JP2010032302A - Remote counter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a remote counter which reduces its current consumption by comparing an integrated value obtained by integration of the remote counter with an integrated value of a meter itself, and stopping integration operation by flow rate pulses if there is a clear difference between them, and prevents a consumer from becoming suspicious when the count of the remote counter changes though no water is used. <P>SOLUTION: Along with calculating an integrated value of the flow rate of the meter based on flow rate pulses sent from the meter, the remote counter reads out an integrated value by the meter itself by communication at each predetermined time interval (step S104), compares the difference between both (step S104), and if the difference between both exceeds a threshold, stops integration based on the flow rate pulses (step S106). Moreover, the remote counter displays on its display part the matter that the integration based on the flow rate pulses is stopped. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a remote counter which is connected to a meter (flow meter) and has a display mechanism capable of displaying a meter pointer value, alarm information, and the like.

  Electronic water meters are often used in cold regions such as Hokkaido. As shown in Fig. 1, they are installed in the ground at a depth of about 1.5m from the ground 4 to prevent freezing. Since it is difficult to see the indicator value of the meter 2 directly, the remote counter 1 is installed on the ground, and the integrated value of the meter 2 is communicated through the cord 3 provided in the cord insertion hole 5 by communication. Alarm information is read and displayed. Further, the remote counter 1 also performs integration based on the flow rate pulse signal from the meter 2.

Also, in apartments, meters are installed in the pipe shafts of each house, but remote counters are sometimes installed on the first floor in order to perform meter reading in one place.
At the time of installation, the remote counter reads the indicator value of the meter, that is, the integrated value of the meter itself, displays it on the display mechanism, and simultaneously reads the flow rate per pulse of the flow rate pulse signal from the meter and stores it in the storage unit of the remote counter To do. Thereafter, the remote counter is uniquely integrated by the flow rate pulse signal from the meter. However, the value may be different from the guideline value of the flow meter because noise may be mixed in the pulse line or processing may be lost when a pulse is input during communication processing. The flow rate indicator value is called and corrected by communication every period (for example, every 24 hours).

The remote counter independently counts the flow pulse signal from the flow meter. When the meter is installed, the meter is driven when the meter is deep underground even when checking the operation by flowing water. Because it is difficult to confirm, if the remote counter is operated by the flow rate pulse from the meter, it can be known that the meter is being driven indirectly. This is because it is possible to know in real time what is being used.
Various types of remote counters have been proposed. For example, there are remote counters as described in Patent Document 1 and Patent Document 2.
JP 2004-240911 A JP 2005-267020 A

As described above, the flow rate pulse from the meter is also integrated in the remote counter, and even if there is a discrepancy between the integrated value in the remote counter and the meter due to noise, the integrated value is obtained by communication at regular intervals. Therefore, there is no error between the meter and the integrated value of the remote counter.
However, electronic water meters may be operated under severe temperature and humidity conditions, such as being submerged for 8 years.

One of such problems is that the flow rate pulse output circuit of the meter becomes abnormal and the signal for driving the LCD is directly on the pulse line. In this case, the remote counter always performs an accumulation operation at a high speed, and the display of the remote counter moves even though water is not used, which causes suspiciousness to the consumer. Further, the remote counter increases the number of pulse processes, which increases current consumption and may cause the battery to run out. Furthermore, it is necessary to notify the outside that a defect has occurred in the pulse output section of the meter and have the meter inspected.
However, even in such a state, there is no abnormality in the integrating unit of the meter, so the meter pointer value (integrated value) can be read from the remote counter by communication and displayed on the display unit of the remote counter. For example, it will not interfere with the collection of water charges.

The present invention has been made in view of such a situation, and an integrated value obtained by integrating a flow rate of a meter based on a flow rate pulse sent from a meter by a remote counter and a meter itself sent from the meter by communication. If there is a clear difference between the accumulated value and the accumulated value, the current consumption of the remote counter is reduced by stopping the accumulation operation by the flow rate pulse. The object is to provide a remote counter that prevents the consumer from being suspicious by the movement of the counter.
It is another object of the present invention to provide a remote counter capable of notifying the display unit of the remote counter that the integration by the flow rate signal from the meter is stopped.

  The invention of claim 1 is a remote counter connected to a meter, having a display mechanism for reading the meter information by communication and displaying the indicator value of the meter, wherein the remote counter is a flow rate signal transmitted from the meter. The flow rate value of the meter is integrated on the basis of the flow rate, and in the remote counter capable of displaying the integration result on the display mechanism, the difference between the result obtained by integrating the flow rate signal from the meter and the meter pointer value read by communication is a predetermined value When the threshold value is exceeded, the integration of the flow rate value based on the flow rate signal from the meter is stopped.

