KR101340843B1 - Electric energy monitoring device, electric energy monitoring system, electric energy monitoring method, control program, and recording medium - Google Patents

Abstract

The present invention is intended to determine whether or not the amount of power used by a plurality of electric devices included in the monitoring range is exceeded by reflecting the use state, characteristics, and the like of the plurality of electric devices included in the monitoring range. The electric power amount monitoring device of the present invention classifies a plurality of electric devices included in the monitoring range into a plurality of counting units, and counts each of the counting units with a data counting unit 22 for counting the amount of power used by the electric devices, respectively. An alarm level difference calculator 23 that calculates an alarm level difference that is a difference between the amount of power used and an alarm level value, and an alarm judgment value calculator 24 that calculates an alarm judgment value based on an alarm level difference of each counting unit; And the judging section 25 that determines whether the alarm judgment value has exceeded the predetermined alarm threshold, and if it is determined that the alarm threshold value has been exceeded, sends alarm information indicating that the amount of power used within the monitoring range is exceeded. An alarm transmitter 27 is provided.

Description

Electric power monitoring device, electric power monitoring system, electric power monitoring method, control program and recording medium {Electric energy monitoring device, electric energy monitoring system, electric energy monitoring method, control program, and recording medium}

The present invention relates to a power amount monitoring device for monitoring the amount of power used by a plurality of electric devices and / or groups of electric devices included in a predetermined monitoring range, a power amount monitoring system, a power amount monitoring method, a control program, and a recording medium. .

In general, electric utilities set a base rate based on demand for consumers who use high voltage power. Therefore, in order to reduce costs, a consumer such as a company monitors demand so that the cumulative power consumption in the demand cycle (usually 30 minutes) does not exceed the target demand value (management demand value). Thus, various demand monitoring systems have been developed for demand monitoring.

For example, a conventional general demand monitoring system calculates the amount of power used based on a metering pulse of a power supply meter (transaction meter), alerts the user before exceeding the management demand value, and suppresses the amount of power used. It is urged to do so.

For example, Patent Literature 1 discloses a demand monitoring system that monitors demand by selecting either the amount of power used based on a metering pulse, the amount of power measured on the high pressure side, or the amount of power measured on the low pressure side (secondary side). It is described.

Patent Document 1: Japanese Patent No. 3603876 (published December 22, 2004)

However, the above-mentioned prior art compares the total used electric power amount of electric equipment in a demand contract with a predetermined threshold, and determines whether the used electric power amount is exceeding. Therefore, the use state and characteristics (for example, standard power, etc.) of each electric apparatus in a demand contract are not considered, and there exists a problem that high precision determination cannot be performed.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and an object thereof is to reflect the state of use, characteristics, and the like of a plurality of electric apparatuses included in a monitoring range, and to exceed the amount of power used by the plurality of electric apparatuses included in the monitoring range. To realize a power amount monitoring device, a power amount monitoring system, a power amount monitoring method, a control program and a recording medium.

Electric power monitoring device according to the present invention, in order to solve the above problems, the electric power monitoring device for monitoring the amount of power used by a plurality of electrical devices included in the monitoring range, the plurality of electrical devices are classified into a plurality of counting units, A counting means for counting the amount of power used by the electric device for each counting unit, a count of alarm levels that is a difference between the amount of power used by the counting means for each counting unit and a predetermined alarm level value for the counting unit; Alarm level difference calculation means for calculating an alarm determination value based on the alarm level difference in each aggregation unit calculated by the alarm level difference calculating means, and alarm calculated by the alarm determination value calculating means Judging means for judging whether or not the judgment value exceeds a predetermined alarm threshold, and the judging means indicates that the alarm judgment value is the alarm threshold. If it is determined that the value is exceeded, it is characterized by including output means for outputting alarm information indicating that the amount of power used within the monitoring range is exceeded.

Moreover, the electric power quantity monitoring method which concerns on this invention is an electric power quantity monitoring method which monitors the used electric power amount of several electric apparatuses contained in a monitoring range, and solves the said subject, and classifies the said electric apparatuses into a some counting unit. And an alarm that is the difference between the counting step of counting the amount of power used of the electric device for each counting unit, the amount of power used in the counting step, and the alarm level value predetermined for the counting unit for each counting unit. An alarm level difference calculating step of calculating a level difference, an alarm judgment value calculating step of calculating an alarm judgment value based on an alarm level difference of each aggregation unit calculated in the alarm level difference calculating step, and the alarm judgment value calculating step A judgment step of judging whether or not the alarm judgment value calculated in the step exceeds a predetermined alarm threshold, and the alarm judgment in the judgment step. This is characterized by an output step of if more than the threshold and the alarm determination, the alarm information which indicates that by using the power supply is greater than in the monitoring range.

According to the above configuration, the counting means classifies the plurality of electric devices included in the monitoring range into a plurality of counting units, and counts the amount of power used for each counting unit. The alarm level difference calculating means calculates an alarm level difference that is a difference between the amount of power used by the counting means for each counting unit and a predetermined alarm level value for each counting unit, and the determination means determines the alarm. The alarm judgment value based on the level difference and the alarm threshold value are compared to determine whether or not the amount of power used within the monitoring range is exceeded. When the amount of power used is exceeded, the alarm device indicating the alarm information is output to the notification device, and the notification device notifies the user of the alarm content indicated by the alarm information, whereby the user uses the amount of electric power used in the monitoring range. It can be seen that the excess.

In this way, the alarm determination value is based on the difference between the amount of power used for each counting unit and the alarm level value predetermined for the counting unit. Therefore, the present invention compares, for example, the state of use and characteristics of the electrical equipment of each counting unit, compared with simply determining whether the amount of power used by the plurality of electrical equipment included in the monitoring range has exceeded a predetermined value. By reflecting, it is possible to determine whether or not the amount of power used by the plurality of electric devices included in the monitoring range is exceeded. Therefore, it has the effect that a user can be notified of the alert content determined with high precision.

The power amount monitoring device according to the present invention further includes contribution calculation means for calculating, for each of the counting units, a contribution which is a ratio of the alarm level difference of the counting unit with respect to the counting alarm value, and the output means further comprises: When the judging means determines that the alarm judgment value has exceeded the alarm threshold, the alarm information indicates that the electric equipment included in the counting unit showing the highest contribution to the alarm judgment value contributes most to exceeding the amount of power used. In addition, it is preferable to output.

