JP2733625B2 - Centralized monitoring and supply control device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION INDUSTRIAL APPLICATION Field of the Invention The present invention relates to a method of supplying a supply of tap water, gas, electricity, hot water, etc. to a plurality of demand points, and determining the supply / interruption and supply amount of each supply. The present invention relates to a centralized monitoring and supply control device which individually and automatically controls at individual locations, and monitors it centrally at a specific location.

2. Description of the Related Art Conventionally, for example, in gas supply, a portable storage medium of a prepaid card system is used, and a gas supply can be received by an available amount stored in the storage medium. There is a supply control device described in the gazette.

Problems to be Solved by the Invention However, this conventional supply control device is intended for independent supply control at each demand point, and does not allow multiple units to be monitored in a concentrated manner. Also, since only a prepaid card type storage medium can be used, if it is not at hand or if the data is 0 even if it is present, supply cannot be received and it is assumed that the supply body is tap water. In addition, there is a problem that water cannot be used even in an emergency requiring a large amount of water such as a fire.

An object of the present invention is to provide a centralized monitoring of supply control at a plurality of demand points, and even when there is no prepaid card type storage medium or cash at each demand point, in the event of an emergency such as a fire, the central monitoring apparatus side It is an object of the present invention to provide a centralized monitoring and supply control device that can supply tap water and the like at all demand points at the same time by a command.

Means for Solving the Problems A centralized monitoring and supply control device according to the present invention comprises a centralized monitoring device A and a plurality of individual supply control devices B connected in parallel to the centralized monitoring device A, as shown in the basic configuration diagram of FIG. Become. Each individual supply control device B includes a supply path opening / closing means D for opening and closing a supply path C for supplying a supply body, a supply amount detection means E for detecting an amount of the supply body flowing through the supply path C, A reading means G for reading a portable storage medium F or cash in which a usable amount is stored, and reading data stored in the inserted storage medium F or the amount of cash inserted; Opening / closing control means H for controlling the supply path opening / closing means D according to the data or the amount of money. Further, the centralized monitoring device A has an emergency input means I and an information control for controlling the opening / closing control means H of all the individual supply control devices B to open the supply path opening / closing means D when inputting by the emergency input means I. Means J.

Operation According to such a configuration, by inserting the storage medium F or cash into the reading means G in each individual supply control device B, supply of tap water or the like by the data or the amount of money stored in the storage medium F is performed. Can be In an emergency, the emergency input by the centralized monitoring device A causes the supply path opening / closing means D of all the individual supply control devices B to be simultaneously opened regardless of the presence of the storage medium F or cash in each individual supply control device B. .

Embodiments Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 2 is a system configuration diagram of a centralized monitoring and supply control device according to the present invention, which exemplifies supply of tap water in a pension, an apartment, an apartment, or the like. This device is composed of a centralized monitoring device A and a plurality of individual supply control devices (hereinafter referred to as individual devices) B connected to the centralized monitoring device A in parallel by a signal line 10. The centralized monitoring device A is located at a place where an administrator or the like can easily operate.
For example, it is installed in a management room, and the individual machine B is installed in each house.

On the front panel 11 of the centralized monitoring device A, lamps L1 to L10 (for 10 units) for displaying information of each dwelling, an emergency switch SW1, a buzzer sound stop switch SW2, and a release switch which are common emergency input means are provided. SW3 and buzzer Bz1 are provided.

On the other hand, each individual machine B has, on its main body 12, a display L11 for displaying various data and information from the centralized monitoring device A, a card reader 13 as reading means, a card removal switch.
SW4, an emergency switch SW5 which is an individual emergency input means, a front borrow switch SW6 which is a front borrow input means, a front borrowing display lamp L12, a water shutoff valve opening display lamp L13, and a buzzer Bz2 are provided. An electronic water meter 14 as detection means and a water-blocking valve 15 as supply path opening / closing means are connected. When a memory card (prepaid card) 16 as a portable storage medium or a clear card 17 as a clearing means is inserted into the card reader 13, data stored in these cards can be read. The memory card 16 is purchased in advance by a user of each house from an administrator or the like, and stores data representing a certain amount of usable water. Incidentally, it is assumed that a predetermined frequency is stored with, for example, one cubic meter measured by the water meter 14 as one unit. The clear card 17 is stored by an administrator or the like, and stores specific data that can reset the individual machine B as described later.