  The invention of claim 2 is characterized in that, in the invention of claim 1, when the integration of the flow value based on the flow signal from the meter is stopped, the fact that the integration has been stopped is displayed on the display mechanism. It is.

In the present invention, even if an unexpected pulse is sent due to an abnormality in the pulse output section of the meter, it is possible to prevent battery consumption of the remote counter by preventing the remote counter from accumulating. Will never be suspicious.
Moreover, by displaying that the integration by the flow rate pulse from the meter is stopped on the remote counter display unit, it is possible to notify the meter reader and prompt the water utility to check the meter.

The remote counter according to the present invention is an apparatus that includes a display unit that is connected to a meter and displays a pointer value of the meter. Hereinafter, the remote counter according to the present invention will be described by way of example as being connected to an electronic water meter. However, even if it is a meter other than a water meter, the measured object (flow rate or flow velocity of other types of fluid) Etc.), and can also be applied to meters that give warnings by detecting the measurement results (guideline values and abnormality detection results based on them) and the abnormalities of the meter itself. ) May be used as long as it is a meter that can transmit to the remote counter side via a wired line or a wireless line.
Further, the remote counter according to the present invention may display not only the electronic pointer value but also the mechanical value. Further, the remote counter according to the present invention will be described below as a device connected to the meter on a one-to-one basis. However, the remote counter is installed in an apartment house or the like and is connected to a large number of water meters. Even in a configuration in which a plurality of meters are connected to the remote counter, the present invention can be similarly applied.

FIG. 2 is a functional block diagram of a remote counter according to an embodiment of the present invention.
The control unit 7 controls the overall operation of the remote counter 1 and is composed of a microcomputer and other peripheral circuits, which will be described in detail later. The meter communication I / F 10 is an I / F (interface) for performing communication between the electronic water meter 2 and the remote counter 1. The external communication I / F 11 is an I / F for performing communication between the external device 6 such as a telegram setting device and the remote counter 1. A display LCD (liquid crystal display) 8 displays the pointer value and alarm information of the electronic water meter 2. The lead SW 9 is a switch for controlling the electronic water meter 2 or the remote counter 1 from the outside when there is no communication external device. The pulse input I / F 12 is an I / F for receiving a flow rate pulse from an electronic water meter (hereinafter referred to as meter) 2 by the remote counter 1 in order to perform integration by the remote counter 1. The pulse output I / F 13 is an I / F for outputting a pulse from the remote counter 1 to the external device 6. Although not shown, power is supplied from the control unit 7 to each block.

  The remote counter 1 is installed on the ground as shown in FIG. 1, and the accessory cord 3 is removed from the meter 2 installed in the ground at a depth of about 1.5 m by digging the cord insertion hole 5 from the ground 4. Via the communication, the integrated value and alarm information of the meter 2 are read and displayed. The remote counter 1 also integrates the flow rate by the flow rate pulse signal from the meter 2.

FIG. 3 is a block diagram of the microcomputer in the control unit of the remote counter.
The ROM 15 is a storage unit in which a remote counter program is written, and the RAM 16 is a storage unit for data that needs to be rewritten. The LCD control unit 17 is a part that performs display control of the display LCD 8. The communication control unit 18 is a part that controls communication with the meter 2 or the external device 6. The timer 19 is a part for creating a time necessary for controlling the remote counter. The input / output port 20 is a port for exchanging various signals between a microcomputer and a circuit outside the microcomputer. The CPU 14 controls various other parts in order to execute various programs, and the internal bus 21 is a path for exchanging information between the respective parts in the microcomputer.

  The remote counter 1 is connected to the meter 2 and then reads the internal information of the meter 2. If the pulse output type, the remote counter 1 reads the weight (flow rate) per pulse, and every time a flow rate pulse is input from the meter 2 thereafter. Integration is performed inside the remote counter 1. Further, the indicator value of the meter 2, that is, the integrated value by the meter 2 itself is read out every predetermined period (for example, 24 hours), and the error is corrected. The pulse output section of the meter 2 is an open collector output, and power is supplied from the remote counter 1 side.

FIG. 4 is a diagram showing a conventional display example of the integrated values of the meter and the remote counter, and FIG. 5 is a diagram showing a display example of the integrated values of the meter and the remote counter according to the present invention.
If the values of the meter 2 and the remote counter 1 are different, the integrated value of the remote counter 1 is matched with the integrated value of the meter 2.
In FIG. 4, for example, until July 16, even if the integrated values of the meter 2 and the remote counter 1 do not match, there is a slight difference, but a difference of about 20 m ³ occurs every day from July 17 for three days. I'm stuck. This is because some abnormality occurs in the pulse output section of the meter 2, the pulse output line and the LCD drive signal line are short-circuited, and the LCD drive signal is sent to the remote counter 1 as a flow rate signal. This is probably because an error occurs with the integrated value of the meter 2 because the integration is performed according to the flow rate signal.