According to the above configuration, the output means outputs in addition to the alarm information that the electric equipment included in the counting unit showing the highest contribution contributes most to exceeding the amount of power used. Therefore, when the notification device which has received the alarm information notifies the user of the alarm contents indicated by the alarm information, the user can determine the amount of power used by the electric device when the electric power used by the electric device included in the monitoring range is exceeded. If suppressed, it can be seen that the amount of power used by the electric equipment included in the monitoring range can be most effectively reduced. Therefore, the user can easily take the action of lowering the amount of power used.

In addition, the power amount monitoring apparatus according to the present invention further includes an influence degree specifying means for specifying an influence degree of the electric apparatus included in the counting unit for all the electric apparatuses included in the monitoring range for each of the counting units. It is preferable that the said alarm determination value calculation means calculates an alarm determination value by adding up the product of the alarm level difference of each aggregation unit multiplied by the said influence degree, respectively.

According to the said structure, the said alarm determination value calculation means calculates an alarm determination value by summing the difference of the alarm level difference of each counting unit, and multiplying the influence degree of the electric apparatus contained in each counting unit, respectively. Therefore, the characteristic etc. of the electrical apparatus contained in an aggregation unit are further reflected in an alert determination value. Therefore, it is possible to determine whether or not the amount of used power is exceeded with higher precision.

The power amount monitoring device according to the present invention is further characterized in that, in the power amount monitoring apparatus, a value obtained by multiplying an alarm determination value calculated by the alarm determination value calculation means by an elapsed time from a monitoring start time and a time coefficient in an increasing relationship It is desirable to determine whether or not the threshold has been crossed.

The electric power amount monitoring device of the present invention monitors the amount of electric power used by a plurality of electric devices included in the monitoring range within a predetermined monitoring period so as not to exceed a predetermined target upper limit electric power amount such as a management demand value. Therefore, as time elapses from the start of monitoring, it becomes difficult to suppress the amount of power used below the target upper limit power amount.

According to the above configuration, the determination means determines whether or not the value obtained by multiplying the alarm determination value by the elapsed time from the monitoring start time and the time coefficient in increasing relation exceeds the alarm threshold. That is, since the value increases according to the elapsed time, when a large amount has elapsed since the start of monitoring, the alarm threshold may sometimes be exceeded even when the alarm determination value is small. It may not go over.

Therefore, the alarm can be notified to the user in consideration of the difficulty of responding to the elapsed time.

In addition, the power amount monitoring apparatus according to the present invention is characterized in that the determination means sums the target upper limit power amount predetermined for all the electric apparatuses included in the monitoring range, and the influence of each aggregation unit specified by the influence degree specifying means. It is preferable to determine whether the alarm threshold value based on the total impact degree has exceeded the alarm determination value.

According to the above configuration, the alarm threshold value is based on a predetermined target upper limit electric power amount for all the electric devices included in the monitoring range, and the total influence degree obtained by adding up the influence degree of each aggregation unit specified by the influence degree specifying means. .

Here, when the counting means is not all the electric devices included in the monitoring range, but the amount of power used by some electric devices included in the monitoring range is counted, the alarm determination value is based on the corresponding electric devices.

Therefore, even when the amount of power used by some of the electric devices included in the monitoring range is counted by setting the alarm threshold that is the comparison target of the alarm determination value based on the electric equipment counted by the counting means, the monitoring range with high accuracy. It is possible to determine whether or not the amount of electric power used by the electric equipment included in is exceeded.

The power amount monitoring system according to the present invention preferably includes the power amount monitoring device and a measuring device for measuring the amount of power used by the electric device and outputting the measured amount of power used by the electric device to the power amount monitoring device. Do.

The power amount monitoring system according to the present invention preferably includes the power amount monitoring device and a notification device for receiving the alarm information output from the output means and notifying the user of the alarm contents indicated by the received alarm information. .

According to the configuration, the power amount monitoring system has the same effect as the power amount monitoring device.

The power amount monitoring device may be realized by a computer. In this case, the computer can be operated as each means of the power amount monitoring device so that the control program for realizing the power amount monitoring device by a computer and the computer that recorded the power amount monitoring device can be read. Record carriers also fall within the scope of the present invention.

As described above, the power amount monitoring apparatus according to the present invention comprises: counting means for classifying the plurality of electric devices into a plurality of counting units, and counting the amount of power used by the electric devices for each counting unit, and for each counting unit, Alarm level difference calculating means for calculating an alarm level difference that is a difference between the amount of power used by the counting means and a predetermined alarm level value for each counting unit, and an alarm for each counting unit calculated by the alarm level difference calculating means; Alarm determination value calculating means for calculating an alarm determination value based on the level difference, determination means for determining whether the alarm determination value calculated by the alarm determination value calculating means has exceeded a predetermined alarm threshold value, and the determination means When it is determined that the alarm determination value has exceeded the alarm threshold, alarm information indicating that the amount of power used within the monitoring range is exceeded is output. It is a configuration equipped with an output means.

In addition, the power amount monitoring method according to the present invention includes a counting step of classifying the plurality of electric devices into a plurality of counting units, and counting the amount of power used by the electric devices for each counting unit, and for each counting unit, An alarm level difference calculating step of calculating an alarm level difference which is a difference between the amount of used power aggregated in the counting step and a predetermined alarm level value for each counting unit, and the alarm level of each counting unit calculated in the alarm level difference calculating step An alarm judgment value calculating step of calculating an alarm judgment value based on the difference, a judgment step of determining whether the alarm judgment value calculated in the alarm judgment value calculation step has exceeded a predetermined alarm threshold value, and in the judgment step, When it is determined that the alarm determination value has exceeded the alarm threshold, alarm information indicating that the amount of power used within the monitoring range is exceeded is output. It includes an output stage.

Therefore, compared with simply determining whether the amount of electric power used by a plurality of electric apparatuses included in the monitoring range has exceeded a predetermined value, the present invention, for example, shows the state of use, characteristics, and the like of the electric apparatuses in each counting unit. By reflecting, it is possible to determine whether or not the amount of power used by the plurality of electric devices included in the monitoring range is exceeded. Therefore, it has the effect that a user can be notified of the alert content determined with high precision.