FIG. 3 shows the internal configuration of the centralized monitoring device A and the individual device B. Centralized monitoring device A is an information processing device including a memory and the like
Includes a CPU 1, a power from the power supply circuit 18 is supplied to the power supply terminal VDD1 of the CPU 1, the switch SW to the input port I ₁
1, Switch detection circuit 1 that detects ON / OFF of SW2 and SW3
9 is connected. Further, the lamp drive circuit 20 for driving the lamp L1~L10 to the output port O ₁ of the CPU 1,
The output port O ₂ buzzer driving circuit 21 for causing the ringing in an emergency the buzzer Bz1 are connected. Furthermore, the input-output ports I / O ₁ is the signal line 10 is connected.

On the other hand, the individual machine B is an information processing device CPU2 including a memory and the like.
The power supply terminal VDD2 of the CPU ₂ is supplied with power from the power supply circuit 22, and the input port I2 has the switches SW4, SW
5, the switch detection circuit 23 for detecting the on-off of SW6 is connected to the input port I ₃ water meter input circuit 24 for inputting a message obtained from the water meter 14 is connected.
The output port O ₃ has a water-blocking valve control circuit 25 that outputs a pulse for opening and closing to the water-blocking valve 15, and the output port O ₄ has a buzzer Bz2
Buzzer driving circuit 26 for driving the display device to the output port O ₅
Display drive circuit 27 for driving the L11, a lamp drive circuit 28 for lighting the lamp L12 · L13 is connected to the output port O _6. Further, the input / output port I / O ₂ is connected to the input / output port I / O _{1 of the} CPU 1 via the signal line 10, and
The card reader 13 is connected to the I / O ₃ .

In such a configuration, when the memory card 16 is inserted into the card reader 13, the CPU 2 reads the frequency stored in the memory card 16 by the card reader 13, and
A signal is sent to the display drive circuit 27, and the frequency value is displayed on the display L1.
Display at 1. Further, when the frequency data is not stored in the internal memory of the CPU 2, the frequency of one cubic meter is transferred from the memory card 16 to the internal memory, and the frequency is subtracted to rewrite the storage of the memory card 16. That is, the CPU 2 reduces the storage frequency of the memory card 16 by one by its data change function. At the same time, the CPU 2 opens the impervious valve 15 by the impervious valve control circuit 25 and turns on the impervious valve open indication lamp L13 by the lamp drive circuit 28. After this, even if the card removal switch SW4 is turned on and the memory card 16 is pulled out from the card reader 13, since the data for one cubic meter is stored in the internal memory of the CPU 2, the water amount for that is usable. .

However, if the frequency of the memory card 16 is 0 or a different type of card, the card reader 13 does not accept the card and ejects the card, and the display L11 indicates that the card cannot be used. In this case, the water-blocking valve 15 is not opened, and the water-blocking valve open indicator lamp L13 remains off.

As described above, when water is used with the water-blocking valve 15 opened, the water meter 14 integrates the measured values, and the content of the message is read into the CPU 2 through the water meter input circuit 24.
Then, as described above, from the time point when one cubic meter of data is stored in the internal memory, the water meter 14
Every time the liter is integrated, the data in the internal memory
100 liters are subtracted from each other, and water can be used until the data becomes zero.

When the storage frequency of the memory card 16 is 1 or less, that is, when it is less than 1 cubic meter, the card reader 13 ejects the memory card 16, the CPU 2 outputs a signal to the buzzer drive circuit 26 for a few seconds to sound the buzzer Bz2, and the memory card 1
Inform the user that the data in step 6 has been lost. At this time, the content of the internal memory of CPU2 is
Displayed in liters. Further, in this state, the water supply is continued, and when the content of the internal memory becomes 100 liters remaining, the buzzer drive circuit 26 sounds the buzzer Bz2 for several seconds, and if the new memory card 16 is not inserted, the water cutoff valve is activated.
15 works to warn of running water shut down. When a new memory card 16 is inserted, the contents of the internal memory are updated and can be used again.

