JPH06251277A - Upper and lower limit measured value monitoring system - Google Patents

Abstract

PURPOSE:To provide a upper and lower limit measured value monitoring system which automatically set or varies an upper and a lower limit value for measured values. CONSTITUTION:A monitoring means 1 compares a measured value detected by a detecting means 3 with the previously set upper or lower limit value to monitor whether the measured value exceeds the upper or lower limit value. An upper and lower limit value setting means 8 sets plural kind of upper and lower limit values for each detecting means 3. A monitoring condition decision means 16 decides whether or not monitoring conditions including a monitor time and the operation states of relative equipments of facility equipments are realized. An upper and lower limit value selecting means 17 selects an upper and a lower limit value including the measured value detected by the detecting means 3 when the monitoring conditions are realized among plural kind of upper and lower limit values set by the upper and lower limit value setting means 8 and outputs the upper and lower limit values to the monitoring means 1.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention particularly relates to a building management system for monitoring building equipment by detecting a value to be measured of the building equipment with a detector and comparing the measured value with upper and lower limits. The present invention relates to a measurement value upper / lower limit monitoring method for monitoring whether or not a measurement value exceeds an upper / lower limit value.

[0002]

2. Description of the Related Art In recent years, remote monitoring systems for remotely monitoring building equipment have been installed in buildings and the like. As this remote monitoring system, there is a cold / hot water monitoring system, for example. The cold / hot water monitoring system compares the temperature measurement value (hereinafter, referred to as a measurement value) detected by a temperature sensor provided in the hot / cold water pipe with a predetermined upper and lower limit value, so that the measured value has an upper and lower limit value. It monitors whether or not it has been exceeded. When the measured value exceeds the upper and lower limit values, a buzzer or the like issues an alarm.

In this case, the operator sets the upper and lower limit values for the chiller / heater to appropriate temperatures according to the season. For example, in winter, the operator sets the upper and lower limits to 45 ° C to 50 ° C.
Set to (when hot water) to make the room temperature on each floor comfortable for people. Also, in summer, the operator sets the upper and lower limits to 6 ° C.
Set to ~ 8 ° C (in cold water).

[0004]

When the measured value of the temperature sensor provided in the hot and cold water pipes is monitored by the upper and lower limit values, the operator determines whether cold water is used or hot water is used. However, the operation was difficult because it was necessary to set or change to different upper and lower limits.

In addition, when the operator changes the upper and lower limit values, there is a possibility that the operator may make an operation error such as setting the upper and lower limit values for hot water to the upper and lower limit values for cold water. The present invention has been made in view of these points,
It is an object of the present invention to provide a measurement value upper / lower limit monitoring method capable of automatically setting or changing the upper and lower limit values for a measurement value.

[0006]

In order to solve the above problems and achieve the object, the present invention has the following constitution. FIG. 1 shows the principle of the present invention. The present invention includes a plurality of detecting means 3, monitoring means 1, upper and lower limit value setting means 8, and monitoring condition determining means 1.
6, the upper and lower limit value selection means 17 is provided. Multiple detection means 3
Indicates a value to be measured by the equipment, and the monitoring means 1 compares the measured value detected by each detecting means 3 with a preset upper and lower limit value to determine whether the measured value exceeds the upper and lower limit value. To monitor.

The upper and lower limit value setting means 8 sets a plurality of types of upper and lower limit values for each measuring means 3. Monitoring condition determination means 16
Determines whether or not a monitoring condition including a monitoring time and an operating state of a related device of the equipment is satisfied when the measured value is monitored by the upper and lower limit values. The upper / lower limit value selecting means 17 detects the detecting means 3 when the monitoring condition is satisfied among the plural kinds of upper / lower limit values set by the upper / lower limit value setting means 8.
The upper and lower limit values including the measured values detected in step 1 are selected, and the upper and lower limit values are output to the monitoring means 1.

Here, the equipment is a hot and cold water pipe, an air conditioner, etc., and the detection means 3 can be a temperature sensor, a gas sensor, etc. The monitoring means 1 is a computer or the like that remotely monitors the measurement value of the sensor.

The upper and lower limit value setting means 8 can be exemplified by a table provided in a memory or the like, and the monitoring condition judging means 1 can be used.
6, the upper and lower limit value selecting means 17 can be exemplified by a central processing unit or the like.

