JP2002335591A - Used energy display system and method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an used energy display system for sequentially displaying a time change pattern of a predicted used energy to be a target and an actual used energy and to provide a method therefor. SOLUTION: The used energy display system 1 comprises an used energy storage means 3 for storing used energy data measured so that a time change of the used energy is figured out, a signal processing means 4 for deriving the time change pattern of the predicted used energy from the time change of the past used energy of a consumer, and a display means for displaying the predicted used energy for a predetermined period in the time change pattern and sequentially displaying the actual used energy for the predetermined period in comparison of the predicted used energy with the time.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an energy usage presentation system and method for presenting a predicted target value and an actual measurement value of energy consumption of a consumer.

[0002]

2. Description of the Related Art The method of presenting energy consumption to consumers has been performed by presenting gas consumption, electricity consumption, water consumption, and the like, which are measured at the end of each month, together with bills. Also, when proposing energy saving targets in order to have them implement energy saving activities, by presenting the previous month's energy usage and this month's target energy usage together with the above-mentioned bill, It was suggested that energy consumption should be reduced only by this.

[0003]

However, when it is desired to determine the degree of achievement of the energy saving target in real time, the conventional method of presenting a long-term target value such as one month's energy consumption is inappropriate. It is also possible to simply derive a daily or hourly energy use target by dividing the monthly energy use target, but the average daily use of energy is In addition, since there is a temporal change in the amount of energy used even during the day, it was not possible to derive a target value of the amount of energy used in real time by the simple calculation as described above. As a result, consumers have not been able to determine whether current energy usage is adequate.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and has as its object to provide a method of sequentially presenting target predicted energy usage and actual energy usage so as to be able to appropriately compare them. An object of the present invention is to provide a usage presentation system and a method thereof.

[0005]

A first characteristic configuration of the energy usage presenting system according to the present invention for solving the above-mentioned problems is as described in claim 1 of the claims. Energy consumption storage means for storing the energy consumption data of the consumer measured so that the temporal change of the energy consumption can be understood; and, based on the temporal change of the past energy consumption of the consumer, the predicted energy consumption. Signal processing means for deriving a time change pattern; presenting the predicted energy usage in a predetermined period of the time change pattern; and calculating the actual energy usage in the predetermined period in time with the predicted energy usage. Presenting means for sequentially presenting them in comparison with each other.

A second feature configuration of the energy usage presentation system according to the present invention for solving the above-mentioned problem is, in addition to the first feature configuration, as described in claim 2 of the claims. And a warning means for issuing a warning at a time when the predicted energy usage is equal to or more than a predetermined value.

[0007] A third characteristic configuration of the energy usage presentation system according to the present invention for solving the above-mentioned problem is, in addition to the first characteristic configuration, as described in claim 3 of the claims. The present invention further comprises an alarming means for issuing an alarm when the actual energy usage exceeds the predicted energy usage.

[0008] A fourth characteristic configuration of the energy usage presentation system according to the present invention for solving the above-mentioned problem is as described in claim 4 of the claims. Time zone setting means for setting one or more time zones by providing a predetermined time width before and after the energy use peak time of the pattern, and signal processing for deriving the predicted energy usage of each of the time zones by the consumer Means for comparing the actual energy usage by the consumer up to a predetermined time of the day with the integrated value of the predicted energy usage before the time period including the predetermined time, or Present the actual energy usage by the consumer in the time period including the time so as to be comparable with the predicted energy usage in the time period including the predetermined time. There is the point made and a presentation means.

[0009] A fifth feature of the energy usage presentation system according to the present invention for solving the above-mentioned problem is, in addition to the fourth feature, as described in claim 5 of the claims. And a first energy storage means for storing energy consumption data of the consumer measured so that a temporal change in the energy usage can be understood, wherein the energy usage pattern is determined based on the energy usage data. It is a point that is.

[0010] A sixth characteristic configuration of the energy usage presentation system according to the present invention for solving the above-mentioned problem is, in addition to the fourth characteristic configuration, as described in claim 6 of the claims. And a registration reception unit that receives the energy use peak time of the energy use pattern from the consumer.

[0011] A seventh characteristic configuration of the energy usage presentation system according to the present invention for solving the above-mentioned problems is as described in claim 7 of the claims. In addition to the above-mentioned characteristic configuration, there is provided second energy usage storage means for storing total value data of daily predicted energy usage by the consumer, wherein the signal processing means includes the total value of the predicted energy usage. The point is to derive the predicted energy usage of each of the time zones based on the data and the number of the time zones.

[0012] A first characteristic configuration of the energy usage presenting method according to the present invention for solving the above-mentioned problem is as described in claim 8 of the claims. A signal processing step of deriving a temporal change pattern of the predicted energy consumption of the consumer based on the temporal change of the past energy consumption of the consumer measured so as to be understood; and a predetermined one of the temporal change patterns. A first presenting step of presenting the predicted energy usage during the period to the consumer; and predicting the actual energy usage of the consumer during the predetermined period measured so that the time change of the energy usage is known. And a second presenting step of sequentially presenting energy use amounts in a time-wise manner.

