JP2002334136A - Distributed power generation system, energy management system capable of using the same and information distributing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide technology to introduce a distributed power generation system such as a fuel battery and to promote the use of it. SOLUTION: A plurality of distributed power generation systems 12 are connected with a managing device 24 of a management company via the Internet 20. The distributed power generation systems 12 acquire quantity of power consumption, gas consumption and water consumption by every user, display the quantity on a display device and manage it by the managing device 24. The managing device 24 distributes practical information and advertisement to the user based on the user's consumption trend.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply technology, and more particularly to a distributed power generation system, an energy management system using the same, and an information distribution method.

2. Description of the Related Art In an era where new technologies such as IT and biotechnology are deployed on a global scale, even in such a situation,
The energy industry remains one of the largest core industries. Recently, with the spread of environmental awareness, including prevention of global warming, expectations for so-called new energy are increasing. In addition to environmental friendliness, new energy can be produced in a decentralized manner close to power consumers, so it has advantages in terms of transmission loss and security of power supply. It is also expected that the development of new energy will have the secondary effect of creating new peripheral industries.

The approach to new energy is about 30
In response to the oil crisis a year ago, full-fledged energy became available.Currently, renewable energy such as solar power generation, recycling energy such as waste power generation, high-efficiency energy such as fuel cells, and new fields of energy represented by clean energy vehicles Are in the stage of development for practical use.

[0003] Among them, fuel cells are one of the most noticeable energies in the industry. Fuel cells are
Hydrogen produced by mixing water vapor with a hydrocarbon fuel represented by natural gas or methanol and oxygen collected from the atmosphere are chemically reacted to generate electricity and heat at the same time.The only by-product of power generation is water. Yes, high efficiency even in low output range,
Moreover, the power generation is stable without being affected by the weather. The polymer electrolyte fuel cell is regarded as one of the next-generation standard power supplies for both stationary and on-vehicle applications, such as residential use.

[0004]

At present, a power generation system using a polymer electrolyte fuel cell is in the process of being prototyped and put into practical use. The spread of fuel cells depends on how costs can be reduced. Initial costs are a development issue,
Operational costs or benefits also depend on the relationship between the fuel cell system and the commercial power system.

[0005] Therefore, in order to spread the fuel cell, it is necessary to construct not only the technical improvement of the fuel cell itself but also an environment using the fuel cell as a business model. It is necessary to highlight the merits of the entire stakeholders, including the first.

The present invention has been made in view of such a background, and an object of the present invention is to provide a technique for promoting introduction and use of a distributed power generation system such as a fuel cell.

[0007]

One embodiment of the present invention relates to a distributed power generation system (hereinafter simply referred to as a distributed power generation system). This system has a power generation device, and has a consumption detection unit that detects a consumption amount of power and gas used by a user of the power generation system and a display device that integrally displays the consumption amount of power and gas. An information presenting unit. The “power generation device” may be any, but a fuel cell using gas for power generation is one suitable example. The “display device” may be a liquid crystal screen or the like which the power generation device integrally has.

In general, a distributed power generation system is supplied with gas from a gas system of a gas company at a place where the power generation system is installed, for example, a house or a building. "Power consumption"
Refers to the total consumption of each user including both the amount of power supplied and consumed by the power generation of the present system and the amount of power supplied and consumed from the commercial power system. “Gas consumption” refers to the total consumption of each user, including both the amount of gas used for power generation by the fuel cell and the amount of gas consumed for other uses. Electricity rates and gas rates are determined based on the supply amount from the electric power system or gas system, and are borne by consumers, that is, users of this system (hereinafter, also simply referred to as users).

The power meter included in the distributed power generation system is also used for measuring power supplied from a power system, and a gas flow detector such as a mass flow meter is also used for measuring gas consumption other than for power generation. And display on the screen together, it becomes possible to centrally manage power and gas. Further, the measurement and display of the water consumption may be added and displayed in a unified manner.

According to another aspect of the present invention, there is provided a distributed power generation system comprising: a consumption detection unit for detecting a power consumption used by a user of the power generation system; and an information storage for recording the power consumption in time series. And an information presentation unit that reads a history of power consumption from the information storage unit and displays the history on the display device. The information presentation unit may display the consumption amount on a display device that is electronically connected while maintaining a physically separated state from the power generation system. The “display device” here is, for example, a liquid crystal screen of a remote controller that is separate from the power generation device, or a screen of a television or a personal computer installed in a home.

According to another aspect of the present invention, there is provided a distributed power generation system comprising: a consumption detection unit configured to detect a gas consumption amount used by a user of the power generation system; and an information unit configured to record the gas consumption amount in time series. An information presenting unit that reads a history of gas consumption from the information accumulating unit and causes the display device to display the history; This information presentation unit may also display the consumption amount on a display device that is electronically connected while maintaining the physical separation state from the power generation system.