Further, a monitoring device operating state table 9 in which the operating states of the specific monitoring device are registered for each of the upper and lower limits of the plurality of types
Of the plurality of types of upper and lower limits, the upper and lower limits are selected based on the operating state of the specific monitoring device registered in the monitoring device operating state table 9, and the upper and lower limits are set in the monitoring means 1. And a monitoring device control unit 18 for outputting.

Here, the specific monitoring device is an air conditioner or the like, and this air conditioner includes a cold / hot water switching device for switching between the summer and winter modes. The monitoring device control unit 18 selects the upper and lower limit values according to the operating state of the hot / cold water switching device from the monitoring device operating state table 9, so that the upper and lower limit values are overlapped and the monitoring condition is satisfied. Even if the measured values at the time of establishment are duplicated, the measured values can be monitored by the selected upper and lower limit values.

Furthermore, an upper and lower limit date table 10 in which upper and lower limit values are registered in advance for each due date is provided, and a date for changing the upper limit value or the lower limit value based on the upper and lower limit values for each date registered in the upper and lower limit date table 10 is set. By including the control unit 19, the upper and lower limit values can be automatically selected on a preset date.

[0013]

According to the present invention, first, the upper and lower limit value setting means 8 sets a plurality of types of upper and lower limit values for each measuring means 3. Then, the monitoring condition determination means 16 determines whether or not the monitoring condition including the monitoring time and the operation state of the equipment related to the equipment is satisfied.

Next, when the plurality of detecting means 3 detect the measured values from the equipment, the upper and lower limit value selecting means 17 monitors the plural kinds of upper and lower limit values set by the upper and lower limit value setting means 8. The upper and lower limit values including the measured values detected by the detecting means 3 when the condition is satisfied are selected, and the upper and lower limit values are output to the monitoring means 1.

Further, the monitoring means 1 compares the measured value with the selected upper and lower limit values and monitors whether or not the measured value exceeds the upper and lower limit values. That is, the optimum upper and lower limit values that match the current state are automatically selected from a plurality of upper and lower limit values and the measured values are monitored, so that the operator does not have to set or change the upper and lower limit values one by one. In addition, operation mistakes such as setting wrong upper and lower limits can be eliminated.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A measurement value upper / lower limit monitoring system according to the present invention will be described below. FIG. 2 is a configuration block diagram of an embodiment of a building management system for realizing the measurement value upper / lower limit monitoring method according to the present invention. <Structure of Embodiment> In FIG. 2, a building is provided with one master station 1 including a computer for monitoring a plurality of building equipments. Child stations 2a to 2n are connected in series. The master station 1 and the plurality of slave stations 2a to 2n constitute a remote monitoring system.

Each of the slave stations 2-1 to 2-n is provided for each floor, and as building equipment, for example, hot and cold water pipes, air conditioners,
It has disaster prevention equipment. Each slave station 2-1 to 2
A plurality of measurement detectors 3a to 3m are connected to -n. Here, the measurement detectors 3a to 3m are, for example, temperature sensors that detect temperature.

The master station 1 has a cathode ray tube 4 (CRT) for displaying the monitoring status of building equipment, a keyboard 5 (KB) for inputting information, and sounds an alarm when the measured value exceeds the upper and lower limit values. A buzzer 6, a printer 7 for printing data such as upper and lower limit values and measured values at constant intervals are connected.

FIG. 3 is a block diagram of the master station 1. In FIG. 3, the master station 1 includes an upper and lower limit device table 8a, an upper and lower limit table 8b, a monitoring device operating state table 9, a due date upper and lower limit device table 10, a monitoring table 11, a magnetic disk 12a, a floppy disk 12b, a clock 13, and a man. Machine interface unit 14a (hereinafter, man-machine I
/ F section. ), A slave station I / F unit 14b, and a central processing unit 15 (hereinafter, referred to as CPU).

Each of the tables 8a to 11 is provided in a random access memory (hereinafter referred to as RAM) not shown. In addition, a control program is stored in a read-only memory (hereinafter referred to as ROM) not shown.

The upper and lower limit device table 8a registers monitoring conditions for monitoring the measured values for each of the temperature sensors 3a to 3m and upper and lower limit value codes for distinguishing a plurality of types of upper and lower limit values. .