[0013] A second feature configuration of the energy usage presentation method according to the present invention for solving the above-mentioned problem is, in addition to the first feature configuration, as described in claim 9 of the claims. A first alarming step of issuing an alarm at a time when the predicted energy usage becomes a predetermined value or more.

[0014] A third characteristic configuration of the energy usage presenting method according to the present invention for solving the above-mentioned problem is, in addition to the first characteristic configuration, as described in claim 10 of the claims. A second warning step of issuing a warning when the actual energy usage at the predetermined time exceeds the predicted energy usage at the predetermined time.

[0015] A fourth feature of the present invention for solving the above-mentioned problem is that a consumer's daily energy consumption is as described in claim 11 of the claims. A time zone setting step of setting one or more time zones by providing a predetermined time width before and after the energy use peak time of the pattern, and a signal processing for deriving a predicted energy usage amount of each of the time zones by the consumer The step and the actual energy consumption by the consumer up to a predetermined time of the day can be compared with the integrated value of the predicted energy usage before the time period including the predetermined time, or Present the actual energy usage by the consumer in the time period including the time so as to be comparable with the predicted energy usage in the time period including the predetermined time. In that it includes the shown steps.

The operation and effect will be described below. According to the first feature configuration of the energy usage presentation system according to the present invention, the energy usage storage means stores the energy usage data measured so that the temporal change of the energy usage by the consumer can be understood, The signal processing means derives a time change pattern of the predicted energy consumption by the consumer based on the past time change pattern of the consumer's energy usage stored in the energy usage storage means, and presents the presenting means. Can present the predicted energy usage in a predetermined period of the time change pattern, and sequentially present the actual energy usage in the predetermined period in time contrast with the predicted energy usage. . As a result, the current energy usage of the consumer is the predicted energy usage in the same time zone (energy saving target).
Can be presented to the consumer as to whether it is more or less than that of the user, and the consumer who sees the content of the presentation is told, "Currently, the predicted value is exceeded, so the energy consumption will be further reduced in the future. It is possible to know that it is necessary to do so, or that "it is acceptable to use the energy as it is because it is below the predicted value at present", and to give a detailed index to the energy saving activity. Furthermore, by giving consumers detailed indicators for energy conservation activities,
It can be said that the effect of energy saving activities by consumers is exhibited.

According to the second characteristic configuration of the energy usage presentation system according to the present invention, the time when the predicted energy usage becomes a predetermined value or more, for example, the time when the energy usage becomes large for preparing meals. The energy use of the belt is easier due to the large amount of energy used, but the alarm can be issued at that time (or time zone) to give consumers a large reduction in energy consumption at present. Is notified, and further energy saving activities are requested, so that the effect of the energy saving activities can be largely obtained.

According to the third feature configuration of the energy usage presentation system according to the present invention, when the current energy usage by the consumer exceeds the predicted energy usage in the same time zone, contrary to the energy saving activity. Conversely, the possibility of using a large amount of energy increases, so that an alarm can be issued for the excess. By issuing the alarm, the consumer can know that he or she is using a large amount of energy, and can carry out energy saving activities based on this.
As a result, the effect of the energy saving activity can be largely obtained.

According to a fourth characteristic configuration of the energy usage presentation system according to the present invention, the signal processing means sets one or a plurality of time zones in accordance with the daily energy usage pattern of the consumer, A predicted energy usage by the consumer in each of the time zones is derived, and the presenting unit calculates an actual energy usage by the consumer up to a predetermined time in the day before the time zone including the predetermined time. The actual energy usage by the consumer in a time zone including the predetermined time is compared with the integrated value of the predicted energy usage, or the predicted energy usage in the time zone including the predetermined time is calculated. By presenting in a manner comparable to the amount, it is possible to present a target value of energy use by the consumer as a predicted energy use amount for a predetermined period having a time width. That. As a result, if the predetermined time width (in other words, the error allowable range of the actual energy use peak time) is provided before and after the energy use peak time, the actual energy use peak time Does not significantly differ from the predicted value (target value) and the measured value, and there is no demand for severe energy saving behavior for the consumer.

According to a fifth characteristic configuration of the energy usage presenting system according to the present invention, the first energy usage storage means stores the energy of the consumer measured so that the time change of the energy usage can be recognized. Since the usage data is stored, the energy usage pattern can be determined based on the energy usage data.

According to the sixth characteristic configuration of the energy usage presentation system according to the present invention, the registration accepting means accepts the registration of the energy use peak time of the energy use pattern from the consumer, thereby enabling the time zone to be registered. Settings can be made easily. As a result, the possibility that the predicted energy usage and the actual energy usage are shifted in time is reduced, and it is possible to prompt the consumer to appropriately save energy by reflecting the actual life pattern of the consumer. .

