JP4641850B2 - Energy saving effect display system and home cogeneration system - Google Patents

Description

  The present invention relates to an energy saving effect display system in a home, and more particularly, to an energy saving effect display system capable of confirming an energy saving effect by going out by applying an existing function of a home cogeneration system.

  In recent years, in order to increase awareness of environmental issues and achieve the goals of the Kyoto Protocol, it has been demanded to promote energy saving (hereinafter abbreviated as “energy saving” as appropriate) not only in business buildings, but also in houses. . Energy saving in homes and the like is achieved, for example, by residents themselves performing energy saving activities such as saving power consumption in power consuming equipment and saving heat consumption in heat consuming equipment. Various techniques for promoting activities have been proposed.

  As a technology for promoting energy saving in a house or the like, there is an energy saving navigation system that displays a monthly total amount of power consumption converted into a charge (for example, see Non-Patent Document 1). This system is composed of a measuring instrument and a display. It measures the voltage and current of the distribution board wiring, calculates the power consumption, converts the power consumption into a charge, and displays it on the display. It is intended to improve motivation for energy saving.

"Introduction to Home Energy Saving Navigation 1", Energy Conservation Center, Internet <URL: http://www.eccj.or.jp/navi/home-system1.html>

  However, the energy-saving navigation system of Non-Patent Document 1 merely displays the monthly total consumption of energy as a charge, and there is a problem that the resident needs to think about what kind of action is energy-saving activity. . On the other hand, since energy consumption is generally lower when not at home (absence period) than when at home, a technique for encouraging residents to go out is desired in order to promote energy saving in homes. In general, it is difficult to continue the same energy saving activity continuously even if it is a waste that can be omitted once. For this reason, technology that supports the sustainability of energy-saving activities is desired.

  The present invention has been made in view of the above problems, and an object thereof is to provide an energy saving effect display system capable of confirming an energy saving effect by going out in order to promote energy saving by going out in a house. It is in. Moreover, the home cogeneration system which can promote the energy saving in a common residence using the said energy saving effect display system is provided.

In order to achieve the above object, an energy saving effect display system according to the present invention includes a load record storage unit that records an actual load value of energy load every unit time in a residence, and the load record storage unit that stores the load record storage unit. A load predicting unit that uses the actual value of the energy load and corrects the past predicted value of the corresponding day of the week to predict the energy load per unit time of the resident in normal time per day, and the dwelling in the dwelling An unattended load prediction unit that calculates a predicted value of the energy load per unit time per day when a person is absent by averaging the minimum actual values of each day in a predetermined period in the past, and the load prediction unit predicts The predicted value of the energy load per unit time of the day at the normal time is input, and the energy load per unit time of the day at the time of absence calculated by the absent time load prediction unit A predicted value is input, and the predicted value of the energy load at the normal time and the predicted value of the energy load at the absence are compared and displayed for each unit time, or the predicted value of the energy load at the normal time and A first feature is that it includes an energy saving effect display unit that displays a difference value from the predicted value of the energy load in the absence.

  According to the energy saving effect display system having the above characteristics, the predicted value of the energy load in the normal time and the absence time can be compared and displayed or the difference value can be displayed, so that the resident can easily save the energy by going out. Can be foreseen. Thereby, a resident's going-out action can be encouraged and energy saving in a house can be promoted.

In order to achieve the above object, an energy saving effect display system according to the present invention includes a load record storage unit that records a record of energy load for each unit time in a house, and an input of a resident absent period in the house. The absence period input unit that receives the actual load value, and the actual value of the energy load accumulated in the load record storage unit, the past predicted value of the corresponding day of the week is corrected, and the resident's normal day in the residence A load predicting unit that predicts an energy load per unit time; and a result value of the energy load per unit time is sequentially input from the load result storage unit, and the absent period is input from the absent period input unit, Comparison display of the predicted value and the actual value at the normal time in the absence period, or a difference value between the predicted value and the actual value at the normal time in the absent period And energy saving effect display unit that indicates, to become equipped with the second feature.

  According to the energy saving effect display system of the above feature, the predicted value and the actual value of the energy load at the normal time at least during the absence period can be compared and displayed, or the difference value can be displayed. The energy saving effect by going out can be easily confirmed. Thereby, a resident's going-out action can be encouraged and energy saving in a house can be promoted.

