JPS63241309A - Integrating meter - Google Patents

Abstract

PURPOSE:To certainly detect a weak current at a remote area, by monitoring the integrated consumption quantity or time when the consumption quantity per predetermined time is a predetermined value or less and remotely transmitting the same when the aforementioned integrated consumption quantity or time becomes a set value or more. CONSTITUTION:When the integrated quantity of an integrating counter 10 during a measuring period is smaller than the set value of a flow rate lower limit value setting circuit 14, an adder 18 is operated by the pulse signal from a timer 12 and the integrated quantity of the integrating counter 10 is integrated and stored in a flow rate integrating memory 19. The value of the flow rate integrating memory 19 is compared with the set value of a setting circuit 21 by a comparing circuit 20 and, when the value of the flow rate integrating memory 19 becomes the set value or more, this result is outputted to a display part 7 or a memory 27. The output of an integrating counter 16 is stored in the memory 27 and, if necessary, a telegram message assembling circuit 29 and a modem 30 are controlled by a transmission control circuit 28 to perform remote transmission.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an integrating meter that measures the amount of water or electricity used, and in particular, monitors the integrated consumption amount or time when the amount of consumption per predetermined time is less than a predetermined value, and calculates the integrated amount. When the consumption amount or time exceeds a set value, the accumulated consumption amount or time can be displayed or remotely transmitted to indicate water leakage or electric leakage.

To simplify the explanation, a water meter will be explained below as an example. Recent water meters have improved measurement accuracy and can now accurately measure a flow rate of, for example, about 20 fl/h. A flow rate of about 20 Q/h is a flow rate at which the water column separates into water droplets and drips approximately 30 ann below the faucet, but if water leaks at this level, the cumulative leakage flow rate for one month will be is 20 (Ω) x 24 (hours) x 30 (days) = 14.40012 = 14.4 bo.

On the other hand, water is used in ordinary households for about 2 hours a day on average over a week, and even if the water meter cannot cumulatively measure the flow rate of 20Q/h or less during this time, the water supply will be used for one month. The cumulative flow rate that cannot be measured is: 20 (Q) x 2 (hours) x 30 (days) = 1200Q = 1
．． 2 Bo, which is about 1/10 or less of the leakage cumulative flow rate.

Considering the above, it is of course important to improve the measurement accuracy of water meters, but in addition, it is also necessary to consider water leakage.

The present invention was made in view of the above-mentioned circumstances, and
A detailed description will be given below with reference to the drawings.

FIG. 1 is a block diagram for explaining one embodiment of the Nero water meter according to the present invention. In the figure, 1 is an impeller that rotates in proportion to the amount of water used; 2 is an impeller 1 3 is a magnetic sensor such as a reed switch, 4 is an interface, 5 is a flow rate/rotational speed conversion circuit, 6 is an integration counter, and 7 is a display section, and these impeller 1 to the display section 7 integrates and displays the amount of water used in exactly the same way as a conventional water meter. Also, 10 is an integration counter.

11 is a flip-flop circuit, 12 is a timer, 13 is a delay circuit, 14 is a flow rate lower limit value setting circuit, 15 is a comparison circuit, 16 and 17 are AND gate circuits, 18 is an adder, 1
9 is the lower limit flow rate integration memory, and the flow rate/rotation speed conversion circuit 5
As shown in FIG. 2 (Ca), a pulse output signal corresponding to the flow rate to be measured is obtained, and this pulse is counted by the integration counter 6 and added to the integration counter 10 and the flip-flop circuit 11. . On the other hand, timer 1
2 outputs pulse signals t1, t2, . . . with a constant period T, as shown in FIG. Through the delay circuit 13 (see Fig. 2 (Q))
The integration counter 10 and the flip-flop circuit 11 are added to the integration counter 10 and the flip-flop circuit 11.
Reset. However, when there is no output signal from the flow rate/rotational speed conversion circuit 5 during the previous pulse period T, the flip-flop circuit 11 is in the reset state, so
Flip-flop circuit 11 maintains its reset state. Therefore, after that, when the flow rate/rotational speed conversion circuit 5 outputs the pulse signals pp2...pn, the integration counter 10 counts the pulses, and the comparison circuit 15 calculates the integrated value (FIG. 2(f) )) is the flow rate lower limit value setting circuit 1.
4 (see Fig. 2(e)), and when the output of the integration counter 10 exceeds the set value, the AND gate circuit 1
6 is closed (see FIG. 2(g)), and when the set value is not exceeded, that is, when the flow rate to be measured is below the lower limit flow rate, the AND gate circuit 16 is opened (see FIG. 2(h)). Thereafter, when the next pulse t2 is generated from the timer 12, the integration counter 10 and the flip-flop circuit 11 are reset in the same manner as described above. The cumulative value of the cumulative counter 10 during the period T is the flow rate lower limit value setting circuit 1.
4, the adder 18 is activated by the pulse signal from the timer 12, and the totalizing counter 10
The integrated value of the integration counter 10 is integrated and stored in the flow integration memory 19. On the other hand, when the AND gate circuit 16 is closed, that is, when the integrated value of the integration counter 10 is larger than the set value, the adder 18
is not activated.