According to a seventh characteristic configuration of the energy usage presenting system according to the present invention, the predicted energy usage in each of the time zones is stored in the second energy usage storage means in advance. Since it is derived based on the usage data, the predicted energy usage presented to the consumer can be set to an appropriate value.

According to the first characteristic configuration of the energy usage presenting method according to the present invention, the temporal change pattern of the predicted energy usage of the consumer is based on the past time variation pattern of the energy usage of the consumer. Can be derived, and the predicted energy usage in the predetermined period is presented to the consumer, and the actual energy usage can be sequentially presented in the predetermined period while being temporally compared with the predicted energy usage. As a result, the current energy usage of the consumer is the predicted energy usage in the same time zone (energy saving target).
Can be presented to the consumer as to whether the number is larger or smaller than the above, and a detailed index to the energy saving activity can be given to the consumer who has seen the content of the presentation. Furthermore,
By giving the detailed index to the energy saving activity to the consumer, it can be said that the effect of the energy saving activity by the consumer is exhibited.

According to the second characteristic configuration of the energy usage presenting method according to the present invention, the time when the predicted energy usage becomes equal to or more than the predetermined value, for example, the time when the energy usage increases for preparing a meal. The energy use of the belt is easier due to the large amount of energy used, but the alarm can be issued at that time (or time zone) to give consumers a large reduction in energy consumption at present. Is notified, and further energy saving activities are requested, so that the effect of the energy saving activities can be largely obtained.

According to the third feature configuration of the energy usage presenting method according to the present invention, when the current energy usage by the consumer exceeds the predicted energy usage in the same time zone, contrary to the energy saving activity. Conversely, the possibility of using a large amount of energy increases, so that an alarm can be issued for the excess. By issuing the alarm, the consumer can know that he or she is using a large amount of energy, and can carry out energy saving activities based on this. As a result, the effect of the energy saving activity can be largely obtained.

According to the fourth feature configuration of the energy usage presenting method according to the present invention, one or more time zones are set according to the daily energy usage pattern of the consumer, and Of the predicted energy usage by the total value data of the predicted energy usage and the number of the time periods, the predicted energy usage by the consumer in each of the time periods is derived, Is compared with the integrated value of the predicted energy consumption before the time zone including the predetermined time, or the actual energy usage by the consumer during the time zone including the predetermined time. By presenting the amount so as to be comparable to the predicted energy usage in the time period including the predetermined time, the target value of energy usage by the consumer is set. It can be presented as a predicted energy consumption of a predetermined period having a time width. as a result,
If the predetermined time width (in other words, the error allowable range of the actual energy use peak time) is provided before and after the energy use peak time, and the actual energy use peak time is within the range of the above-mentioned time zone. Therefore, the predicted value (target value) and the actually measured value do not greatly differ from each other, and there is no demand for a severe energy saving action for the consumer.

[0027]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a configuration diagram of an energy usage presentation system according to the present invention. An energy usage presentation system 1 includes an input unit 2 for inputting energy usage data read by an electric meter, a gas meter, a water meter, or the like installed in a household, and an energy usage storage unit 3 for storing the data. And signal processing means 4 for performing various signal processing on the energy usage data, presentation means 5 for presenting the result of the signal processing, and alarm means 6 for issuing an alarm based on the result of the signal processing. Become. It should be noted that the usage data may not be automatically obtained from an electric meter, a gas meter, a water meter, or the like, but may be manually input by a consumer as described later.

More specifically, the energy usage presentation system 1 can be realized by using a kitchen remote control or the like installed in a kitchen or the like for adjusting the temperature of hot water supplied from a water heater. The input means 2 is connected to an electric meter, a gas meter, a water meter, or the like in a wired or wireless manner, so that the energy usage data measured by the meter can be converted into a unit time (for example, 5 (For example, every minute) or the time of use for each unit energy use, and the data is stored in a memory (energy use storage means 3) provided in the energy use presentation system 1. Is stored.
The data input to the input means 2 or the data read from the energy usage storage means 3 is subjected to various kinds of signal processing as described later by a signal processing means 4 realized by a microcomputer or the like. Is presented by the presentation means 5 realized by a liquid crystal display unit or the like of the kitchen remote controller. When the signal processing unit 4 determines that it is necessary to issue an alarm based on the result of the signal processing, an alarm is issued using the alarm unit 6. The alarm means 6 realizes an alarm function by emitting a warning sound or a voice message using an audio alarm function provided in the kitchen remote controller, or by turning on a lamp or the like. Alternatively, the liquid crystal display unit (presenting means 5) is also used as the warning means 6 to display a warning sentence or to change the display color (in the case of a display capable of displaying color, the color is changed, and if a monochrome liquid crystal is used). For example, by changing the color of the backlight), the alarm function may be realized.

[0029] In this case, the energy consumption is simply described, but the electricity consumption, gas consumption, water consumption, etc.
Needless to say, the present embodiment can be applied to various energy sources (utilities) continuously supplied to each household.