1 shows an embodiment of the present invention and is a block diagram showing the main configuration of an electric power amount monitoring device.
2 is a diagram showing an example of an outline of a power amount monitoring system including the power amount monitoring device.
3 is a flowchart showing an example of the power amount monitoring process executed by the power amount monitoring device.
FIG. 4 is a graph plotting the cumulative amount of power used in each aggregation unit and the alarm level value in each aggregation unit. FIG.
Fig. 5 is a graph plotting the alarm level difference of each aggregation unit in the above embodiment.
Fig. 6 is a graph plotting the alarm determination value in the above embodiment.

An embodiment of the present invention will be described below with reference to FIGS. 1 to 6.

[Configuration of Electric Power Monitoring System]

First, the electric power quantity monitoring system which concerns on this embodiment is demonstrated based on FIG. 2 is a diagram illustrating an example of an outline of the power amount monitoring system 100 according to the present embodiment. As shown in FIG. 2, the power amount monitoring system 100 includes a power amount monitoring device 1, buildings 2a and 2b on which electric devices are installed, a display device 9, and a terminal 10.

The electric power monitoring device 1 monitors the electric power used by a plurality of electric devices included in the monitoring range. In this embodiment, it is assumed that the monitoring range is set in a site contracted with a power company, and the buildings 2a and 2b are provided in the site. That is, the electric apparatus contained in a monitoring range is an electric apparatus contained in the buildings 2a and 2b.

However, the monitoring range of the electric power quantity monitoring device 1 is not limited to the range of the contract site with a power company. For example, the monitoring range may be inside the building 2a (the whole building 2a) or may be part of the building 2a. In addition, the monitoring range may be a range including all of a plurality of bases in the company. In addition, the monitoring range may be a range including not only the company but also related companies such as subsidiaries.

In other words, the monitoring range of the electric power amount monitoring device 1 is not limited to a contract unit with the electric power company, but may be a range including a plurality of electric devices, and the range may be arbitrarily set.

In other words, the electric power amount monitoring device 1 of the present invention is not limited to demand monitoring, and can be used as monitoring the electric power used by a plurality of electric devices included in a predetermined range. In addition, the detailed structure and process of the electric power quantity monitoring apparatus 1 are mentioned later.

In buildings 2a and 2b, power meters (measuring devices) 3a and 3b for calculating electric charges installed by electric companies, respectively, transformers 4a1, 4a2, 4a3, and 4b1 for transforming electric power supplied from electric companies. And 4b2 and 4b3, and production equipment 6a and 6b, which are electrical equipment, air conditioners 7a and 7b, and lamps 8a and 8b.

In addition, below, when the buildings 2a and 2b are not distinguished, respectively, the buildings 2a and 2b are named generically and the building 2 is called. In the case where the power meters 3a and 3b are not distinguished from each other, the power meters 3a and 3b are collectively referred to as a power meter 3. In the case where the transformers 4a1, 4a2, 4a3, 4b1, 4b2 and 4b3 are not distinguished from each other, the transformers 4a1, 4a2, 4a3, 4b1, 4b2 and 4b3 are collectively referred to as a trans 4. In the case where the production facilities 6a and 6b are not distinguished from each other, the production facilities 6a and 6b are collectively referred to as the production facility 6. In the case where the air conditioners 7a and 7b are not distinguished from each other, the air conditioners 7a and 7b are collectively referred to as an air conditioner 7. In the case where the lights 8a and 8b are not distinguished from each other, the lights 8a and 8b are collectively referred to as a light 8.

Three transformers 4 are provided in the building 2a and 2b, respectively. Each electric machine is connected to the transformer 4, respectively, and electric power is supplied through the transformer 4. As shown in FIG. Ammeters 5a1, 5a2, 5a3, 5b1, 5b2 and 5b3 are provided between each electric device and the transformer 4, respectively. In the following, when the ammeters 5a1, 5a2, 5a3, 5b1, 5b2, and 5b3 are not distinguished from each other, the ammeters 5a1, 5a2, 5a3, 5b1, 5b2, and 5b3 are collectively referred to as ammeters 5.

The ammeter (measuring device) 5 measures the amount of power used by the electric equipment connected to each transformer 4. The ammeter 5 is connected to the electric power amount monitoring device 1 by a wireless communication means or a wired communication means, and transmits the measured amount of used electric power to the electric power amount monitoring device 1.

The production facility 6 operates by electricity and is a facility directly related to the production activity of the product. The production facility 6 is a machine, apparatus, a tool, a conveyance, a storage facility, etc., for example, and consists of one or some electrical equipment. In addition, what consists of a some electrical apparatus is also called electrical apparatus group.

In addition, in this embodiment, although the production equipment 6, the air conditioner 7, and the electric lamp 8 are illustrated as an electrical apparatus provided in the building 2, it is not limited to this. The electrical equipment installed in the building 2 should just operate by electricity, and arbitrary.

In addition, in this embodiment, although one electric machine or one electric machine group is connected to one transformer 4, it is not limited to this. A plurality of electric devices may be connected to one transformer 4, a plurality of electric device groups may be connected, and an electric device and an electric device group may be connected.

In addition, in this embodiment, although the three transformers 4 are provided in the building 2, respectively, the number of the transformers 4 is arbitrary.

In addition, in this embodiment, although the ammeter 5 is provided between the transformer 4 and an electric device, it is not limited to this. For example, an ammeter 5 may be provided between the transformer 4 and the power meter 3.

When a plurality of electric devices and / or groups of electric devices are connected to the transformer 4, one ammeter 5 is provided for one electric device or a group of electric devices, and each electric device or group of electric devices is provided. The amount of power used may be measured respectively.

In addition, the electric power amount monitoring device 1 may acquire the electric power used directly from the electric power meter 3 without providing the ammeter 5.

The display device 9 receives the alarm information from the electric power amount monitoring device 1 and displays the alarm content indicated by the alarm information. The display device 9 may display an image according to the instruction of the electric power monitoring device 1, and for example, an LCD (liquid crystal display), an organic EL display, a plasma display, or the like can be applied.

The terminal 10 receives the alarm information from the power amount monitoring device 1 and informs the user of the alarm contents indicated by the alarm information. The terminal 10 is, for example, a personal computer, a mobile phone, a personal digital assistant (PDA), or the like.