  The energy saving effect display system according to the present invention having the above-described features is characterized by accumulating a difference between the predicted value and the actual value for each unit time on the day of the day to reduce the amount of energy load per day. A third feature is that an energy saving effect calculating unit that calculates the amount of increase in the absence period on the day and calculates the energy saving effect associated with the increase in the absence period is provided as a third feature.

  According to the energy saving effect display system of the above feature, since the amount of reduction in the daily energy load and the amount of increase in the absence period are calculated, the resident can easily grasp the energy saving effect due to the increase in the absence time. It is possible to promote the outing behavior of residents.

  Furthermore, in the energy saving effect display system according to the present invention having any one of the above features, part or all of the data displayed by the energy saving effect display unit is transferred to the resident by way of a predetermined communication line. A data transmission unit that can be transmitted to the information terminal used in the fourth feature is a fourth feature.

  According to the energy saving effect display system having the above characteristics, a resident can easily grasp the energy saving effect due to going out in real time at the place of going out. As a result, the resident's going-out behavior can be promoted.

  The energy saving effect display system according to the present invention having any one of the above features is characterized in that the load record storage unit and the load prediction unit are the same type of load record storage unit mounted in an operation control unit of a home cogeneration system. It is characterized by using a load prediction unit.

  Generally, in a home cogeneration system, since the operation control is performed by predicting the energy load (thermal load and power load) per unit time on the control target day, the past actual value of the energy load used for the prediction of the energy load is used. A load record storage unit for storing and a load prediction unit for calculating a predicted value of energy load are provided. Therefore, by using the existing equipment of the home cogeneration system, such as the energy saving effect display system having the above characteristics, the load result storage unit and the load prediction unit of the energy saving effect display system are realized, thereby realizing the load result storage. This eliminates the need to newly create a load part and a load prediction unit, saves labor for producing the present invention, and allows the present invention to be realized at low cost.

  In order to achieve the above object, a household cogeneration system according to the present invention includes the energy saving effect display system having any one of the first to fourth characteristics.

  According to the home cogeneration system having the above characteristics, all the effects of the energy saving effect display system having any one of the above first to fourth characteristics can be achieved, and the resident can easily grasp the energy saving effect by going out. can do. Furthermore, since the existing equipment is used, the home cogeneration system according to the present invention can be realized at low cost.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of an energy saving effect display system and a home cogeneration system according to the present invention will be described with reference to the drawings.

<First Embodiment>
First, a first embodiment of a home cogeneration system provided with an energy saving effect display system according to the present invention will be described with reference to FIGS. In the present embodiment, a heat load and an electric power load are assumed as energy loads. Hereinafter, the power load will be described as an example.

  FIG. 1 is a block diagram showing a schematic configuration of a home cogeneration system 1 including an energy saving effect display system 2. The home cogeneration system 1 here is a gas engine generator comprising a gas engine that outputs mechanical rotational energy by combustion of city gas, and a generator that converts the rotational energy into electrical energy and outputs alternating current power. An inverter 14 for converting AC power generated by the unit 12 and the generator into AC power having the same voltage and frequency as those of the commercial power system 5 and connecting the commercial power system 5 to the power load 4 in a grid connection. The heat exchanger 13 for recovering exhaust heat generated from the gas engine, the heat energy recovered by the heat exchanger 13, for example, hot water heating equipment such as floor heating or bathroom dryer, The operation of the exhaust heat utilization hot water supply / heating unit 15 and the gas engine generator unit 12 for use in the heat load 3 including the hot water supply equipment used for And a driving control unit 11 Gosuru. The home cogeneration system 1 further includes a flow meter 31 and a thermometer 32 for measuring the performance of the thermal load 3, and an ammeter 41 and a voltmeter 42 for measuring the performance of the power load 4. The household cogeneration system 1 also includes a remote controller 10 that sets hot water supply temperature and heating temperature.

  The operation control unit 11 of the home cogeneration system 1 according to the present embodiment controls the start and stop of the gas engine generator unit 12 on the control target date of the home cogeneration system 1 in order to control the heat load 3 on the control target date. And the power load 4 is predicted. Specifically, as shown in FIG. 2, the operation control unit 11 includes a load record storage unit 21 and a load prediction unit 22, and includes a flow meter 31, a thermometer 32, an ammeter 41, and a voltmeter 42. Data can be acquired.