FIG. 7 shows the contents of the upper / lower limit device table.
The upper and lower limit device table 8a shown in FIG. 7 has different monitoring conditions (such as a and b in the figure) such as time conditions and related device operating conditions for each temperature sensor, and a plurality of types of upper and lower limit codes c1 and c.
2 ... and are registered.

FIG. 5 shows an example of the monitoring conditions. The monitoring conditions shown in FIG. 5 are the monitoring time from 8:00 to 20:00, the related equipment such as the air conditioner is turned on from time t ₀ (after 8 o'clock), and is turned off at time t ₃ , until the related equipment starts up. The condition is the time t ₁ including the monitoring delay time. In this case, the satisfaction of the monitoring condition described later is from time t ₁ to time 20:00.

The upper and lower limit table 8b registers an upper limit value and a lower limit value for each upper and lower limit code. FIG. 8 shows the contents of the upper and lower limit table 8b. Upper and lower limit table 8 shown in FIG.
In b, the upper limit value and the lower limit value are registered for each code (c1, c2, etc.). In the upper and lower limit table 8b, for example, the code c1 registers the upper limit value 50.0 and the lower limit value 45.0 for hot water of the cold / hot water pipe (winter mode), and the code c2 registers cold water of the cold / hot water pipe (summer mode). Upper limit for 8.0, lower limit
6.0 is registered.

FIG. 6 shows a plurality of upper and lower limits for the measured values. In FIG. 6, the vertical axis represents temperature T and the horizontal axis represents time t.
Is. In the figure, the upper limit value 1 corresponding to the code c1
(50.0), the lower limit value 1 (45.0), and the upper limit value 2 (8.0) and the lower limit value 2 (6.0) corresponding to the code c2 are shown. In addition, the measured values at the time of hot water are plotted in a constant cycle (marked with ○ and × in the figure). The plurality of upper and lower limit values and the measured values are printed on the printer.

Note that the times t _{1 to} 20:00 shown in FIG.
Monitoring condition is satisfied when the time t ₁ to 20 shown in: 00 corresponds to the upper limit value is the measurement value T1 at time t _{1 1} (45.0~5
0.0). Further, at time t ₄ , the upper and lower limit value 1 is exceeded at the temperature T ₄ , and an alarm is generated by the buzzer, and at time t ₅ , the upper and lower limit value 1 is reached at the temperature T _5.
Since it is within the range, the alarm will be restored.

The monitoring device operating status table 9 registers the operating status of a specific monitoring device for each of a plurality of upper and lower limits.
As shown in FIG. 9, a plurality of types of upper and lower limit value ranges with respect to the measurement value of the specific monitoring device overlap (the upper limit value 2 (25.0) and the lower limit value 1 (23.0) in the figure overlap, and the monitoring condition is satisfied. It is used when the measured value at the time of doing is in the overlapping range.

Here, the specific monitoring device is an air conditioner, and the air conditioner includes a cold / hot water switching device for switching the summer / winter mode. FIG. 10 shows the contents of the monitoring device operation state table 9. The monitoring device operation status table 9 shown in FIG.
The upper and lower limits for the measured value, the type of specific monitoring device, and the operating status (ON, OFF) of the specific monitoring device are registered for each code.

In the air conditioner, the upper limit value 27.0 and the lower limit value 23.0 corresponding to the code c1 are set in the summer mode, and the upper limit value 25.0 and the lower limit value 21.0 corresponding to the code c2 are set in the winter mode. For this reason, the monitoring device operating state table 9 indicates that the operating state (ON = cold water) of the cold / hot water switching device is code c1, the upper limit value.
Corresponding to 27.0 and lower limit value 23.0, the operating state (OFF = warm water) of the cold / hot water switch is code c2, upper limit value 25.0, lower limit value 2
Corresponds to 1.0.

The due date upper / lower limit device table 10 automatically selects the upper and lower limit values on a preset due date in consideration of the case where the specific monitoring device condition does not exist. FIG. 11 shows the contents of the due date upper / lower limit device table. In the due date upper / lower limit device table 10 shown in FIG. 11, monitoring conditions (a, b, etc.) for each sensor and the upper / lower limit value code for each due date are registered. For example, in the sensor 3a, the monitoring condition is a and the due date k1
Upper and lower limit code c1 for (05/01 9:00, spring), upper and lower limit code c for due date k2 (12/01 9:00, winter)
2 is registered.

