the hall sensor or the photo sensor every two seconds, and the first rotation signal of the meter sensor unit. A microcomputer that wakes up every time and accumulates and stores the rotation value of the meter by real time clock and by monthly using a real time clock, and when a signal is given to an interrupt port, wakes up and outputs data corresponding to an external meter reading signal, and checks whether or not it is received. It operates according to the power supplied by 2m / s every 2 seconds, when receiving a metering signal of a specific frequency signal to the interrupt port of the microcomputer consists of a wireless meter receiving unit for transmitting the data of the microcomputer wirelessly.

The present invention, according to the configuration as described above, the microcomputer is normally displayed by simply integrating the pulse value of the meter sensor unit consisting of a Hall sensor or a photo sensor with a minimum power supply. The wireless meter receiver includes a transmitter / receiver and a meter signal filter unit. The wireless meter receiver waits with a minimum power and interrupts the microcomputer when a specific frequency of the external wireless meter is input. The microcomputer sends and receives monthly data according to the command of the wireless meter reader. Intermittent operation of the microcomputer, wireless meter receiver and meter sensor unit every 2 seconds, as in the present invention, reduces the current consumption of the battery to 1 / 1,000 compared to continuous operation.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a block diagram and a circuit diagram showing an overall configuration, and FIGS. 2 and 3 show two embodiments of a meter sensor unit. In the embodiment, it consists of a meter sensor unit 1, a real time clock 2, a microcomputer 3, a meter signal filter unit 4, and a transceiver unit 5. The meter reading signal filter unit 4 and the transceiver unit 5 correspond to the wireless meter reading unit of the present invention.

The meter sensor part 1 uses the hall sensor 6 like FIG. 2, and the photo sensor 7 like FIG.

In the case of using the Hall sensor 6, a magnet 10a is attached to a point on the upper surface of the rotating plate 9a such as a water meter 8, that is, a water meter, an electric meter, a gas meter, a calorimeter, and the magnet 10a is located close to the magnet 10a. The Hall sensor 6 is provided at the position, and the Hall sensor 6 is connected with the transistor TR ₁ and the interface 11a. Thus, when the interface 11a biases the base of the transistor TR ₁ every 2 m / s for about 2 seconds, current flows between the collector and the emitter so that the hall sensor 6 operates. Then, it takes about 5 seconds for the rotating plate 9a to rotate once, so that when the Hall sensor 6 is turned on by 2 m / s every 2 seconds as described above, the rotation of the rotating plate 9a causes the interface 11a to be rotated. Is sent to the microcomputer (3). The interface 11a wakes up the microcomputer 3 in the stop mode every time it sends a rotational value of one revolution to the microcomputer 3 as a pulse. When the microcomputer 3 detects the one-turn signal of the meter 8, the microcomputer 3 accumulates and stores the EPROM and immediately returns to the stop mode.

When the photosensor 7 is used, a black mark 10b is attached to a point on the upper surface of the rotating plate 9b such as a water meter 8, that is, a water meter, an electric meter, a gas meter, a calorimeter, and the mark 10b is The photosensor 7 which has a light receiving part and a light emitting part is provided in the position which adjoins, and the transistor TR ₂ and the interface 11b are connected to the photosensor 7. Thus, when the interface 11b biases the base of the transistor TR ₂ every 2 m / s for about 2 seconds, current flows between the collector and the emitter so that the photo sensor 7 operates. Then, it takes about 5 seconds for the rotating plate 9b to rotate one time, so if the Hall sensor 6 is turned on by 2 m / s every 2 seconds as described above, one rotation of the rotating plate 9b is made black and (mark). It is recognized as a change of white color and sent to the microcomputer 3 via the interface 11b. The interface 11b wakes up the microcomputer 3 in the stop mode whenever it sends a rotational value of one revolution to the microcomputer 3 as a pulse. When the microcomputer 3 detects the one-turn signal of the meter 8, it is integrated, stored in the EPROM, and immediately returns to the stop mode.