  The load record storage unit 21 records a record of energy load for each unit time every day in the residence. The unit time of this embodiment is 1 hour. Specifically, the load record storage unit 21 obtains the measured values of the flow meter 31 and the thermometer 32 in units of one hour, calculates the actual value of the thermal load 3, and obtains the measured values of the ammeter 41 and the voltmeter 42. Obtained in units of 1 hour, calculate the actual value of the power load 4, and store it. Note that the load record storage unit 21 of the present embodiment is configured to classify and store the record values for one week for each day of the week.

  The load predicting unit 22 predicts an energy load per unit time per day in a normal time of a resident in the residence based on the actual values of the thermal load 3 and the power load 4 accumulated in the load actual storage unit 21.

  Here, the load prediction unit 22 of the present embodiment is accumulated in the load performance storage unit 21 of the day of the week corresponding to the actual value using the determined actual value when the actual value of the day is determined. Correct past predicted values. The operation control unit 11 acquires the predicted value stored in the load record storage unit 21 on the day and performs start / stop control of the gas engine generator unit 12.

Hereinafter, correction of the prediction value by the load prediction unit 22 will be described. The load predicting unit 22 records the actual value E _m (t) (t = 0, 1) of the hourly energy load measured by the load record storage unit 21 at the time when the actual value of the day is determined, that is, 0:00 in this example. ,..., 23), and the past predicted value E _b (t) of the day of the week corresponding to the acquired actual value E _m (t). Subsequently, the load prediction unit 22 corrects the past predicted value E _b (t) to obtain a new predicted value E _st (t). The predicted value E _st (t) is obtained by the equation (1). Here, t is a variable representing a time zone.

[Equation 1]
E _st (t) = E _m (t) × 0.5 + E _b (t) × 0.5

The predicted value E _b (t) is determined to be at home, the actual value E _m (t) is determined to be absent, and the predicted value E _b (t) is determined to be absent. The time zone that is determined to be at home from the actual value E _m (t) may be regarded as a resident performing a different behavior and may not be corrected.

The load prediction unit 22 calculates a predicted value E _st (t) for each unit time, and calculates the predicted value E _b (t) of the same day stored in the load record storage unit 21 as the calculated predicted value E _st ( Replace with t).

  Next, an energy saving effect display system 2 according to the present invention will be described with reference to FIGS. The energy saving effect display system 2 of the present embodiment is composed of computer hardware and application software executed on the hardware, and generates power, hot water supply, and heating by consuming city gas (natural gas). This is realized by applying the existing function of the home cogeneration system 1.

  As shown in FIG. 2, the energy saving effect display system 2 includes an unattended load prediction unit 23 and an energy saving effect display unit 24, and is configured to be able to perform data communication with the home cogeneration system 1. The energy saving effect display system 2 of the present embodiment further includes a data transmission unit 25, and is configured to be capable of data communication with an information terminal via a communication network 6 such as a telephone line or the Internet.

The absent load prediction unit 23 calculates a predicted value of the energy load per unit time per day when the resident is absent in the residence. Here, the predicted value E _min of the energy load when going out is obtained by obtaining the minimum actual value of each day of the past week from the load actual storage unit 21 and averaging them.

  The energy saving effect display unit 24 inputs the predicted value of the energy load for each unit time of the day at the normal time predicted by the load prediction unit 22, and for each unit time of the day at the time of absence calculated by the load prediction unit 23 for the absence. The predicted value of the normal energy load and the predicted value of the normal energy load and the predicted value of the non-absent energy load are compared and displayed for each unit time, or the predicted value of the normal energy load and the non-existing value The difference value from the predicted value of the energy load is displayed. The energy saving effect display unit 24 of the present embodiment displays a comparison display or a difference value on the display screen of the remote controller 10 of the home cogeneration system 1.

Here, FIG. 3 shows a comparative display example in which the predicted value of the power load 4 during normal time and the predicted value of the power load 4 when absent are compared every hour. The bar graph is the predicted value E _st (t) of the power load 4 when the resident is normal, and the broken line on the graph is the predicted value E _min of the power load 4 when the resident is out (when absent). It can be said that the time zone in which the predicted value E _st (t) of the normal power load 4 exceeds the broken line on the graph is a time zone in which the reduction of the energy load due to going out is expected.