The display device 9 and the terminal 10 are connected to the electric power amount monitoring device 1 by wireless communication means or wired communication means.

In other words, the display device 9 and the terminal 10 are notification devices for the power amount monitoring device 1 to notify the user of an alarm or the like. In the present invention, the power amount monitoring system 100 may be provided with at least one notification device. In addition, the display device 9 or the terminal 10 may be integrated with the power amount monitoring device 1.

The notification device may be a sound output device such as a speaker that notifies an alarm or the like by sound. The notification device may be a light emitting device such as a patlight (registered trademark) or an LED that notifies an alarm or the like by light. In this way, the notification device may be anything as long as it can notify the user of an alarm or the like, and a known device can be applied.

[Configuration of power monitoring device]

FIG. 1 is a block diagram showing an example of a main configuration of an electric power monitoring device 1. As shown in FIG. As shown in FIG. 1, the power amount monitoring device 1 includes a control unit 11, a storage unit 12, a data input unit 13, an operation unit 14, and a communication unit 15.

The data input unit 13 is an interface for acquiring the amount of power used by each ammeter 5. As described above, the data input unit 13 and each ammeter 5 are connected by wireless communication means or wired communication means. As described above, when the ammeter 5 is not provided, the data input unit 13 obtains the amount of power used from the wattmeter 3.

The operation unit 14 is for a user to input an instruction signal to the power amount monitoring device 1 to operate the power amount monitoring device 1. The operation part 14 may be comprised from input devices, such as a keyboard, a mouse, a keypad, and operation buttons. In addition, when the electric power quantity monitoring device 1 is provided with the display apparatus 9, the touch panel by which the operation part 14 and the display apparatus 9 are integrated may be sufficient. The operation unit 14 may be a remote control device such as a remote controller separate from the power amount monitoring device 1.

The communication unit 15 communicates with other devices (notification devices) such as the display device 9 and the user terminal 10 by wireless communication means or wired communication means, and the data of the data according to the instruction of the control unit 11. It is sending and receiving.

The memory | storage part 12 stores the program, data, etc. which the control part 11 references, for example, counting unit information 31, alarm level value information 32, impact degree information 33, and an alarm threshold value. Information 34, time coefficient information 35, and the like. Details of the counting unit information 31, the alarm level value information 32, the impact degree information 33, the alarm threshold value 34 and the time coefficient information 35 will be described later.

The control unit 11 executes a program read out from the storage unit 12 into a temporary storage unit (not shown) to perform various operations and to collectively manage each unit included in the power amount monitoring device 1. To control.

In the present embodiment, the control unit 11 is a function block, which includes a data acquisition unit 21, a data aggregation unit (aggregation means) 22, an alarm level difference calculation unit (alarm level difference calculation unit) 23, and alarm determination. A value calculation unit (alarm determination value calculation means, influence degree specifying means) 24, a determination unit (determination means) 25, a contribution calculation unit (contribution degree calculation means) 26, an alarm transmitter (output means) 27 And a data setting unit 28. Each of the functional blocks 21 to 28 of these control units 11 implements a program stored in a storage device in which a CPU (central processing unit) is realized by a ROM (read only memory) or the like by using a random access memory (RAM) or the like. This can be realized by reading and executing the temporary storage unit.

The data acquisition unit 21 acquires the amount of power used by each electric device from the ammeter 5 through the data input unit 13. The data acquisition unit 21 outputs the amount of power used by each of the acquired electrical devices to the data aggregation unit 22.

The data aggregation unit 22 acquires the amount of electric power used by each electric device from the data acquisition unit 21 and reads out the aggregation unit information 31 from the storage unit 12. And the data counting part 22 aggregates the accumulated amount of used electric power of the electric equipment from the monitoring cycle start time to the present time for every counting unit indicated by the counting unit information 31 at predetermined monitoring intervals. The data aggregation unit 22 outputs the accumulated amount of used power for each aggregated unit to the alert level difference calculation unit 23.

Here, the monitoring period is a period (period) in which the power amount monitoring device 1 monitors the power amount. In other words, the monitoring cycle determines the timing and end of the accumulated amount of power used by the data aggregation unit 22. In the present embodiment, since the electric power amount monitoring device 1 assumes demand monitoring, the monitoring period is a demand period (30 minutes), but the present invention is not limited thereto. For example, the monitoring period may be 1 minute, may be 1 hour, may be 1 day, may be 1 year, and the monitoring period may be set arbitrarily.

In addition, a monitoring interval is an interval which the electric power quantity monitoring apparatus 1 judges the presence or absence of exceeding the used electric power quantity of several electric apparatuses contained in a monitoring range within a monitoring period. In other words, the monitoring interval is an interval at which the data counting unit 22 counts the accumulated amount of used power. The monitoring interval may be any interval shorter than the monitoring period. In the present embodiment, the monitoring interval is set to 1 minute, and the data counting unit 22 counts the cumulative used power amount for each counting unit every minute.

In addition, an aggregation unit is a unit which aggregates the accumulated amount of used electric power, and is a unit which contains at least one electric apparatus contained in a monitoring range. In this embodiment, it shall aggregate for every building 2. In other words, in the present embodiment, the production facility 6a, the air conditioner 7a and the lamp 8a are set in one counting unit, and the production facility 6b, the air conditioner 7b and the lamp 8b are counted in one counting unit. The data counting unit 22 accumulates the total cumulative power consumption of the production equipment 6a, the air conditioner 7a and the lamp 8a, and the total accumulation of the production equipment 6b, the air conditioner 7b and the lamp 8b. We count amount of electricity use.

However, the counting unit is not limited to this, and the electric device measured by one ammeter 5 may be the counting unit, each electric device or the group of electric devices may be the counting unit, and the demand contract unit is the counting unit. You may also In the present invention, any counting unit may be used as long as the plurality of electric devices included in the monitoring range are classified into a plurality of counting units.

The alarm level difference calculation unit 23 acquires the accumulated amount of used power for each aggregation unit from the data aggregation unit 22 and reads out the alarm level value information 32 from the storage unit 12. Then, the alarm level difference calculation unit 23 includes the cumulative amount of power used by the data counting unit 22, the alarm level value at the present time of the counting unit indicated by the alarm level value information 32, for each counting unit. It is to calculate an alarm level difference which is a difference of. The alarm level difference calculation unit 23 outputs the alarm level difference for each counting unit calculated to the alarm determination value calculation unit 24.