The microcomputer 3 basically has a central processing unit (hereinafter referred to as a CPU) and an EPROM (EPROM), a display (LCD) 12, a real time clock (hereinafter referred to as RTC) (2), and a meter signal. The filter part 4, the meter sensor part 1, etc. are connected. The real time clock 2 stores time information on the year, month, and day and continuously outputs real time to the CPU. The real time clock 2 also serves to bias the base of the transistor TR every two seconds. This pyrom (erase-type pyrom) performs a function of storing the data of the CPU only when the CPU is interrupted and outputting the data to the meter reading signal filter unit 4.

The CPU of the microcomputer 3 basically wakes up in the stop mode according to the interrupt instruction of the meter reading signal filter section 4 and transmits and receives data to and from the meter reading signal filter section 4 according to the requested instruction of the external wireless meter reading unit 13. do. This is to allow the CPU to minimize battery drain. The CPU detects the pulse value of the meter sensor unit 1, stores data for each real-time band input from the RTC 2, outputs the month and the accumulated value to the display 12, and reads the meter reading signal filter unit 4 ), The cumulative value of each month and the corresponding month is calculated, and the data is output to the meter reading signal filter section 4 together with the unique code signal given to the meter 8. Whenever a signal is output, the CPU of the microcomputer 3 checks whether the signal responding from the external wireless meter reader 13 matches with the data signal originally sent, and repeats if it does not match. If the unique code signal to be transmitted / received initially does not match or the signal of the wireless meter reader 13 does not arrive in reverse within one minute after outputting the data signal, the interrupt port INT is enabled and the stop mode is enabled. Return to

The meter signal filter unit 4 operates only when there is a signal from the transceiver unit 5, and when the meter signal is correct when the meter signal signal unit 4 starts operation, the interrupt of the microcomputer 3 is interrupted. This will interrupt the port (INT). This is to minimize the current consumption of the battery. The metering signal filter unit 4 further employs a method other than the interrupt command method as a method for reducing current consumption of the battery. It refers to biasing the base of the transistor TR in the real time clock 2 about 2 m / s every 2 seconds. This is to minimize the current consumption of the battery by allowing the metering signal filter unit 4 and the transceiver unit 5 to be in a standby state at ordinary times. That is, when power is supplied to the meter reading signal filter section 4 and the transmission / reception section 5 by 2 m / s every two seconds by the real time clock 2, the meter reading signal filter section 4 detects a specific pulse signal of a specific frequency. If a specific pulse is detected and a specific pulse comes in, the interrupt port (INT) of the microcomputer 3 is signaled when the meter unique code is corrected, causing the microcomputer 3 to wake up in the stop mode.

When the microcomputer 3 wakes up, the data is transmitted to the wireless meter reader 13 via the meter signal filter 4 and the transmitter / receiver 5 according to a command given from the wireless meter reader 13. The microcomputer 3 controls the real time clock 2 to bias the base of the transistor TR after the interrupt so that the metering signal filter unit 4 and the transmission / reception 5 can continue to operate. The microcomputer 3 outputs the monthly integrated data according to the command of the wireless meter reader 13. The microcomputer 3 also exports the monthly integrated value already stored in the EPROM and displays the rotation value of the meter. A new integration method may be used in combination with the command of (13).

Transmitter and receiver 5 pulses a specific frequency received from antenna ANT and sends it to meter reading signal filter 4, and data pulses coming from meter reading signal filter 4 are converted back to a specific frequency to antenna ANT. Is transmitted to the external wireless meter reader (13). The transceiver 5 should consist of at least a detection circuit, an amplification circuit and a pulse oscillation circuit involving parallel resonance. Since the circuit configuration of the transceiver 5 is, for example, a general frequency method of 424 MHz, only a block is illustrated in FIG. 1 and a detailed description thereof will be omitted.