  The data transmission unit 25 is configured to be able to transmit part or all of the data displayed by the energy saving effect display unit 24 to an information terminal used by a resident on the go via a predetermined communication line. The information terminal here is a mobile phone 7 or a PC (Personal Computer) 9. The data transmission unit 25 is configured to be able to output data to the resident's mobile phone 7 via the communication network 6 and the mobile phone network 8 and configured to be able to output data to the PC 9 via the communication network 6. is there. Thereby, the resident can acquire the energy saving effect by going out in real time when going out.

Second Embodiment
A second embodiment of a home cogeneration system 1 equipped with an energy saving effect display system 2 according to the present invention will be described with reference to FIGS. In the present embodiment, a case where the display target is different from that in the first embodiment will be described. In addition, since the structure of the home cogeneration system 1 is the same as the said 1st Embodiment, the description is omitted in this embodiment. The energy saving effect display system 2 according to the first embodiment is useful when, for example, foreseeing the energy saving effect due to going out, but the energy saving effect display system 2 according to the present embodiment is, for example, a resident. It is useful for confirming the energy saving effect of going out after going out.

  As shown in FIG. 2, the energy saving effect display system 2 of the present embodiment includes an absent period input unit 26 and an energy saving effect display unit 24, and, similarly to the first embodiment, the home cogeneration system 1 and It is configured to allow data communication. The energy saving effect display system 2 of the present embodiment further includes an energy saving effect calculation unit 27 and a data transmission unit 25, and is configured to be able to perform data communication with an information terminal via a communication network 6 such as a telephone line or the Internet. ing.

  The absent period input unit 26 receives an input of the absent period of the resident in the residence. In this embodiment, it is comprised so that a resident can input an absent period in the operation panel of the remote control 10 of the home cogeneration system 1. Specifically, the resident is configured to make an absence setting on the remote controller 10 before going out and to cancel the absence setting when returning home. The absence period input unit 26 acquires the absence setting time and the cancellation time from the remote controller 10, and automatically calculates the absence period based on the absence setting and cancellation.

  The energy saving effect display unit 24 sequentially inputs the actual value of the energy load per unit time from the load result storage unit 21, inputs the absent period from the absent period input unit 26, and predicts the actual energy load value and the actual result. The values are compared for each unit time, and the normal predicted value and the actual value in the absence period are compared and displayed, or the difference value between the normal predicted value and the actual value in the absent period is displayed.

  Specifically, the energy saving effect display unit 24 of the present embodiment displays a comparison display of the predicted value and the actual value in the absence period, or displays the predicted value and the actual value on the display unit of the remote control 10 of the home cogeneration system 1. Display the difference value. Here, FIG. 5 shows an example of the comparison display displayed on the display screen of the remote controller 10, and the predicted value and the actual value for the power load 4 are displayed in units of one hour. In addition, the broken line A is a time slot | zone when the electric power load 4 decreased by going out, and the broken line B is a time slot | zone when the electric power load 4 increased at home.

  The energy saving effect calculation unit 27 calculates the reduction amount of the energy load per day and the increase amount of the absent period of the day by accumulating the difference between the predicted value and the actual value for each unit time on the day of the day. Then, the energy saving effect accompanying the increase in the absence period is calculated. Here, FIG. 6 shows a display example of the difference value between the normal predicted value and the actual value displayed on the display screen of the remote controller 10, and the daily outing time and the daily hourly prediction. The amount of power reduction obtained by accumulating the difference between the actual value and the actual value, and the energy saving effect associated with the increase in the absence period are displayed. The energy saving effect is the amount of power reduction per hour on the display target date.

<Third Embodiment>
Next, a third embodiment of the energy saving effect display system 2 according to the present invention will be described with reference to FIG. In the said 1st and 2nd embodiment, although the energy saving effect display system 2 was implement | achieved using the load performance memory | storage part 21 and the load prediction part 22 with which the operation control part 11 of the home cogeneration system 1 was equipped. In this embodiment, the case where the energy saving effect display system 2 includes the load record storage unit 21 and the load prediction unit 22 will be described.