Here, an alert level value is a value used as a reference for evaluating the use amount of electric power of the electric equipment contained in an aggregation unit. In this embodiment, the sum total of the standard electric power (standard use electric power amount) of the electric equipment contained in a counting unit is set as an alarm level value. Specifically, for example, when the standard power of the electric equipment included in the counting unit is 60 MW / h, when the time is 10 minutes from the start of the monitoring cycle, the alarm level value is 10 MW, and when 20 minutes , 20 MW, and 30 MW at the time of 30 minutes. That is, the alarm level value may be set to [amount of power used in the monitoring cycle (30 minutes) based on the standard power] x [time ratio (elapsed time / 30 minutes)].

However, the alarm level value is not limited to the above-described example, and may be any value as long as it is a reference value for evaluating the amount of power used by the electric apparatus included in the counting unit.

The alarm determination value calculation unit 24 obtains an alarm level difference for each aggregation unit from the alarm level difference calculation unit 23, and calculates an alarm determination value based on the alarm level difference for each aggregation unit. For example, the alarm determination value calculation part 24 calculates an alarm determination value by adding up the alarm level difference of each counting unit. The alarm determination value calculation unit 24 outputs the calculated alarm determination value to the determination unit 25.

In addition, the alarm determination value calculation unit 24 acquires the alarm level difference for each aggregation unit from the alarm level difference calculation unit 23, and reads the influence degree information 33 from the storage unit 12, The impact degree of all the electric apparatuses included in the counting unit for all the electric apparatuses included in the monitoring range indicated by the impact degree information 33 is multiplied by the alarm level difference of each counting unit, respectively, and the value obtained by multiplying sums the alarms. The determination value may be calculated.

In this embodiment, the ratio of the sum total of the standard electric power of all the electric equipment contained in a counting unit with respect to the sum total of the standard electric power of all the electric equipment contained in a monitoring range is called an influence degree. For example, the total of standard power of the production equipment 6a, the air conditioner 7a, and the lamp 8a included in the building 2a is 60 MW, and the production equipment 6b and the air conditioner included in the building 2b. When the sum of the standard electric powers of 7b and the electric lamp 8b is 40 MW, the influence of the building 2a is 0.6, and the influence of the building 2b is 0.4.

That is, for example, when the alarm level difference of the building 2a is 10 and the alarm level difference of the building 2b is 20, the alarm determination value calculation part 24 will set 10 * 0.6 + 20 * 0.4 = 14 as an alarm determination value. You may make it. However, the influence degree is not limited to the above-mentioned example.

The determination unit 25 acquires the alarm determination value from the alarm determination value calculation unit 24, reads the alarm threshold value information 34 from the storage unit 12, and the obtained alarm determination value is the alarm threshold value information ( It is to judge whether or not the alarm threshold indicated by 34) is exceeded. The determination unit 25 outputs the result of the determination to the alarm transmission unit 27.

Here, the alarm threshold is a threshold for determining whether or not the amount of power used in the monitoring range has exceeded the assumption value, and the characteristics (standard power, etc.), use state, management demand value, and the like of the electric equipment in the monitoring range are described later. It sets suitably based on a value etc. The alarm threshold may be set to 2% of the management demand value, for example. In addition, although an alarm threshold may be set from the standard electric power value of the electric equipment in a monitoring range, in many cases, an electric machine is operated with electric power less than a standard electric power value. Therefore, the actual power consumption (power consumption) of the electric equipment within the monitoring range may be measured, and an alarm threshold may be set based on the sum of the average power usage of each electric equipment within the usual monitoring range.

In addition, the determination unit 25 further reads the time coefficient information 35 from the storage unit 12, and stores the time coefficient indicated by the time coefficient information 35 in the alarm determination value obtained from the alarm determination value calculation unit 24. It may multiply and determine whether the value obtained by multiplying exceeds the alarm threshold which the alarm threshold information 34 shows.

Here, the time coefficient is in an increasing relationship with the elapsed time from the start of the monitoring cycle, and is a coefficient for giving a weight according to the elapsed time to the alarm determination value. The time coefficient may be, for example, elapsed time / 10. In this case, if the elapsed time is 10 minutes, the time coefficient is 1, and if the elapsed time is 20 minutes, the time coefficient is 2. When the elapsed time is 0 to 5 minutes, the time coefficient may be 0, and when the elapsed time is 6 to 30 minutes, the time coefficient may be 1. When the elapsed time is 0 to 10 minutes, the time coefficient is 1, when the elapsed time is 11 minutes to 20 minutes, the time coefficient is 2, and when the elapsed time is 21 minutes to 30 minutes, the time coefficient is 3 You may also In other words, the time coefficient may be expressed as a function of elapsed time.

In addition, when it determines with having exceeded the alarm threshold, the determination part 25 may output it to the contribution calculation part 26. As shown in FIG.

When the contribution calculation unit 26 acquires a determination result from the determination unit 25 that the alarm determination value has exceeded the alarm threshold value, the contribution calculation unit 26 calculates, for each aggregation unit, the contribution degree which is the ratio of the alarm level difference in the aggregation unit to the alarm determination value. It is. The contribution calculator 26 outputs the contributions for each calculated unit to the alert transmitter 27.

When the alarm transmission unit 27 acquires the determination result that the alarm threshold value has been exceeded from the determination unit 25, the alarm transmission unit 27 transmits alarm information indicating that the amount of power used within the monitoring range exceeds the assumption value via the communication unit 15. 9) and / or to the terminal 10. For example, the alert transmitter 27 may transmit the alert information to the terminal 10 by e-mail, and notify the user of the alert contents.

Here, the alarm information more specifically indicates that the amount of power used in the monitoring range is an excess state exceeding the assumed value, and that if the state continues as it is, there is a possibility (or a high possibility) that the management demand value is exceeded. will be. In addition, the said assumption value is a value smaller than the management demand value in elapsed time, and may be set arbitrarily. The hypothetical value may be set to, for example, 50% of the management demand value.

In addition, when the alarm transmission part 27 acquired the determination result from the determination part 25 that it does not exceed an alarm threshold (downgrades an alarm threshold value), and uses it in the monitoring range, when it is said that the previous determination result exceeded the alarm threshold value, it is used. Recovery information indicating that the amount of power has been lowered may be transmitted.