  Therefore, as shown in FIG. 5, when the difference in the integrated value is clearly too large as of July 17, the remote counter 1 does not perform the integration by the pulse from the meter 2 and the remote counter 1 performs the meter every 24 hours. The integrated value read from 2 is held and updated every 24 hours.

FIG. 6 is a flowchart showing the integration operation of the remote counter in the present invention.
The timer 19 in the remote counter 1 counts 24 hours (step S101), and when 24 hours have elapsed, the integrated value of the meter 2 is read by communication (step S102), and the meter integrated value and the remote counter integrated value are compared. (Step S103). Here, the remote counter integrated value is a flow value integrated by the remote counter 1 receiving the flow pulse from the meter 2.
As a result of the comparison, if the meter integrated value and the counter integrated value match, nothing is done and the process is terminated (step S107). If the results of the comparison do not match, it is determined whether the difference is within a predetermined threshold (1 m ^{3 in the} example) (step S104).
If the result of determination is within the threshold value, the counter integrated value is rewritten to the meter integrated value (step S105), and the process is terminated (step S107).
If the result of determination in step S104 is that the difference is greater than the threshold value, the remote counter 1 stops integration by the flow rate pulse (step S106) and ends the process (step S107). In step S106, when the integration by the flow rate pulse is stopped, the power supply to the pulse output circuit of the meter 2 is turned off so that no pulse will enter thereafter.
Note that the threshold value is not limited to 1 m ³ , and an appropriate value may be set.

FIG. 7 is a diagram illustrating a display example of the display unit (display LDC) of the remote counter.
The display LDC 8 includes an integrated value display unit 30 of the meter 2, an alarm display unit 31 generated in the meter 2, a pilot display unit 32, and an inspection mark display unit 33. The alarm display unit 31 includes a battery voltage drop alarm 31a indicating that the battery of the meter is low, an excessive flow alarm 31b indicating that water is flowing at a flow rate higher than expected, and a long time when water is higher than expected. A water leakage alarm 31c indicating that the water continues to flow, a water non-use alarm 31d indicating that the water has not been used for more than expected, and a backflow alarm 31d indicating that the water continued to flow for longer than expected. The mark can be displayed, and the alarm display unit 31 is normally off. Moreover, the pilot display part 32 repeats lighting and extinction for every flow rate pulse sent from a water meter. The inspection mark display unit 33 is an inspection mark that prompts inspection of the meter, and is normally turned off.
Then, as shown in step S106 of FIG. 6, when the remote counter 1 stops the integration by the flow rate pulse from the meter 2, the inspection mark display unit 33 is turned on or blinked to make the meter 2 Informs that the integration by the flow rate signal from is stopped and prompts inspection.

It is a figure which shows the example of a connection of a meter and a remote counter. It is a functional block diagram of the remote counter which concerns on one Example of this invention. It is a block diagram of the microcomputer in the control part of a remote counter. It is a figure which shows the example of the conventional display of the integrated value of a meter and a remote counter. It is a figure which shows the example of a display by this invention of the integrated value of a meter and a remote counter. It is a flowchart which shows the integrating | accumulating operation | movement of the remote counter in this invention. It is a figure which shows the example of a display of the display part of a remote counter.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Remote counter, 2 ... Electronic water meter, 3 ... Code, 4 ... Ground, 5 ... Cord insertion hole, 6 ... External device, 7 ... Control part, 8 ... Display LDC, 9 ... Lead SW, 10 ... Meter Communication I / F, 11 ... External communication I / F, 12 ... Pulse input I / F, 13 ... Pulse output I / F, 14 ... CPU, 15 ... ROM, 16 ... RAM, 17 ... LCD control unit, 18 ... Communication Control part, 19 ... Timer, 20 ... Input / output port, 30 ... Integrated value display part, 31 ... Alarm display part, 32 ... Pilot display part, 33 ... Inspection mark display part.

Claims (2)

  A remote counter connected to a meter, having a display mechanism for reading out the meter information by communication and displaying a pointer value of the meter, wherein the remote counter is based on a flow signal transmitted from the meter. When the difference between the result obtained by integrating the flow rate signal from the meter and the pointer value of the meter read by communication exceeds a predetermined threshold in a remote counter capable of displaying the integration result on the display mechanism A remote counter characterized by stopping the accumulation of flow values based on a flow signal from.   2. The remote counter according to claim 1, wherein when the integration of the flow rate value based on the flow rate signal from the meter is stopped, the fact that the integration is stopped is displayed on the display mechanism.

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