(First Embodiment) As described above, the past energy consumption data input from various meters is stored in the energy consumption storage means 3 so that the temporal change of the energy consumption by the consumer can be recognized. Is stored. Therefore,
By performing arithmetic processing such as averaging processing on the data measured daily using the signal processing means 4, a time change pattern of the energy consumption for 24 hours a day can be derived. The change pattern can be a time change pattern of the predicted energy usage (signal processing step).

Further, instead of simply averaging the entire data, averaging is performed for each season or each day of the week, and the fluctuation factor of energy consumption based on weather data such as daily temperature and water temperature is considered. Thus, a temporal change pattern of the predicted energy usage can be derived.

When the present energy usage presentation system 1 is operated, the temporal change pattern of the predicted energy usage derived as described above is presented using the presentation means 5 (first presentation step). FIG. 2A shows an example of the presented temporal change pattern of the predicted energy usage. Here, the time change pattern of the predicted energy usage from the current time (11:00 (11:00)) to two hours later (13:00) is presented, but the length of the time can be freely determined. Can be set.

Next, as shown in FIG. 2B, the real-time energy consumption input to the input means 2 or temporarily stored in the energy consumption storage means 3 passes through the signal processing means 4. Transmitted to the presentation means 5
, And sequentially presented in temporal contrast with the temporal change pattern of the predicted energy usage (second presentation step). As shown in FIG. 2B, the temporal change pattern of the predicted energy usage and the real-time energy usage are superimposed and presented on the same horizontal axis and vertical axis, so that the predicted energy usage, that is, the past Real-time energy usage can be compared with the predicted value of the energy usage calculated based on the energy usage of the above.

Further, not only the predicted energy usage and the real-time energy usage are presented so as to be comparable, but also the time when the energy usage by the consumer is predicted to increase, that is, the predicted energy usage becomes a predetermined value. It is also possible to provide an alarming means 6 which issues an alarm at a time when the value exceeds the value and there is a high risk of using a lot of energy contrary to the energy saving activity. The alarm means 6 installed here is an alarm lamp 6a, and an alarm is given to a consumer by lighting the lamp.

As shown in FIG. 2 (b), during the time period from time t 'to time t'', the predicted energy usage is equal to or more than the predetermined value.
Is turned on (first alarm step). The predetermined value may be set as an absolute value, or may be set as a ratio of the predicted energy usage to the peak value (for example, 80% of the peak value).

As time further elapses, the real-time energy usage exceeds the predicted energy usage at time t ′ ″ shown in FIG. 2C. The fact that the real-time energy usage has exceeded the predicted energy usage means, for example,
Since the total actual energy usage of the day may exceed the sum of the predicted energy usage, it is necessary to pay more attention to the increase in the energy usage after time t ′ ″. Also in this case, the signal processing means 4 turns on the alarm lamp 6a to notify the consumer that the real-time energy usage exceeds the predicted value, and urges the user to reduce the energy usage.

In the above embodiment, the temporal change pattern of the predicted energy usage and the temporal change pattern of the real-time energy usage are presented in a graph and compared. However, as shown in FIG. You may compare. In this case, the current time is 11:35, and 11:00.
From 12:00 to 12:00 (predicted value) (2
kWh) and the real-time energy usage (actual usage) between 11:00 and 11:35 are presented as numerical values,
As time elapses, the value of the real-time energy usage is sequentially updated and presented. When the real-time energy usage is smaller than the predicted value, a comment such as “energy saving status: good” can be presented. Conversely, when the real-time energy usage exceeds the predicted energy usage, the alarm lamp 6a functioning as the alarm means 6 is turned on to give an alarm to the consumer as described above with reference to FIG. . Furthermore, since “energy saving status: caution is required” or the like is presented as a comment,
Can be used together as the alarm means 6.

Further, not only the energy consumption during the specific period from 11:00 to 12:00, but also the "today's target value"
As the total value of the predicted energy usage for the day,
At the same time, the total value of the real-time energy consumption up to the current time can be presented. If the real-time energy usage is lower than the predicted value, the "energy saving situation:
On the contrary, when the real-time energy usage exceeds the predicted energy usage, the alarm lamp 6a is turned on in the same manner as described above with reference to FIG. As described above, a warning can be given to the consumer, and a comment such as "energy saving situation: need attention" can be presented as a comment.

In the example of the presentation means 5 shown in FIG. 3, an "electricity" selection button 7, a "gas" selection button 8, and a "water supply" selection button 9 are further provided. When the "electricity" selection button 7 is pressed, the predicted energy usage and the real-time energy usage related to the electricity usage are presented, and when the "gas" selection button 8 is pressed, the gas usage is displayed. The predicted energy usage and the real-time energy usage related to the amount are presented, and when the “water supply” selection button 9 is pressed, the predicted energy usage and the real-time energy usage related to the water usage are presented. still,
By combining the presentation method illustrated in FIG. 2 (graph display) and the presentation method illustrated in FIG. 3 (character display), it is possible to adopt a presentation method in various display forms.