Herein, the recovery information more specifically indicates that the amount of power used within the monitoring range is restored from the excess state to the normal state, and if the state is maintained as it is, the management demand value is not exceeded (or is unlikely to be exceeded). .

Moreover, when the alarm transmission part 27 acquires the determination result that the alarm threshold value was exceeded from the determination part 25, and acquired the contribution for every counting unit from the contribution calculation part 26, the count which shows the highest contribution degree is shown. By specifying the unit, alarm information may be transmitted indicating that the amount of power used in the monitoring range exceeds the assumed value and that the electric equipment included in the specific aggregation unit contributes most to the excess.

Moreover, when the alarm transmission part 27 acquires the determination result that the alarm threshold value was exceeded from the determination part 25, and acquired the contribution amount for every counting unit from the contribution calculation part 26, the order of the value of contribution degree is large. In this case, alarm information indicating a ranking is given to each of the aggregated units, and the amount of power used in the monitoring range exceeds the assumed value, and the ranking given to each aggregated unit is contributed.

In this way, when the amount of power used by any electric device is suppressed, the user can be notified that the amount of power used by the electric device included in the monitoring range can be most effectively reduced.

The alarm transmitter 27 may not transmit the alarm information even when a predetermined time has not elapsed since the start of the monitoring cycle, even when a determination result of exceeding the alarm threshold has been obtained from the determination unit 25. The period during which this alarm information is not transmitted is called an alarm mask period.

The data setting unit 28, based on the user's instructions input from the operation unit 14, the aggregation unit information 31, alarm level value information 32, impact degree information 33, alarm threshold value information 34 And time coefficient information 35 are generated and stored in the storage unit 12.

[Treatment of Electric Power Monitoring Device]

Subsequently, the flow of the process of the electric power monitoring device 1 will be described with reference to FIG. 3. 3 is a flow chart showing an example of the flow of the power amount monitoring process of the power amount monitoring device 1.

As shown in Fig. 3, the data acquisition unit 21 acquires the amount of power used by each electric device from the ammeter 5 via the data input unit 13 (S1). The data acquisition unit 21 outputs the amount of electric power used by each of the acquired electrical devices to the data aggregation unit 22.

The data aggregation unit 22 acquires the amount of electric power used by each electric device from the data acquisition unit 21 and reads out the aggregation unit information 31 from the storage unit 12. Then, the data counting unit 22 counts the cumulative power consumption of the electric equipment from the start of the monitoring cycle to the present time for each counting unit indicated by the counting unit information 31 (S2). The data aggregation unit 22 outputs the accumulated amount of used power for each aggregated unit to the alert level difference calculation unit 23.

The alarm level difference calculation unit 23 acquires the accumulated amount of used power for each aggregation unit from the data aggregation unit 22 and reads out the alarm level value information 32 from the storage unit 12. Then, the alarm level difference calculation unit 23 includes the cumulative amount of power used by the data counting unit 22, the alarm level value at the present time of the counting unit indicated by the alarm level value information 32, for each counting unit. The alarm level difference which is a difference of is calculated (S3). The alarm level difference calculation unit 23 outputs the alarm level difference for each counting unit calculated to the alarm determination value calculation unit 24.

The alarm determination value calculation unit 24 obtains an alarm level difference for each aggregation unit from the alarm level difference calculation unit 23, and calculates an alarm determination value based on the alarm level difference for each aggregation unit (S4).

Subsequently, the determination unit 25 acquires the alarm determination value from the alarm determination value calculation unit 24, reads the alarm threshold value information 34 from the storage unit 12, and the obtained alarm determination value is the alarm threshold value. It is determined whether or not the alarm threshold indicated by the information 34 is exceeded (S5).

Here, when it determines with the alarm determination value exceeding an alarm threshold value (YES in S5), the determination part 25 outputs the determination result to the alarm transmission part 27 and the contribution calculation part 26.

When the contribution calculation unit 26 acquires a determination result from the determination unit 25 that the alarm determination value has exceeded the alarm threshold value, the contribution degree calculation unit 26 calculates the contribution degree which is the ratio of the alarm level difference in the aggregation unit to the alarm determination value for each aggregation unit. It calculates (S6). The contribution calculator 26 outputs the contribution of each calculated unit to the alert transmitter 27.

The alarm transmission unit 27 acquires the determination result that the alarm threshold value has been exceeded from the determination unit 25, and at the same time acquires the contribution of each aggregation unit from the contribution calculation unit 26, and calculates the aggregation unit indicating the highest contribution. It specifies (S7). Then, the alarm transmitter 27 receives, via the communication unit 15, alarm information indicating that the amount of power used in the monitoring range exceeds the assumed value, and that the electric equipment included in the specific counting unit contributes most to the excess. It transmits to the display apparatus 9 and the terminal 10. FIG. The display device 9 and the terminal 10 notify the user of the alarm contents indicated by the received alarm information (S8).

On the other hand, when the determination unit 25 determines that the alarm determination value does not exceed the alarm threshold value (NO in S5), the determination unit 25 outputs the determination result to the alarm transmission unit 27.

When the alarm transmission unit 27 obtains a determination result from the determination unit 25 that the alarm determination value does not exceed the alarm threshold value, the alarm transmission unit 27 further determines whether or not the previous determination result has exceeded the alarm threshold value (S9). When it is said that the previous determination result exceeded the alarm threshold (YES in S9), the alarm transmitter 27 transmits recovery information indicating that the amount of power used within the monitoring range has been lowered to the assumption value. The display device 9 and the terminal 10 notify the user of the contents indicated by the received recovery information (S10). On the other hand, when it is said that the last determination result did not exceed the alarm threshold value (NO in S9), power amount monitoring process is complete | finished.

In addition, the electric power amount monitoring device 1 executes a series of these processes S1 to S10 for each monitoring interval, and monitors the amount of electric power used by the electric apparatus included in the monitoring range within the monitoring period.

In addition, in S4, the alarm determination value calculation part 24 may calculate an alarm determination value by adding up the alarm level difference of each counting unit. In addition, the alarm determination value calculation unit 24 acquires an alarm level difference for each aggregation unit from the alarm level difference calculation unit 23, and reads the influence degree information 33 from the storage unit 12, and influences it. You may calculate the alarm determination value by multiplying the influence degree of each aggregation unit shown by FIG. Information 33 by the alarm level difference of each aggregation unit, respectively, and totaling the value obtained by multiplying.