However, when the data of the memory card 16 becomes 0 at night or the like and the water cutoff valve 15 operates and the water supply cannot be used, or when a new memory card 16 cannot be easily obtained, the front borrow switch SW6 is turned on to set 1 The use of cubic meters is possible. That is, when the switch SW6 is turned on, data of one cubic meter is stored in the internal memory of the CPU 2 irrespective of the card reader 13. At this time, the CPU 2 sends a signal to the lamp drive circuit 28 to turn on the borrowing indicator lamp L12, and at the same time, transmits the information from the input / output port I / O ₂ to the CPU 1 of the centralized monitoring device A by the information control function. . In the centralized monitoring device A, the lamp corresponding to the house of the individual machine B among the lamps L1 to L10 is turned on by the lamp drive circuit 20, and the manager or the like is notified that the house is rented in advance.

When the usable memory card 16 having data is inserted into the card reader 13 after the advance borrowing input, the CPU 2 subtracts the frequency from the memory card 16 by the amount of the advance borrow. And
The CPU 2 stops the signal to the lamp drive circuit 28, turns off the front borrowing display lamp L12, and transmits information on the clearing of the front borrow to the centralized monitoring device A. Centralized monitoring device A
Then, the lamp is turned off by the lamp drive circuit 20.

Also, when it is necessary to use water urgently due to a fire or the like when there is no memory card 16 in each individual machine B, when the emergency switch SW5 is turned on, the CPU 2 controls the water blocking valve control circuit 25 to control the water blocking. Since the valve 15 is forcibly opened, the user can freely use water. At this time, the CPU 2 sends a signal to the lamp driving circuit 28 to
When is turned on, a signal is also sent to the buzzer drive circuit 26 at that time to sound the buzzer Bz2. Further, the CPU ₂ transmits the information from the input / output port I / O ₂ to the CPU 1 of the centralized monitoring device A. As a result, in the centralized monitoring device A, the lamps L1 to L1
The lamp corresponding to the house of the individual machine B in L10 is repeatedly blinked by the lamp drive circuit 20 and the buzzer Bz1 is continuously sounded by the buzzer drive circuit 21, and the emergency switch SW5 is operated in any house by the manager or the like. Notify Taka. The administrator or the like can confirm that and turn on the buzzer sound stop switch SW2 to stop only the buzzer Bz1 of the centralized monitoring device A. Furthermore, when it becomes unnecessary to open the water cutoff valve in an emergency, the central monitoring device A
By turning on the release switch SW3 at
With the information from 1, the buzzer Bz2 of the individual machine B is automatically stopped via the CPU2, and the water cutoff valve 15 can be automatically closed and reset. The settlement of the amount of water used in an emergency at the residence of the individual machine B is performed by inserting a usable memory card 16 into the card reader 13 and subtracting it from the card. If this is not performed, the centralized monitoring device A determines that the settlement has not been made by the CPU 1 and the lamp L1
Blink the lamp corresponding to the house of ~ L10,
Further, the buzzer Bz1 is also sounded to notify the administrator or the like that the settlement has not been made.

On the other hand, when the manager or the like discovers a fire or the like in any house, the emergency switch SW1 of the centralized monitoring device A is turned on, so that the water in other houses can be used freely. That is, when the emergency switch SW1 is turned on, the CPU1 transmits information to the CPU2 of all the individual units B, and the CPU2 in all the individual units B opens the water blocking valve 15 regardless of whether the memory card 16 is inserted, Turn on the cutoff valve open indicator lamp L13. At this time, in the centralized monitoring device A, all lamps L1
~ L10 flashes, and the buzzer Bz1 also sounds to notify all dwelling units of an emergency. The stop and release of the buzzer sound in this case are the same as described above.

When a user leaves a house due to relocation or the like, the manager or the like inserts a clear card 17 prepared in advance into the card reader 13 of the house. Then, the individual machine B
The CPU 2 performs a self-reset by specific data stored in the clear card 17, clears the internal memory, etc., shuts off the water-blocking valve 15 by the water-blocking valve control circuit 25, and initializes the individual machine B. Return to the state.

FIG. 4 and FIG. 5 are flowcharts of the respective processes of the CPU1 and CPU2. The operation as described above will be described below according to the description.