(Second Embodiment) In the above-described first embodiment, a temporal change value of the predicted energy consumption for 24 hours a day is derived from the temporal change pattern of the energy consumption of the consumer measured daily. Are sequentially presented in comparison with the current energy usage by the consumer, but in the second embodiment, the actual energy usage and the predicted energy usage are compared by another method. Will be described.

An energy usage presentation system 1 'according to the second embodiment as shown in FIG. 4 is similar to the system described with reference to FIG. 1, but a registration reception for receiving registration of information from a consumer. Means 11 and time zone setting means 12 for setting a single or a plurality of time zones by providing a predetermined time width before and after the energy use peak time of the energy use pattern of the consumer's day. Further, it is necessary to make modifications so that functions different from those described with reference to FIG.

More specifically, the energy consumption storage means 3 realized by a memory or the like can store the total value data of the daily energy consumption predicted by the consumer, or further, the temporal change of the energy consumption. It is sufficient that the energy consumption data of the consumer measured as described above is stored. For this purpose, similarly to the first embodiment, the input unit 2 connected to an electric meter, a gas meter, a water meter, or the like by wire or wirelessly converts the energy usage data measured by those meters into a unit time (for example, (For example, every 5 minutes) or usage time per unit energy usage, and once storing those data in the energy usage storage means 3, the total of the predicted energy usage per day There is a way to derive value data. In addition, the total data of the required one-day predicted energy usage is derived from the average of the daily total data of the energy usage measured during the past predetermined period (for example, one week). There are ways. Note that the predicted energy usage is based on attributes of the measured data (information such as season, weather, temperature, and the like when the data was measured, and information on which day of the week, Saturday, or holiday was measured). It is preferable to derive it taking into account.

Yet another alternative is for the consumer to use 24
There is also a method of manually inputting the total value data of the predicted energy usage amount over time via the registration receiving unit 11. in this case,
You have to register the total amount of energy consumption for one month described in the monthly invoice sent from the electric utility, gas utility, water utility, etc. It is possible to derive the total value data of the predicted energy usage of. Alternatively, the total energy data per day may be derived by inputting the predicted energy usage for one month.

The signal processing means 4 is based on the number of the above-mentioned time zones set in the daily energy use pattern of the consumer and the total value data of the daily predicted energy use obtained by the above method. And has a function of deriving a predicted energy usage amount in each of the time zones by the consumer.

Thereafter, the presenting means 5 can compare the actual energy consumption by the consumer up to a predetermined time of the day with the integrated value of the predicted energy usage before the time period including the predetermined time. In some way, the actual energy usage by the consumer during the time period including the predetermined time is presented so as to be comparable with the predicted energy usage in the time period including the predetermined time.

Hereinafter, a second embodiment will be described in detail with reference to the drawings. FIG. 5 shows an example of the presentation means 5. When the consumer's daily energy use pattern is obtained, for example, by inputting the energy use peak time of the energy use pattern by the consumer himself, the registration reception unit 11 inputs the input gas use peak. Reception of the time of is performed. In the example shown in FIG. 4, what is received from the consumer is that the time of the gas usage peak is 7:00 (7:00), 12:00, and 1
There are three cases at 9:00. In this case, an energy use pattern having three gas use peaks is set to a waveform as illustrated in FIG. Note that the number of peak times that can be registered is not limited to three, and one or more arbitrary numbers can be registered.

The energy use pattern can also be determined based on the consumer's energy use data stored in the energy use storage means 3 and measured so that the change over time of the energy use can be understood. .

Next, the daily energy use pattern is shown in FIG.
As shown at 7:00, 12:00, and 19:
When there are three peaks at each time of 00, three time zones including each peak time and having a predetermined time width before and after each peak time are set by the time zone setting means 12. Specifically, setting of a time T1 (9:30) between 7:00 and 12:00 and a time T2 (15:30) between 12:00 and 19:00 are performed. And time zone I from 00:00 to 9:30, 9:30 to 1
Time zone II until 5:30, and 15:30 to 24:
A time zone III up to 00 is set.

Further, in this embodiment, when the number of energy use peaks is three, those peaks are due to the energy use in the morning time, the daytime, and the night time. And the energy use pattern is set with a waveform such that the ratio of the energy use amount in each time zone including each peak time (in FIG. 6, the area of the energy use pattern in each time zone) becomes 2: 1: 3. A description will be given of the case in which the setting of the number of energy usage peaks and the ratio of the energy usage in each time zone including the peak time is not limited to the above, and can be arbitrarily modified. Therefore, even when the number of energy usage peaks is two, or when the number of energy usage peaks is four or more, the ratio of the energy usage in each time zone including the peak time is set to a predetermined value. Can be set to a value. For example, in the case of a consumer whose energy usage during the daytime is larger than the energy usage during the morning and at night, the ratio of the energy usage during the daytime is maximized. Settings can be made.