The monitoring table 11 has registered therein upper and lower limit values selected by an upper and lower limit value selection unit 17, a monitoring device control unit 18, and a due date control unit 19, which will be described later. Magnetic disk 1
2a and the floppy disk 12b store other data. The clock 13 measures the monitoring time.

The man-machine I / F unit 14a is connected to the C
The RT 4, KB 5, buzzer 6, and printer 7 are connected, and the slave station I / F unit 14b connects the inside of the master station and the slave station 2. The CPU 15 controls the above-mentioned respective units, and also has a monitoring condition determination unit 16, an upper / lower limit value selection unit 17, a monitoring device control unit 18, and a due date control unit 19.

The monitoring condition judging unit 16 judges whether or not the above-mentioned monitoring condition is satisfied, and when this condition is satisfied, the measured value is acquired at a constant cycle, and the measured value exceeds the upper and lower limit range. Is determined.

The upper / lower limit value selection unit 17 selects the upper limit value or the lower limit value including the acquired measured value from among the plurality of upper limit values or the lower limit values stored in the upper / lower limit value table 8b when the monitoring condition is satisfied. To automatically select the optimum upper limit or lower limit.

The monitoring device control unit 18 selects the upper and lower limit values from the upper and lower limit values of the plurality of types based on the operating state of the specific monitoring device registered in the monitoring device operating state table 9. Here, the monitoring device control unit 18 selects upper and lower limit values from the monitoring device operating state table 9 according to the operating state of the cold / hot water switch.

The due date control section 19 uses the upper and lower limit due date table 1
The upper limit value or the lower limit value is changed based on the upper limit value and the lower limit value registered for each date. FIG. 4 is a configuration block diagram of the slave station 2. In FIG. 4, each slave station 2-1 to 2-n has a ROM 21 for storing programs, a RAM 22 provided with various tables, a clock 23 for measuring a monitoring time, and a master station I / F.
24a, a plurality of digital interface sections 24b
(Hereinafter, referred to as DI section), analog interface section 24c (hereinafter referred to as AI section), and CPU 25 for controlling each section.

Here, each table such as the upper and lower limit value table 8b is provided in the RAM of the master station 1, and the master station 1 refers to each table to monitor the measured values.

It should be noted that, for example, the RAM 22 in the slave station may be provided with the respective tables, and the slave station 2 may refer to the respective tables to monitor the measured values. <Process of Embodiment> Next, the process of the measurement value upper / lower limit monitoring method in the embodiment will be described. FIG. 12 is a processing flow of the measurement value upper / lower limit monitoring method of the embodiment.

First, a cycle is activated to start the process (step 101). Next, the monitoring condition determination unit 16
It is determined whether or not a monitoring condition such as a temporal condition or a related device condition is satisfied (step 102).

For example, as shown in FIG. 5, the monitoring condition judging section 16 monitors the monitoring time, the ON operation of related equipment such as an air conditioner,
It is determined whether monitoring conditions such as monitoring delay are satisfied. Here, when the monitoring condition determination unit 16 determines that the monitoring condition is not satisfied, the alarm recovery process by the buzzer 6 is performed (step 103), and the process ends (step 104).

On the other hand, when the monitoring condition determining unit 16 determines that the monitoring condition is satisfied, for example, in the example shown in FIG. 5, the power of the related device is turned on after the monitoring time (8:00) and the related device starts up. At the time (time t ₁ ), it is determined that the monitoring condition is satisfied, and then the CPU 15 today determines whether or not the _first measurement value (initial value, for example, temperature T _{1 in} FIG. 6) of the upper and lower limit values is monitored. Is determined (step 105).

Here, when the CPU 15 determines that it is not the monitoring of the first and second measured values for the upper and lower limits, the process proceeds to step 111. On the other hand, when the CPU 15 determines that the first measurement value is monitored with respect to the upper and lower limit values, the monitoring condition determination unit 16 reads the upper and lower limit device table 8a and determines whether there are a plurality of types of upper and lower limit value codes. It is determined (step 106).

If the monitoring condition judging unit 16 judges that there are no plural kinds of upper and lower limit values in the upper and lower limit device table 8a, the process proceeds to step 110. On the other hand, when the monitoring condition determination unit 16 determines that there are a plurality of upper and lower limit value codes in the upper and lower limit value device table 8a, the temperature sensors 3a to 3m provided in each slave station 2 detect the measured values. (Step 107).