In FIG. 4, CPU 1 sets an emergency switch in step S1.
The state of SW1 is detected by the switch detection circuit 19, and the switch S
If W1 is on, an emergency water cutoff valve opening request signal is transmitted in step S2. Next, in step S3, the lamp driving circuit 20 is driven to light all the lamps L1 to L10.
Further, the buzzer drive circuit 21 is driven in step S4,
Ring the buzzer Bz1.

On the other hand, if the emergency switch SW1 is off at step S1, the process proceeds to step S5, where the state of the buzzer sound stop switch SW2 is detected by the switch detection circuit 19, and if the switch SW2 is on, the buzzer is driven at step S6. The sound of the buzzer Bz1 is stopped by the circuit 21. If the buzzer sound stop switch SW2 is off in step S5, the process proceeds to step S7,
The state of the release switch SW3 is detected by the switch detection circuit 19, and if the switch SW3 is turned on, an emergency cutoff valve opening release request signal is transmitted in step S8. Next, in step S9, the lamp driving circuit 20 is driven, and all lamps L1 to L1 are driven.
Turn off L10. Further, in step S6, the buzzer Bz1 is stopped from sounding by the buzzer drive circuit 21.

If the release switch SW3 is off in step S7, the process proceeds to step S10 to transmit an information request signal. Next, in step S11, a response signal transmitted from the individual device B is received. Further, the presence or absence of information is determined in step S12, and if there is no response information, the lamp driving circuit 20 is driven in step S9, and the lamp corresponding to the individual unit B having no response information is turned off, and in step S6 The buzzer Bz1 is stopped by the buzzer drive circuit 21. on the other hand,
If there is response information in step S12, the lamp driving circuit 20 is driven to light all the lamps L1 to L10 in step S3, and the buzzer Bz1 is sounded by the buzzer driving circuit 21 in step S4.

In FIG. 5, the CPU 2 first drives the display drive circuit 27 in step S13 to display on the display L11 a message prompting insertion of a card. Next, in step S14, it is detected whether or not the card is inserted into the card reader 13, and if inserted, the process proceeds to step S15 to determine the validity of the card. The circuit 27 is driven to display on the display L11 that the card cannot be used, and the card is ejected from the card reader 13 in step S17.

On the other hand, if the card is valid in step S15, the process proceeds to step S18 to determine whether or not the card is a clear card 17,
If it is the clear card 17, the process proceeds to step S19 to initialize the individual machine B, and the clear card 17 is ejected from the card reader 13 in step S20.

If it is not the clear card 17 in step S18, that is, if it is a valid memory card 16, the process proceeds to step S21, where the water-blocking valve control circuit 25 opens the water-blocking valve 15. next,
In step S22, the lamp drive circuit 28 is driven to
Is opened by a water-blocking valve open display lamp L13. Further, in step S23, the display driving circuit 27 is driven to display the frequency value of the memory card 16 on the display L11.

Next, in step S24, the switch detection circuit 23 detects whether or not the card removal switch SW4 is ON. If the card removal switch SW4 is ON, the frequency of the memory card 16 is rewritten in step S25. The card 16 is ejected from the card reader 13.

On the other hand, if the card removal switch SW4 is off at step S24, the process proceeds to step S27, where it is determined whether or not there is an information request signal from the centralized monitoring device A.
At S28, the information of the CPU 1 of the centralized monitoring device A is transmitted.

Next, in step S29, the integrated value of the water meter 14 is fetched from the water meter input circuit 24, the used amount is calculated in step S30, and when it reaches 1 cubic meter, the frequency is subtracted in step S31. Subsequently, in step S32, it is determined whether or not the data of the memory card 16 has cut less than 1 cubic meter. If so, the buzzer Bz2 is sounded by the buzzer drive circuit 26 for several seconds in step S33. Further, the frequency value of the memory card 16 is set to 0 in step S34, and the memory card 16 is ejected from the card reader 13 in step S35.

Further, in step S36, it is determined whether or not the data in the internal memory of the CPU 2 is less than 100 liters. When the data is turned off, the buzzer Bz2 is sounded for several seconds by the buzzer drive circuit 26 in step S37, and displayed in step S38. Device drive circuit 2
7 is driven to display on the display L11 a message prompting the exchange of the memory card 16.

Next, in step S39, it is determined whether or not the data in the internal memory of the CPU 2 has become 0.
Returning to 3, if 0, proceed to step S40 to shut off the water-blocking valve 15 in the water-blocking valve control circuit 25, and drive the lamp drive circuit 28 in step S41 to turn off the water-blocking valve open indication lamp L13. .