In addition, in S5, the determination unit 25 reads the time coefficient information 35 from the storage unit 12, and the time coefficient information 35 indicates the alarm determination value obtained from the alarm determination value calculation unit 24. You may multiply the time coefficient and determine whether or not the value obtained by multiplying exceeds the alarm threshold indicated by the alarm threshold information 34.

As time elapses from the start of the monitoring cycle, it becomes difficult to suppress the management demand value or less when the amount of power used exceeds the assumed value. That is, by multiplying the alarm determination value by the time coefficient, it is possible to add the difficulty (risk) of the response based on the elapsed time.

[Example]

Subsequently, a specific embodiment of the power amount monitoring process will be described with reference to FIGS. 4 to 6.

In this embodiment, the counting unit is a unit for each type of electric device. That is, the production facilities 6a and 6b are one aggregate unit (aggregate unit A), the air conditioners 7a and 7b are one aggregate unit (aggregate unit B), and the lamps 8a and 8b are one. We assume count unit (aggregation unit C). The total standard power of the production facilities 6a and 6b is 50 MW / h, the total standard power of the air conditioners 7a and 7b is 30 MW / h, and the total standard power of the lamps 8a and 8b is 20 MW. assumes / h.

And the alarm level value of each counting unit is made into the total standard electric power of the electric apparatus contained in a counting unit. That is, the alarm level value of the aggregation unit A is 50 MW x elapsed time / 60 minutes, the alarm level value of the aggregation unit B is 30 MW x elapsed time / 60 minutes, and the alarm level value of the aggregation unit C is 20 MW x elapsed time / 60 minutes.

In addition, it is assumed that the management demand value is 100 MW and the alarm threshold is set at 2 MW, which is 2% of the management demand value.

In this case, the cumulative power consumption amount of each counting unit in a certain monitoring period, which is aggregated by the data counting unit 22, is shown in FIG. 4 is a graph that plots the cumulative amount of power used in each of the aggregation units A, B, and C, and the alarm level value of each aggregation unit. 4 is the elapsed time (minutes) from the start of the monitoring cycle, and the vertical axis is the cumulative power consumption (MW).

FIG. 5 shows the results calculated by the alarm level difference calculator 23 based on the cumulative amount of power used and alarm level values shown in FIG. 5 is a graph plotting the alarm level difference of each aggregation unit. 5 is the elapsed time (minutes) from the start of the monitoring cycle, and the vertical axis is the warning level difference (MW).

Next, the alarm determination value calculated by the alarm determination value calculation unit 24 is shown in FIG. 6 based on the alarm level difference in each aggregation unit shown in FIG. 5. 6 is a graph plotting the alarm determination value. 6 is the elapsed time (minutes) from the start of the monitoring cycle, and the vertical axis is the alarm determination value (MW). In addition, the alarm determination value calculation part 24 calculates an alarm determination value by adding up the alarm level difference of each counting unit here.

As shown in Fig. 6, when the elapsed time is 24 minutes, the alarm determination value exceeds the alarm threshold, and the contribution unit has the largest aggregation unit C. Therefore, at the time when the elapsed time is 24 minutes, the alarm transmitter 27 exceeds the assumed value in the amount of power used in the monitoring range, and the lamp 8 included in the counting unit C contributes most to the excess. Send alarm information indicating.

At the time when the elapsed time is 25 minutes, the alarm determination value is lowering the alarm threshold. Therefore, when the elapsed time is 25 minutes, the alarm transmitter 27 transmits recovery information indicating that the amount of power used in the monitoring range has been lowered to the assumption value.

[Modifications]

In this embodiment, although the electric power used by the whole electric equipment contained in a monitoring range is acquired, only the electric power used by some electric equipment contained in a monitoring range may be acquired, and the electric power used within a monitoring range may be monitored.

When many electric devices are installed within the monitoring range, the consumption and installation cost of an ammeter or the like for measuring the amount of power used by each electric device increases. In addition, it may be difficult to provide an ammeter for measuring the amount of electric power used by an electric device due to structural problems of the electric device or a situation in which the electric device is installed. Therefore, a situation can be considered in which only the amount of electric power used by some electric devices included in the monitoring range can be obtained.

Even in this case, the alarm threshold value is set accurately based on a predetermined management demand value (target upper limit amount of electricity) for the entire electric equipment included in the monitoring range and the total impact degree obtained by adding up the influence degree of each counting unit. can do.

That is, in this case, the data counting unit 22 classifies some electric devices included in the monitoring range into a plurality of counting units, and calculates a cumulative amount of power used for each counting unit. The alarm level difference calculation unit 23 calculates an alarm level difference that is a difference between the cumulative used power amount and the alarm level value for each counting unit. The alarm determination value calculation part 24 calculates an alarm determination value based on the alarm level difference of each counting unit. In addition, the alarm determination value calculation part 24 may make into this alarm determination value the thing which simply summed the alarm level difference of each aggregation unit, and may calculate an alarm determination value using an influence degree. Then, the determination unit 25 determines whether the alarm threshold value based on the management demand value and the total impact degree has passed the alarm determination value.

For example, it is assumed that an ammeter is provided only in the production facility 6 and the air conditioner 7 except for the lamp 8. In other words, in the above-described embodiment, it is assumed that only the aggregation units A and B are aggregated. When the influence degree is calculated as a ratio of standard electric power, the influence degree of the aggregation unit A is 0.5, the influence degree of the aggregation unit B is 0.3, and the total impact degree of the aggregation units A and B is 0.8.

In the above-described embodiment, the alarm threshold is set to 2% of the management demand value. In this case, the alarm threshold may be set to [management demand value 100 MW] x [total impact degree 0.8] x 0.02 = 1.6 MW.

In this way, even when only the amount of power used by some electric devices included in the monitoring range is acquired, it is possible to determine the accuracy accurately by setting the alarm threshold appropriately.

[supplement]

This invention is not limited to embodiment mentioned above, A various change is possible in the range shown to a claim. That is, embodiment obtained by combining the technical means suitably changed in the range shown to the claim is also included in the technical scope of this invention.