For example, the temperature sensor detects the temperature T ₁ as an initial value at time t _{1 as} shown in FIG. Further, the upper / lower limit value selection unit 17 uses the upper / lower limit table 8
Among the plural kinds of upper and lower limit values stored in b, the sensor 3a-
It is determined whether or not there are upper and lower limit values including the measured value (hereinafter referred to as the current value) detected by 3 m (step 108).

Next, when there are upper and lower limit values including the current value, the monitoring device control unit 18 determines whether or not a plurality of types of upper and lower limit values including the current value overlap (step 10).
9). Here, when the monitoring device control unit 18 determines that the upper and lower limit values of the plurality of types do not overlap, the upper and lower limit value selecting unit 17 sets the upper and lower limit values including the current value in the monitoring table 11 ( Step 110). That is, the upper / lower limit value selection unit 17 selects an upper / lower limit value including the current value from among a plurality of types of upper / lower limit values and registers it in the monitoring table 11.

After the optimum upper and lower limits are registered in advance in the monitoring table 11 in this way, the measured values are detected by the sensors 3a to 3m provided in the slave station 2 (step 111).

Further, the CPU 15 has the sensors 3a-3
It is determined whether or not the measured value detected by m exceeds the upper and lower limit values registered in the monitoring table 11 (step 112).

Here, when the measured value exceeds the upper and lower limit values, CP
If U15 determines, an alarm process is performed (step 113), and the process ends (step 114). In addition,
In step 112, when the CPU 15 determines that the measured value does not exceed the upper and lower limit values, that is, when the CPU determines that the measured value is normal, the process ends without performing the alarm process.

On the other hand, when it is determined in step 108 that there is no upper and lower limit value including the current value, or when it is determined in step 109 that the upper and lower limit values overlap, the monitoring device control section 18 It is determined whether or not there is a specific monitoring device such as an air conditioner (step 115).

Here, when it is determined that there is a specific monitoring device, the monitoring device control section 18 monitors the operating state of the specific monitoring device (step 116). For example, the summer / winter mode is determined by monitoring the operating state of the cold / hot water switch provided in the air conditioner.

Further, it is judged whether or not the operating state of the specific monitoring device is established in the monitoring device operating state table 9 (step 117). Here, the monitoring device operating state table 9
When the operation state of the specific monitoring device is established, for example, when the cold / hot water switch is ON, the code c1 is referred to by referring to the operation state (ON) of the cold / hot water switch in the monitoring device operation state table 9. , Upper limit value 27.0, lower limit value 23.0. Then, the process proceeds to step 110, and the selected upper and lower limit values are set in the monitoring table 11.

On the other hand, in step 115, when the monitoring device control section 18 determines that there is no specific monitoring device, then the due date control section 19 determines whether or not there is a due date designation (step 118). ). When the due date control unit 19 determines that the due date is designated, the upper and lower limit due date table 10
To determine whether the due date condition is met (step 11
9).

Here, when the due date condition is satisfied, the routine proceeds to step 110, where the selected upper and lower limit values are set in the monitoring table 11. On the other hand, in step 118,
If no due date is specified, or if the due date condition is not satisfied, the current upper and lower limit values are set in the monitoring table (step 120), and the process proceeds to step 111.

Then, the measured values are detected by the temperature sensor at regular intervals, and it is determined whether or not these measured values exceed the range of the selected upper and lower limit values (optimal values).

As described above, by using the upper / lower limit device table 8a, the upper / lower limit table 8b, the monitoring condition judging section 16, and the upper / lower limit selecting section 17, the optimum upper limit value from the plurality of upper / lower limit values is matched with the current state. Since the upper and lower limit values are automatically selected and the upper and lower limit values are changed, unnecessary unnecessary alarms that occur temporarily are eliminated. Moreover, since the change operation is not necessary, there is no operation error such as setting the wrong upper and lower limits.

Further, by using the monitoring device operation table 9 and the monitoring device control unit 18, even if a plurality of upper and lower limit values are overlapped and the measured values when the monitoring condition is satisfied are overlapped, the optimum upper and lower limit values are You can monitor the measured value by selecting.

Further, by using the upper and lower limit date table 10 and the date control unit 19, the upper and lower limit values can be automatically selected on a predetermined date even when the specific monitoring device condition is not satisfied.