As described above, the energy use pattern of the consumer, the setting of the time zone according to the energy use pattern, and the setting of the ratio of the energy usage in each time zone including each peak time have been described. With that alone, it is not possible to know the predicted energy usage of the consumer in each time slot. Therefore, a method for deriving the predicted energy usage of the consumer in each time zone will be described below.

Here, as described with reference to FIG. 6, when three time zones (time zone I to time zone III) are set for the energy use pattern of 24 hours a day, the time zone Estimated energy usage of I and time zone II
And the predicted energy usage in the time zone III are set to have a ratio of 2: 1: 3. Thus, if the total value data E _t of the predicted energy consumption of the day is known, prediction in the time zone I energy usage E _1, and the predicted energy usage E ₂ time zone II,
Predicted energy usage E ₃ time zones III is represented by the following equation (1).

[0052]

[Number 1] _{E 1 = 2 / (2 +} 1 + 3) × E t = E t / 3 E 2 = 1 / (2 + 1 + 3) × E t = E t / 6 E 3 = 3 / (2 + 1 + 3) × E t = E t / 2

[0053] Here, as a method for obtaining the total value data E _t of the predicted energy consumption of the day has the following two methods. First, as a first method, similarly to the case of the first embodiment, the input means 2 connected to an electric meter, a gas meter, a water meter, or the like by wire or wirelessly,
The energy consumption data read by those meters is
The data is collected as energy usage per unit time (for example, every 5 minutes) or usage time per unit energy usage, and the data is temporarily stored in the energy usage storage unit 3 and then stored for 24 hours a day. This is a method for deriving total value data of the predicted energy usage. The second method is to estimate the daily energy use from the total value of the monthly energy use described in a bill sent to a consumer every month from an electric utility, a gas utility, a water utility or the like. This is a method in which the total value of the amounts is determined, and the value is input to the consumer using the registration reception unit 11.

According to the above method, E _t , E ₁ , E
₂ and E ₃ , the time change of the integrated value of the predicted energy usage in the energy usage pattern of FIG.
Is obtained with the waveform shown in FIG.

Therefore, at time t, in order to urge the consumer to save energy, the predicted energy usage (the target value for energy saving) in the time zone including the time t and the time zone In this case, the actual energy consumption up to that time may be presented in comparison. To be more specific, taking the gas usage as an example, as shown in FIG. 8A, the predicted energy usage E ₂ = 0.6 m in the time zone II including the time t (the target value in the daytime zone). ³ and 0.8 m ³ of the actual energy consumption (actual value) in that time zone are presented in a comparable manner.

In addition, there is a method of presenting a comparison between the predicted energy usage of the day before the time zone including the time t and the actual energy usage of the day until the time. Specifically, as shown in FIG. 8B, the time zone II including the time t
Estimated daily energy usage E ₁ + E ₂ = 1.
2 + 0.6 = 1.8 m ³ and 2.0 m ³ of the actual energy consumption (actual value) for one day up to that time are presented in a comparable manner.

Further, when the actual energy usage exceeds the predicted energy usage, a warning means 6 similar to that described in the first embodiment is installed to warn the consumer. You can also.

Next, FIG. 9 shows an example in which a consumer registers a daily energy use pattern, which is different from the case shown in FIG. Here, instead of prompting the consumer to input the gas usage peak time, first, the consumer is presented with a plurality of energy usage patterns so that the consumer can select the energy usage pattern using the registration reception unit 11. , The energy use pattern of the consumer is determined based on the result of the selective registration. FIG. 9 shows a case where the energy use pattern has a waveform having three peaks, a waveform having two peaks, and a waveform having one peak. Here, the time of each peak in each energy use pattern can be set in advance (for example, three peaks are set at 7:00, 1
2:00 and 19:00), in which case, when the consumer registers any of the presented energy use patterns, the time of the energy use peak in the energy use pattern Is registered, and the actual energy usage and the predicted energy usage are presented in a comparable manner as described above.

On the other hand, if each peak time in the energy use pattern is not set in advance, the consumer registers any one of the presented energy use patterns and then registers as shown in FIG. A step of presenting a screen and prompting registration of each peak time may be performed.

<Another Embodiment><1> As an example of display on the presentation means 5 of the energy consumption presentation system in the first embodiment and the second embodiment, the predicted energy consumption during one day of life The display screen 10 as shown in FIG. 2, FIG. 3, and FIG. 8 has been exemplified for a method of presenting by comparing the actual energy consumption up to a predetermined time of the day with the actual energy consumption. Not limited. For example, there is also a method of presenting a comparison between the predicted energy usage and the actual energy usage up to a predetermined day of the month while living a month. Similarly, the time period may be every week.