Therefore, only the integrated value when the flow rate is less than the value set by the flow rate lower limit value setting circuit 14 is stored in the flow rate integration memory 19. The value of this flow rate accumulation memory 19 is compared with the set value of the setting circuit 21 in a comparison circuit 20, and when the value of the flow rate accumulation memory 19 exceeds the set value, the flip-flop circuit 25 is activated and the result is displayed on the display section 7. Alternatively, it is output to the memory 27.

As mentioned above, when the flow rate to be measured during the fixed period T is below the set value, the AND gate circuit 16 is open, and at least one signal from the flow rate/rotational speed conversion circuit 5 is output during the period T. When an output pulse is generated, that is, when the flow rate to be measured is not 0, the AND gate circuit 17 is open. In other words, the flow rate to be measured during one cycle T is below the set value and is not 0. Since the AND gate circuit 17 is open, the output pulses from the timer 12 are supplied to the time counter 21 through the AND gate circuits 16 and 17, and are integrated and counted by the time counter 21. ), when the measured flow rate during one period T is equal to or higher than the set value, the AND gate circuit 16 is closed, and when the flow rate is O, the AND gate circuit 1 is closed.
7 is closed, so at this time the output pulses from the timer 12 are not counted by the time counter 22, thus:
The time counter 22 cumulatively measures the time when the flow rate to be measured is not O and below the set value, but this cumulative measured value is compared with the set value from the setting circuit 24 in the comparator circuit 23, and when the flow rate exceeds the set value. When the flip-flop circuit 26
and outputs the result to the display section 7 or memory 27.

The memory 27 includes an integration counter 6 and a comparison circuit 20.2.
3, etc. are stored, and if necessary, the message assembly circuit 29, modem 30, etc. are controlled by the transmission control circuit 28 for remote transmission. The invention is not limited to the above embodiments, and for example, the timer 12 may be made programmable, or a lower limit flow rate accumulation memo may be provided. J-19, time counter 22
It is also possible to display or transmit the output as it is, and furthermore, it is possible to display or transmit the output as it is.
．． Time counter 22. and flip-flop circuit 25
．． 26 etc. may be reset manually or automatically.

As is clear from the above description, according to the present invention, it is possible to reliably monitor and display a state in which water leakage or electric leakage in each household, that is, the measured flow rate is not O and is lower than a predetermined (set) flow rate.

[Brief explanation of the drawing]

FIG. 1 is an electric circuit diagram for explaining one embodiment of the integrating meter according to the present invention, and FIG. 2 is a time chart for explaining the operation of the circuit shown in FIG. DESCRIPTION OF SYMBOLS 1... Impeller, 2... Permanent magnet, 3... Reed switch, 4... Interface, 5... Flow rate/rotation speed conversion circuit, 6... Integration counter, 7... Display part, 10...integration counter, 12...timer, 13
...Delay circuit, 14...Flow rate lower limit value setting circuit, 15
...Comparison circuit. 18... Adder, 19... Lower limit flow rate integration memory. 20.23... Comparison circuit, 21.24... Reference value setting circuit, 27... Memory, 28... Transmission control circuit, 29... Telegram assembly circuit, 30... Modem. Patent applicant Ricoh Co., Ltd. Figure 1 Figure 2 Procedural amendment (voluntary) March 18, 1985 Director General of the Patent Office Kunio Ogawa 1, Indication of the case 1988 Patent application No. 36349 2, Invention Name: Microflow Detection Device 3, Relationship with the person making the correction Patent applicant Address: 1-3-6 Nakamagome, Ota-ku, Tokyo Name (
Name) (674) Ricoh Co., Ltd. Representative Hama
1) Hiro 4, Agent address: 1-2-7 Furocho, Naka-ku, Yokohama 231
Shear Train Yokohama No. 807 No. 6, Subject of amendment 7, Contents of amendment (1), The title of the invention in the specification is amended to "Minor flow rate detection device J. (2), The scope of claims in the specification is as shown in the attached sheet. (3), page 1 of the specification, lines 11 to 16, ``The present invention is designed to obtain...''. The present invention relates to a minute flow rate (minute consumption amount) detection device that remotely transmits after detecting the cumulative consumption amount or time when the consumption amount per unit is less than a predetermined value. ”. (4), page 2, line 17 of the same statement, “In the following,
The purpose of the present invention is to provide a minute flow rate detection device that can reliably detect a minute flow rate, which is a leakage of water or electric power to be measured, at a remote location. The following is corrected to 6 (
5), page 7, lines 10 to 13. According to the present invention, it is possible to display... According to the present invention, it is possible to reliably detect a minute flow rate, which is a leakage of water or electricity, which is an object to be measured, at a remote location. ”. Claim 1: When the consumption amount per predetermined time is less than or equal to a predetermined value

Claims (1)

[Claims] 1. Monitor the cumulative consumption amount or time when the consumption amount per predetermined time is less than a predetermined value, and display or remotely transmit the cumulative consumption amount or time when the cumulative consumption amount or time exceeds the set value. An integrating meter characterized by having a means.