  As shown in FIG. 7, the energy saving effect display system 2 of the present embodiment includes a load record storage unit 21, a load prediction unit 22, an absent load calculation unit 23, an energy saving effect display unit 24, a data transmission unit 25, and absence. A period input unit 26 and an energy saving effect calculation unit 27 are provided. In addition, the energy saving effect display system 2 of the present embodiment is configured to be capable of data communication with an information terminal via a communication network 6 such as a telephone line or the Internet, as in the first and second embodiments. . Furthermore, the energy saving effect display system 2 of the present embodiment is configured to be capable of data communication with an ammeter 41 and a voltmeter 42 for measuring the performance of the power load 4 supplied from the commercial power system 5. The absence load calculation unit 23, the energy saving effect display unit 24, the data transmission unit 25, the absence period input unit 26, and the energy saving effect calculation unit 27 have the same functions as those in the first and second embodiments. In this embodiment, the description thereof is omitted.

  The load record storage unit 21 records a record of energy load for each unit time every day in the residence. The load record storage unit 21 of the present embodiment acquires a measurement value every hour from an ammeter 41 and a voltmeter 42 for measuring the record of the power load 4 supplied from the commercial power system 5. The actual value of the power load 4 for each hour is calculated and stored.

  The load predicting unit 22 predicts an energy load per unit time per day in the normal time of the resident in the residence based on the actual value of the energy load accumulated in the load actual storage unit 21. The load predicting unit 22 according to the present embodiment calculates a predicted value of the power load 4 for every hour in the normal time based on the actual value of the power load 4 calculated and stored by the load record storage unit 21.

<Another embodiment>
<1> In the first and second embodiments, the energy saving effect is obtained for the power load 4. However, in the home cogeneration system 1, not only the power load 4 but also the heat load 3 is obtained and predicted. Therefore, it may be configured to obtain an energy saving effect with respect to the thermal load 3, or may be configured so that the energy saving effect with respect to the power load 4 and the heat load 3 can be individually displayed. You may comprise so that the energy saving effect with respect to the load 4 and the heat load 3 can be totaled and displayed.

  <2> In the first embodiment, the energy saving effect calculation unit 23 calculates the predicted value of the energy load when absent, but is further configured to calculate the energy saving effect due to going out per unit time. Also good.

Specifically, the energy saving effect calculation unit 23 of the present embodiment calculates an energy load reduction predicted value as the energy saving effect. The energy load reduction predicted value is obtained by the difference between the normal energy load predicted value E _st (t) and the absent energy load predicted value E _min . Here, FIG. 8 shows an example of the predicted reduction value of the power load 4 every hour.

  <3> In the second embodiment, the absent period input unit 26 inputs the entire absent period. However, the absent period may be configured to be input in part, for example, for each outing destination.

  Specifically, the energy saving effect display system 2 of the present embodiment is configured to be able to perform data communication with an information terminal that can read information on a card owned by a resident, and information on whereabouts recorded on the card Based on the above, the energy saving effect or the like is displayed on the information terminal. Here, a case where a PC 9 owned by a resident is assumed as an information terminal and a non-contact IC card is assumed as a card will be described. The information on whereabouts is the entry and exit times of the supermarkets and museums where IC card readers that can communicate with IC cards owned by residents are installed. Time and entry times are recorded.

  The absent period input unit 26 of the present embodiment acquires information on the IC card via the PC 9 and sets the time period from the entry time to the entry time of each destination as a stay period (absence period). Furthermore, the energy saving effect calculation part 23 of this embodiment considers the stay period for every going out as an absent period in a residence, calculates an energy reduction amount, and memorize | stores an energy reduction amount for every going out place in an IC card. In addition, when the destination is moved within the unit time, the energy reduction amount in the unit time is distributed according to the stay time ratio of each destination.

  The IC card reader stores the entry time and entry time on the resident's IC card, obtains the energy reduction amount corresponding to the previous stay stored in the IC card, and gives points according to the energy reduction amount To do. Furthermore, the IC card reading device acquires the energy reduction amount for the previous stay stored in the IC card. Here, for example, an effect of prompting the resident to go out can be expected by allowing the resident to receive a service corresponding to the point.

  <4> In each of the above embodiments, the load prediction unit 22 calculates the predicted value of the energy load for each day of the week, but may calculate the predicted value of the energy load using other day classifications such as holidays and weekdays. The predicted value of the energy load may be calculated by further classifying by month or season.