Finally, each block of the power amount monitoring device 1, in particular, the control unit 11 may be configured by hardware logic, or may be realized by software using a CPU as follows.

That is, the power amount monitoring device 1 includes a central processing unit (CPU) for executing instructions of a control program for realizing each function, a read only memory (ROM) containing the program, and a random access RAM (RAM) for expanding the program. memory), a storage device (recording medium) such as a memory for storing the program and various data. In addition, an object of the present invention is a recording medium in which a program code (execution type program, intermediate code program, source program) of a control program of the power amount monitoring device 1, which is software for realizing the above-described functions, can be read by a computer. Can be achieved by supplying the power amount monitoring apparatus 1 to the computer (or CPU or MPU) by reading out and executing the program code recorded on the recording medium.

The recording medium may be, for example, a tape system such as a magnetic tape or a cassette tape, a magnetic disk such as a floppy disk or a hard disk, or a CD-ROM / MO / MD / DVD / CD-R. Disk systems including optical disks, card systems such as IC cards (including memory cards) / optical cards, and semiconductor memory systems such as mask ROM / EPROM / EEPROM / flash ROM.

In addition, the electric power amount monitoring device 1 may be configured to be connectable with a communication network, and the program code may be supplied via a communication network. The communication network is not particularly limited, and for example, the Internet, intranet, extranet, LAN, ISDN, VAN, CATV communication network, virtual private network, telephone line network, mobile communication network, satellite communication network, etc. can be used. Do. In addition, the transmission medium constituting the communication network is not particularly limited, and, for example, infrared, Bluetooth (such as IrDA or remote control) can be used even with a wire such as IEEE1394, USB, power line carrier, cable TV line, telephone line, ADSL line. Trademarks), 802.11 wireless, HDR, mobile phone networks, satellite lines, terrestrial digital networks, etc. The invention may also be realized in the form of a computer data signal embedded in a carrier wave, on which the program code is embodied by electronic transmission.

INDUSTRIAL APPLICABILITY The present invention can be used for a power amount monitoring device that monitors the amount of power used by a plurality of electric devices such as demand monitoring.

1: power monitoring device 3: power meter (measuring device)
5: ammeter (measuring device) 6: production equipment (electrical equipment)
7: Air conditioner (electric equipment) 8: Lamp (electric equipment)
9: display device (notification device) 10: terminal (notification device)
11: control unit 22: data aggregation unit (aggregation means)
23: alarm level difference calculating unit (alarm level difference calculating means)
24: alarm determination value calculation unit (alarm determination value calculating means, impact degree specifying means)
25: determination unit (determination means) 26: contribution calculation unit (contribution calculation unit)
27: alarm transmitter (output means) 100: power monitoring system

Claims (9)

An amount of power monitoring device for monitoring the amount of power used by a plurality of electrical equipment included in the monitoring range,
Counting means for classifying the plurality of electric devices into a plurality of counting units, and counting the amount of electric power used by the electric devices for each counting unit;
Alarm level difference calculating means for calculating an alarm level difference that is a difference between the amount of power used by the counting means and the alarm level value predetermined for each counting unit for each counting unit;
Alarm determination value calculating means for calculating an alarm determination value based on an alarm level difference of each aggregation unit calculated by the alarm level difference calculating means;
Judging means for judging whether or not an alarm judgment value calculated by said alarm judgment value calculation means has exceeded a predetermined alarm threshold value; And
Output means for outputting alarm information indicating that the amount of power used within the monitoring range is exceeded when the determining means determines that the alarm determination value has exceeded the alarm threshold value;
Power amount monitoring device comprising: a.
The method according to claim 1, further comprising: contribution calculation means for calculating each contribution amount that is a ratio of an alarm level difference of the aggregation unit to the alarm determination value;
The output means, when the determination means determines that the alarm determination value has exceeded the alarm threshold value, the electric machine included in the counting unit indicating the highest contribution to the alarm determination value most contributes to exceeding the amount of power used. The amount of power monitoring device characterized in that the output in addition to the alarm information.
The method according to claim 1 or 2, further comprising an influence degree specifying means for specifying each of the counting units, the degree of influence of the electric apparatuses included in the counting unit to all the electric apparatuses included in the monitoring range,
And said alarm determination value calculating means calculates an alarm determination value by adding up the product of the alarm level difference of each counting unit calculated by said alarm level difference calculating means and multiplying each said influence degree.
The said determining means is a value obtained by multiplying an alarm determination value calculated by the alarm determination value calculating means by an elapsed time from a monitoring cycle start time and a time coefficient in an increasing relationship. The amount of power monitoring device characterized in that it determines whether or not the threshold has been exceeded.
4. The determination means according to claim 3, wherein the determination means is based on a total target degree in which the target upper limit power amount predetermined for all the electric devices included in the monitoring range and the influence degree of each aggregation unit specified by the influence degree specifying means are added together. And determining whether or not the alarm threshold value has exceeded the alarm determination value.
The amount of power monitoring device according to claim 1 or 2; And
A measuring device for measuring the amount of power used by the electric device and outputting the measured amount of power used by the electric device to the power amount monitoring device;
Power amount monitoring system comprising a.
The amount of power monitoring device according to claim 1 or 2; And
A notification device which receives the alarm information output from the output means and notifies the user of the alarm contents indicated by the received alarm information;
Power amount monitoring system comprising a.
A power amount monitoring method for monitoring the amount of power used by a plurality of electric devices included in the monitoring range,
A counting step of classifying the plurality of electric devices into a plurality of counting units, and counting the amount of power used by the electric devices for each counting unit;
An alarm level difference calculating step of calculating an alarm level difference that is a difference between the amount of power used aggregated in the counting step and the alarm level value predetermined for each counting unit for each counting unit;
An alarm determination value calculating step of calculating an alarm determination value based on an alarm level difference of each aggregation unit calculated in the alarm level difference calculating step;
A judging step of judging whether or not an alarm judgment value calculated in said alarm judgment value calculation step has exceeded a predetermined alarm threshold value; And
An output step of outputting alarm information indicating that the amount of power used within the monitoring range is exceeded when it is determined in the determination step that the alarm determination value has exceeded the alarm threshold value;
Power amount monitoring method comprising a.
A computer-readable recording medium having a control program recorded therein for operating the power monitoring device according to claim 1 or 2 and for causing a computer to function as the respective means of the power monitoring device.

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