FIG. 10 shows an example of a change between the integrated value of the predicted energy usage amount for one month and the integrated value of the actual energy usage amount for the month. In FIG. 10, a solid line A is a graph showing a change in the integrated value of the actual energy usage, and a broken line B shows a change in the integrated value (the target value of energy saving) of the predicted energy usage. It is a graph. The predicted energy usage is a value derived based on the past energy usage of the consumer.

A method of presenting the predicted energy usage and the actual energy usage in comparison with each other based on the graph of the change in the energy usage shown in FIG. 10 will be described below. FIG. 11A shows a display example at the time of June 28, but what is displayed is the predicted energy usage with respect to the integrated value from June 1 to June 27. It is the ratio (%) of the integrated value of the actual energy consumption from June 1 to June 27, in other words, the actual value of energy saving. Therefore, if the ratio displayed on the display screen 10 is less than 100%, it can be said that the effect of the energy-saving behavior of the consumer has appeared.

As shown in FIGS. 11 (a) and 10,
The integrated value of the actual energy consumption at the end of June 27 is 98% of the integrated value (target value) of the predicted energy usage.
And the effect of the energy saving behavior of the consumer from June 1 to June 27 appears. FIG. 11B shows a display example at the time of June 29.
The integrated value of the actual energy consumption at the end of the 8th is
The value exceeds 100%, such as 101% of the integrated value (target value) of the predicted energy usage at the end of June 28, and it can be said that the consumer's energy behavior is insufficient.

As shown in FIG. 11 (b), instead of presenting the actual value of energy saving up to the previous day using only numerical values, a display that allows comparison with the actual value of energy saving from the previous day is also provided. You can do it too. For example, in FIG. 12, an upward arrow is added to indicate that the ratio has increased from the ratio displayed on June 28 (98%) to the ratio displayed on June 29 (101%). By displaying, it is possible to clearly show to the consumer that the actual energy saving value is reduced and the effect of the energy saving activity is less than the previous day.

<2> In the above embodiment, the predicted value derived by the signal processing means 4 is used as the target value for the consumer as it is. However, the predicted value can be changed and used as the target value. For example, a value obtained by multiplying the derived predicted value by a coefficient (for example, a value obtained by multiplying the predicted value by 0.95) in order to demand a larger energy saving activity from the consumer. It can also be set to a target value. Furthermore, a method of multiplying a coefficient only to the predicted energy consumption during a time period when energy saving activities are more required (18:00 to 2)
There is also a method of multiplying the predicted value between 0:00 and 0.95 only by 0.95).

Furthermore, in addition to the method of using the average value of the actual energy consumption for the 10 days on weekdays as the predicted energy consumption for one day (the target value of energy saving), the energy consumption of the There is also a method in which the average value of the energy consumption for five days is estimated as the predicted energy consumption (target value of energy saving). Alternatively, first, the average value of the energy usage for 5 days is set as the predicted energy usage, and thereafter, when the actual energy usage continuously exceeds the predicted energy usage (for setting the predicted energy usage, If it is impossible, the energy saving target value may be changed to an average value of the actual energy consumption for 10 days.

<3> Input means 2 connected by wire or wirelessly to an electric meter, gas meter, water meter, etc.
, The pulses input from each meter are counted at predetermined time intervals, and the number of pulses is set to a preset value of 1.
When calculating the energy consumption data by multiplying the value of the energy consumption per pulse, arithmetic processing such as obtaining a moving average of the number of pulses may be performed. For example, even if the actually measured number of pulses shows a sudden change due to the influence of the above time interval, the number of pulses should be averaged over a period approximately several times the pulse integration interval (for example, five adjacent pulses). By calculating the average of the number of pulses in a time section, etc., it is possible to obtain time change data of the energy usage amount showing a relatively smooth change. The calculation performed on the energy usage data is not limited to the moving average described above, and various other calculation methods can be applied.

<4> In the above embodiment, the kitchen remote controller was described as an example of the energy usage presenting system 1 or 1 ′. However, the energy usage presenting system can be used even if another device having an arithmetic function is used. It is possible to realize 1, 1 '. For example, when a water heater or a hot water supply system including the same has an arithmetic function, the energy use presentation system according to the present invention can be constructed using those devices.

Accordingly, in the above-described embodiment, the form in which the energy usage data is collected from each meter via the input means 2 has been described. However, as described above, the energy usage is presented by the water heater or the hot water supply system having the same. When the system is realized, since the energy usage presentation system itself controls the energy usage (energy usage data is known), a system that does not need to collect data from each meter is constructed. You can also.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of an energy usage presentation system.

FIGS. 2A to 2C are diagrams showing examples of presentation by presentation means.

FIG. 3 is a diagram illustrating a presentation example in a presentation unit.

FIG. 4 is another configuration diagram of the energy usage presentation system.

FIG. 5 is a diagram illustrating a presentation example in a presentation unit.

FIG. 6 is a diagram illustrating a method of deriving a predicted energy usage.

FIG. 7 is a diagram illustrating a method of deriving a predicted energy usage.

FIG. 8 is a diagram illustrating a presentation example in a presentation unit.