  <5> In the first and second embodiments described above, the energy saving effect display system 2 is provided separately from the home cogeneration system 1, but it is also preferable to construct it in the home cogeneration system 1.

  <6> In each of the above embodiments, the energy saving effect display system 2 is applied to the household cogeneration system 1, but it may be applied to other energy supply devices such as a water heater, a hot water heater and a heat pump.

The block diagram which shows the schematic structural example of the household cogeneration system and energy saving effect display system which concern on this invention The block diagram which shows the schematic structural example of 1st Embodiment of the energy saving effect display system which concerns on this invention. The graph which shows the comparative display example of the predicted value of the energy load of the energy saving effect display system which concerns on this invention at the time of normal time and absence The block diagram which shows the schematic structural example of 2nd Embodiment of the energy saving effect display system which concerns on this invention. Schematic which shows the comparison display example of the normal time predicted value and actual value of the energy-saving effect display system which concerns on this invention Schematic which shows the example of a display of the difference value of the predicted value and actual value at the time of the normal of the energy saving effect display system which concerns on this invention The block diagram which shows the schematic structural example of 3rd Embodiment of the energy saving effect display system which concerns on this invention. Schematic which shows the example of a display of the energy saving effect in the energy saving effect display system which concerns on this invention

Explanation of symbols

1: Home cogeneration system 2 according to the present invention: Energy saving effect display system 3: Thermal load 4: Electric power load 5: Commercial power system 6: Communication network 7: Mobile phone 8: Mobile phone network 9: PC
DESCRIPTION OF SYMBOLS 10: Remote control 11: Operation control part 12: Gas engine generator unit 13: Heat exchanger 14: Inverter 15: Waste heat utilization hot water supply heating unit 21: Load performance storage part 22: Load prediction part 23: Absence load prediction part 24 : Energy saving effect display unit 25: Data transmission unit 26: Absence period input unit 27: Energy saving effect calculation unit 31: Flow meter 32: Thermometer 41: Ammeter 42: Voltmeter

Claims (6)

A load record storage unit that records a record of energy load for each unit time of day in the residence;
The actual load value stored in the load record storage unit is used to correct the past predicted value of the corresponding day of the week to predict the energy load per unit time of the resident's normal time in the residence. A load prediction unit to
An unattended load prediction unit that calculates a predicted value of the energy load for each unit time in a day in the absence of a resident in the residence by averaging the minimum actual values of each day in a predetermined past period ;
The predicted value of the energy load for each unit time of the day at the normal time predicted by the load prediction unit is input, and the prediction of the energy load for the unit time of the day at the time of absence calculated by the unattended load prediction unit. A value is input, and the predicted value of the energy load at the normal time and the predicted value of the energy load at the absence are compared and displayed for each unit time, or the predicted value of the energy load at the normal time and the predicted value of the energy load An energy saving effect display unit for displaying a difference value from the predicted value of the energy load in the absence;
An energy-saving effect display system comprising: A load record storage unit that records a record of energy load for each unit time of day in the residence;
An absent period input unit that accepts an input of an absent period of a resident in the residence;
The actual load value stored in the load record storage unit is used to correct the past predicted value of the corresponding day of the week to predict the energy load per unit time of the resident's normal time in the residence. A load prediction unit to
The actual value of the energy load per unit time is sequentially input from the load actual storage unit, the absent period is input from the absent period input unit, and at least the predicted value and the actual value at the normal time in the absent period A comparison display, or an energy saving effect display unit for displaying a difference value between the predicted value and the actual value in the normal time in the absence period;
An energy-saving effect display system comprising:   The difference between the predicted value at the normal time and the actual value for each unit time on the day of the day is accumulated to calculate a reduction amount of energy load per day and an increase amount of the absent period on the day. The energy saving effect display system according to claim 2, further comprising an energy saving effect calculation unit that calculates an energy saving effect accompanying an increase in the absence period.   A data transmission unit capable of transmitting a part or all of the data displayed by the energy saving effect display unit to an information terminal used by the resident on the go via a predetermined communication line. The energy saving effect display system according to any one of claims 1 to 3.   The load actual storage unit and the load predicting unit are configured by using a load actual storage unit and a load predicting unit of the same type mounted in an operation control unit of a home cogeneration system. The energy-saving effect display system according to any one of -4.   A home cogeneration system comprising the energy saving effect display system according to any one of claims 1 to 4.