In the embodiment, the example of measuring the temperature of the cold / hot water pipe is shown, but the present invention can be applied to the measurement of other building equipment.

[0059]

According to the present invention, the optimum upper and lower limit values that match the current state are automatically selected from a plurality of upper and lower limit values and the upper and lower limit values are changed. Eliminates unnecessary alarms that occur. Moreover, since the change operation is not necessary, there is no operation error such as setting the wrong upper and lower limits.

[Brief description of drawings]

FIG. 1 is a principle diagram of the present invention.

FIG. 2 is a configuration block diagram of an embodiment of the present invention.

FIG. 3 is a configuration block diagram of a master station.

FIG. 4 is a configuration block diagram of a slave station.

FIG. 5 is a diagram showing monitoring conditions.

FIG. 6 is a diagram showing a plurality of upper and lower limits for measured values.

FIG. 7 is a diagram showing the contents of an upper / lower limit device table.

FIG. 8 is a diagram showing the contents of an upper and lower limit table.

FIG. 9 is a diagram showing a state in which a plurality of upper and lower limit values overlap.

FIG. 10 is a diagram showing the contents of a monitoring device upper / lower limit table.

FIG. 11 is a diagram showing the contents of a date upper / lower limit device table.

FIG. 12 is a processing flow of the embodiment.

[Explanation of symbols]

 1 ・ ・ Master station 2 ・ ・ Slave station 3 ・ ・ Measurement detector 4 ・ ・ CRT 5 ・ ・ Keyboard 6 ・ ・ Buzzer 7 ・ ・ Printer 8a ・ ・ Upper / lower limit device table 8b ・ ・ Upper / lower limit table 9 ・ ・ Monitoring device Operating status table 10-Due date upper / lower limit device table 11-Monitoring table 12a-Magnetic disk 12b-Floppy disk 13,23-Clock 14a-Condominium I / F section 14b-Slave station I / F section 15・ ・ CPU 16 ・ ・ Monitoring condition judgment unit 17 ・ ・ Upper and lower limit value selection unit 18 ・ ・ Monitoring equipment control unit 19 ・ ・ Due date control unit 21 ・ ・ ROM 22 ・ ・ RAM 24a ・ ・ Master station I / F unit

Claims (4)

[Claims] 1. A plurality of detecting means (3) for detecting a value to be measured of facility equipment, and measurement by comparing the measured values detected by each detecting means (3) with preset upper and lower limit values. In a remote monitoring system including a monitoring means (1) for monitoring whether or not the value exceeds the upper and lower limit values, an upper and lower limit value setting means for setting a plurality of types of upper and lower limit values for each measuring means (3). (8), and a monitoring condition determining means (16) for determining whether or not a monitoring condition including a monitoring time and an operating state of a related device of the equipment is satisfied when the measured value is monitored by upper and lower limits. Of the plural kinds of upper and lower limit values set by the upper and lower limit value setting means (8), an upper and lower limit value including a measured value detected by the detecting means (3) when the monitoring condition is satisfied is selected. The upper and lower limit value selecting means for outputting the upper and lower limit values to the monitoring means (1) (17) A measurement value upper / lower limit monitoring method comprising: 2. A monitoring device operating state table (9) in which operating states of specific monitoring devices are registered for each of the plurality of types of upper and lower limit values.
Of the plurality of types of upper and lower limits, the upper and lower limits are selected based on the operating state of the specific monitoring device registered in the monitoring device operating state table (9), and the upper and lower limits are set to the monitoring means (1 ) And a monitoring device control unit (18) for outputting to the measurement value upper and lower limit monitoring method according to claim 1. 3. The specific monitoring device is an air conditioner, and the air conditioner includes a cold / hot water switch for switching between summer and winter modes, and the monitoring device control unit (18) includes the monitoring device operating state table. The upper and lower limit monitoring method according to claim 2, wherein the upper and lower limit values are selected from (9) according to the operating state of the cold / hot water switch. 4. An upper and lower limit date table (10) in which upper and lower limit values are registered in advance for each due date, and an upper and lower limit date table (1).
The measurement value upper / lower limit monitoring method according to claim 1, further comprising a due date control unit (19) for changing the upper limit value or the lower limit value based on the upper limit value and the lower limit value registered for each date.