The radio meter reader 13 which transmits and receives a specific frequency to and from the antenna ANT must have at least a built-in frequency transceiver, and when the input is input to the microcomputer built in itself according to the operation of the switch, the signal is transmitted, and the counter of the present invention ( In FIG. 1, when a signal is transmitted from the transceiver 5 to the part other than the wireless meter reader, a signal corresponding to the signal is transmitted. The wireless meter reader 13 should be able to perform and display at least the following functions. That is, the data of the microcomputer 3 and the year, month, date and time can be set, the usage can be modified, and the total usage, the current monthly cumulative amount, the previous month's cumulative amount, the previous month's cumulative amount, and the previous month's cumulative amount are stored. It must be able to display through its own display.

A signal transmission / reception flow as one embodiment of the meter reading by the wireless meter reader 13 is shown.

1. When the user operates the wireless meter reader 13, the operation start signal is received by the transmitter / receiver unit 5 of the counter, and the meter signal filter unit 4 filters a specific pulse signal of a specific frequency and if the signal is correct, the microcomputer ( The microcomputer 3 wakes up by generating a pulse at the interrupt port INT of 3).

2. When the microcomputer 3 wakes up, the interrupt port INT connected to the meter reading signal filter unit 4 is disabled and the meter reading signal of the wireless meter 13 is waited.

3. The microcomputer 3 enables the interrupt port INT and returns to the stop mode if the meter reading signal of the wireless meter reader 13 does not come within one minute or the unique code of the meter does not match.

4. The wireless meter reader 13 sends a unique code to the counter. There are two code signals. One is a unified code signal used when not knowing the code signal and the other is the unique (user) code number of the counter.

5. The counter sends a unique code signal to the wireless meter reader 13 when the code signal is correct.

6. The wireless meter reader 13 sends an instruction code signal to the CPU of the counter again when a unique code signal comes. Indication code is meter reading code and data modification code.

7. The CPU of the counter sends the data value in accordance with the indication code signal of the wireless meter reader 13.

8. The wireless meter reader 13 sends the received data back to the counter.

9. The CPU of the counter judges whether the returned data and the sent data are the same, and if it is the same, it sends an OK signal and if it is wrong, it sends the data again.

10. The wireless meter reader 13 stores the data in a memory together with the unique code of the counter when the transmitted data is an OK signal.

11. If the data is not the OK signal, the above 8, 9 and 10 operations are repeated.

Since the present invention configured as described above has a calendar function, if the counter is accumulated so that the cumulative value, for example, from 0 o'clock on the first day of the month to 24 o'clock on the last day of the month, the meter can be read at any time next month, as well as the previous 1 The integrated value for months can be easily checked, reducing complaints from users' fees. In addition, it maintains the electronic counter with minimum current consumption while using DC power, and transmits and receives data only when needed, and counts the rotation speed of the meter by the contactless Hall sensor or photo sensor method with low current consumption and low defects. Therefore, the small battery is used for a long time, and the problem of contact failure of the sensor unit is also solved. In particular, the battery consumption can be reduced to 10 to 20 써 by constructing 5 to 10 하면 according to the present invention in a general manner, so that the battery that can be used for only one week can be used for at least 10 years. .

Claims (1)

The meter sensor unit is configured to detect whether one revolution of the meter rotating plate is supplied while power is supplied to the hall sensor or the photo sensor every 2 m / s for about 2 seconds. It is accumulated and saved by real time zone and monthly, and when a signal is given to the interrupt port, it wakes up and outputs the data corresponding to the external metering signal and checks the reception, and the power supplied by 2m / s every 2 seconds. According to the operation of a specific frequency signal received when receiving a signal signal to the interrupt port of the microcomputer and wireless meter reading unit for wirelessly transmitting the data of the microcomputer characterized in that it consists of a wireless meter for the calendar function Metering system.