FIG. 9 is a diagram illustrating a method for deriving a predicted energy usage.

FIG. 10 is a diagram illustrating a method of deriving a predicted energy usage.

FIG. 11 is a diagram illustrating a presentation example in a presentation unit.

FIG. 12 is a diagram illustrating a presentation example in a presentation unit.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Energy use presentation system 2 Input means 3 Energy use storage means 4 Signal processing means 5 Presentation means 6 Alarm means 6a Alarm lamp 7 Select button 8 Select button 9 Select button 10 Display screen 11 Registration accepting means 12 Time zone setting means

Continued on the front page (72) Inventor Hideki Okamoto 4-1-2 Hirano-cho, Chuo-ku, Osaka-shi, Osaka Inside Osaka Gas Co., Ltd. (72) Gen Fujii 4-1-2, Hirano-cho, Chuo-ku, Osaka-shi, Osaka No. Osaka Gas Co., Ltd. (72) Inventor Takuhiro Yamada 4-1-2, Hirano-cho, Chuo-ku, Osaka-shi, Osaka Osaka Gas Co., Ltd. (72) Inventor Makoto Kato 4-chome, Hirano-cho, Chuo-ku, Osaka No. 1-2 F-term in Osaka Gas Co., Ltd. (reference) 3L060 AA03 CC08 CC10 DD06 EE45 3L061 BC05 BC07 BD03 5K048 AA16 BA36 EB10 FB00 FB07 FB09 FB10 HA21

Claims (11)

[Claims] 1. Energy consumption storage means for storing energy consumption data of a consumer measured so that a temporal change in energy consumption can be understood, and based on a temporal change in the past energy consumption of the consumer. Signal processing means for deriving a time change pattern of the predicted energy usage, presenting the predicted energy usage in a predetermined period of the time change pattern, and predicting the actual energy usage in the predetermined period. An energy usage presentation system comprising: presentation means for sequentially presenting energy consumption in a time-wise manner. 2. The energy use presentation system according to claim 1, further comprising an alarm unit that issues an alarm at a time when the predicted energy use is equal to or more than a predetermined value. 3. The energy use presentation system according to claim 1, further comprising a warning unit that issues a warning when the actual energy use exceeds the predicted energy use. 4. A time zone setting means for setting one or more time zones by providing a predetermined time width before and after an energy use peak time of a daily energy use pattern of a consumer, and said time by said consumer. Signal processing means for deriving a predicted energy usage of each of the zones; and an actual energy usage by the consumer up to a predetermined time of the day, the estimated energy usage of the predicted energy usage before the time zone including the predetermined time. The actual energy usage by the consumer in the time zone including the predetermined time can be compared with the predicted energy usage in the time zone including the predetermined time so as to be comparable with the integrated value. An energy usage presentation system comprising: a presentation unit that presents the information in a certain manner. 5. A first energy consumption storage means for storing energy consumption data of a consumer measured so that a temporal change in energy consumption can be recognized, wherein the energy consumption pattern is stored in the energy consumption data. The energy usage presentation system according to claim 4, wherein the system is determined based on the information. 6. The energy use presentation system according to claim 4, further comprising a registration accepting unit that accepts the energy use peak time of the energy use pattern from the consumer. 7. A system according to claim 1, further comprising a second energy storage unit for storing total data of daily predicted energy usage by a consumer, wherein said signal processing unit stores said total data of said predicted energy usage and said second data. The energy usage presentation system according to any one of claims 4 to 6, wherein the predicted energy usage in each of the time zones is derived based on the number of time zones. 8. A temporal change pattern of the predicted energy consumption of the consumer is derived based on the temporal change of the past energy consumption of the consumer measured so as to recognize the temporal change of the energy consumption. A signal processing step; a first presenting step of presenting the predicted energy use amount to the consumer during a predetermined period of the time change pattern; and a consumer's measured energy consumption time change so as to be understood. A second presenting step of sequentially presenting the actual energy usage during the predetermined period in time contrast with the predicted energy usage and sequentially presenting the predicted energy usage. 9. The energy use presentation method according to claim 8, further comprising a first warning step of issuing a warning at a time when the predicted energy use is equal to or more than a predetermined value. 10. The method according to claim 8, further comprising the step of: issuing a warning when the actual energy usage at a predetermined time exceeds the predicted energy usage at the predetermined time. 10. The energy usage presentation method according to item 9. 11. A time zone setting step of setting one or more time zones by providing a predetermined time width before and after an energy use peak time of a daily energy use pattern of a consumer, and the time by the consumer A signal processing step for deriving a predicted energy usage of each of the bands; and an actual energy usage by the consumer up to a predetermined time in a day is calculated based on the predicted energy usage before the time zone including the predetermined time. The actual energy usage by the consumer in the time zone including the predetermined time can be compared with the predicted energy usage in the time zone including the predetermined time so as to be comparable with the integrated value. And a presenting step of presenting as is.