If the memory card 16 is not inserted in step S14, the process proceeds to step S42, where the front borrow switch SW6
Is determined to be on, and if it is on, step S43
It is determined whether or not the individual machine B is in a state where it can be borrowed in advance, and if it is in a state where it can be borrowed, the process proceeds to step S44, where the lamp drive circuit 28 turns on the borrowing display lamp L12,
Proceed to step S21.

If both NO in step S14 and step S42,
In step S45, it is determined whether there is an information request from the centralized monitoring device A, and if so, the information is transmitted from the individual device B to the centralized monitoring device A in step S46.

In step S47, it is determined whether or not the emergency mode is set, that is, whether or not the emergency switch SW5 is turned on in the individual machine B or whether or not there is an emergency water cutoff valve opening request signal from the centralized monitoring device A. If YES, step S
At 48, the water shield valve 15 is opened by the water shield valve control circuit 25. Also,
In step S49, the buzzer Bz2 is sounded by the buzzer drive circuit 26, and in step S50, the water-blocking valve open indication lamp L13 is turned on.

Next, in step S51, it is determined whether or not there is an emergency cutoff valve opening release request signal from the centralized monitoring device A,
If there is, the process proceeds to step S52 to turn off the watertight valve open indication lamp L12 by the lamp driving circuit 28, to stop the buzzer Bz2 from sounding in step S53, and to control the watertight valve by the watertight valve control circuit 25 in step S54. Cut off 15.

Note that the memory card 16 and the clear card 17 may be any portable storage medium such as a magnetic card and an IC card, and the storage form is not limited. In addition, by inserting cash and reading the amount of money, supply may be made in the same manner as when the memory card 16 is inserted.

Further, as shown in FIG. 6, data reading and data rewriting of the storage medium F by the reading means G may be performed via the centralized monitoring device A. K is information control means on the individual supply device B side, L is data change means,
M is emergency input means, and N is advance borrowing input means.

Further, the device according to the present invention is not limited to tap water, electricity,
It can also be applied to supply control of hot water, gas, etc.

According to the present invention, it is possible to centrally monitor supply control at a plurality of demand points, and to provide a centralized monitoring device in the event of an emergency such as a fire, even if there is no prepaid card type storage medium or cash at each demand point. Tap water etc. can be supplied simultaneously at all demand points according to instructions from the side.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a basic configuration of the present invention, FIG. 2 is a system configuration diagram of an example thereof, FIG. 3 is a block diagram of an internal configuration of a centralized monitoring device and an individual supply control device (individual unit) therein, FIG. 4 is a flowchart of a process performed by the CPU of the centralized monitoring device, and FIG. 5 is a flowchart of a process performed by the CPU of the individual supply control device. FIG. 6 is a block diagram of a basic configuration of another example of the present invention. A: Centralized monitoring device B: Individual supply control device C: Supply path D: Supply path opening / closing means E: Supply amount detecting means F: Storage medium G: Reading means H: Opening / closing control means I: ... Emergency input means J ... Information control means

 ──────────────────────────────────────────────────続 き Continuation of front page (72) Inventor Norio Nakane 2-28-24 Izumi, Higashi-ku, Nagoya-shi, Aichi Inside Ricoh Elemex Co., Ltd. (56) References JP-A-51-130195 (JP, A) Hei 1-93890 (JP, A)

Claims (1)

(57) [Claims] A centralized monitoring device and a plurality of individual supply control devices connected in parallel to the centralized monitoring device, wherein each individual supply control device has a supply path opening / closing means for opening and closing a supply path for supplying a supply body; Supply amount detecting means for detecting the amount of the supply body flowing through the supply path, and a portable storage medium or cash in which the usable amount of the supply body is stored, and data or data stored in the inserted storage medium can be inserted. Reading means for reading the inserted amount of cash, and opening / closing control means for controlling the supply path opening / closing means in accordance with the data or the amount of money read by the reading means; and the centralized monitoring device includes an emergency input means A centralized monitoring and supply control device, comprising: an information control means for controlling the opening and closing control means of all the individual supply control devices at the time of input by the emergency input means to open the supply path opening and closing means.