[0012] Still another embodiment of the present invention relates to an energy management system. This system is connected to a distributed power generation system having a power generation device via a network, and includes a management device capable of remotely confirming a power consumption amount used by a user of the distributed power generation system. This management device exchanges practical information including information related to power consumption with a user of the distributed power generation system via a display device connected to the distributed power generation system. The “information related to the consumption amount” may be information such as the consumption amount of the user in a given month, the difference from the consumption amount in other months, and the fee based on the consumption amount. The “practical information” is information for a user that can be selected based on the consumption amount and the tendency of the fee, and is, for example, trivia about a power saving method, information useful for daily life, advertisement, and the like. The “network” may be the Internet.

[0013] The management device may manage the consumption trend of the user's power or gas based on the consumption amount, and may display practical information corresponding to the consumption trend on the display device. The management device may classify users according to consumption trends, select an advertisement corresponding to the classification, and display the advertisement on the display device as practical information.

[0014] An energy management system according to still another aspect of the present invention is connected to a distributed power generation system having a power generation device that uses gas for power generation through a network, and is used by a user of the distributed power generation system. Includes a management device that can remotely check the amount of consumption. The management device exchanges practical information including information related to gas consumption with a user of the distributed power generation system via a display device connected to the distributed power generation system.

This management device also manages the power or gas consumption trend of the user based on the consumption amount, and may display practical information corresponding to the consumption trend on a display device, or may display the information on the consumption trend. After the users are classified according to the classification, an advertisement according to the classification may be selected and displayed on the display device as practical information.

[0016] An energy management system according to still another aspect of the present invention is connected to a distributed power generation system having a power generation device via a network to reduce consumption of at least a part of resources used by a user of the distributed power generation system. The information may be remotely managed via the network, and information contributing to the saving of the fee may be selected according to the amount of consumption and displayed on the screen of the distributed power generation system. "resource"
May include water, including electric power and gas. “Information contributing to cost savings” may be practical information or an advertisement.

Still another preferred embodiment according to the present invention relates to an information distribution method. The method includes detecting a consumption trend regarding at least a part of resources used by a user of a distributed power generation system having a power generation device, classifying the users of the distributed power generation system into a plurality of types according to the consumption trend, Advertise according to the classification. The “type” may be categorized based on, for example, estimated number of households, life cycle, life style, and the like.

Any combination of the above components,
What replaced the components and expressions of the present invention among methods, apparatuses, systems, computer programs, recording media storing computer programs, and the like is also effective as an aspect of the present invention.

[0019]

FIG. 1 shows an overall configuration of an energy management system 10 according to an embodiment. The figure shows a general electronic network, not a network for power distribution, gas distribution and water distribution.

In the energy management system 10, a plurality of distributed power generation systems 12 and a management company 22 including a management device 24 that manages them collectively are connected via the Internet 20. The management company 22 is connected to a power company 28, a gas company 26, a water service company 29, an advertising agency 25, and an advertisement providing company 27 by a dedicated line, and performs a business entrusted by these companies. The power company 28 has the power system 16
The power is supplied to the homes and buildings of the consumers having the distributed power generation system 12 through the power generation system. Similarly, the gas company 26 supplies gas through the gas system 14, and the water utility 29 supplies water through the water system 18. Distributed power generation system 12
Includes a fuel cell system that utilizes gas and water for power generation. Advertising Agency 25 and Advertising Provider 27
Transmits information on the advertisement to the management device 24.

The basic feature of the energy management system 10 is that the power, gas, and water consumption of each user is confirmed and displayed on each display unit. These consumptions are collected in the management device 24, and practical information and advertisements are selected and distributed according to consumption trends of each user. In the past, notifications about each consumption and charge were only sent separately from the electric power company, gas company, and water utility about once a month. According to the present embodiment, the user can check the consumption and the fee at any time, and can collectively grasp electricity, gas, and water. In addition, the user's awareness of energy saving can be enhanced by comparison of each period based on the history and various practical information.

FIG. 2 shows the configuration of the distributed power generation system 12. The fuel cell system 30 includes a reformer 34 that reacts a hydrocarbon-based fuel such as natural gas or methanol with water vapor generated from tap water to obtain hydrogen, and a reaction between the hydrogen and oxygen to obtain water and a DC voltage. The fuel cell system includes a fuel cell 36, an inverter 38 that converts the voltage into an alternating current, and a control unit 32 that controls the inverter. Whether to use power from the fuel cell system 30, purchase power from the power system 16, or use them in combination is generally determined by the user.

The first switch 40 is inserted between the electric power system 16 and the path 72 of the indoor electric equipment, and is brought into a conductive state when power is purchased from the electric power system 16. The second switch 44 is interposed between the fuel cell system 30 and the path 74 between the indoor electric equipment and is turned on when supplying the electric power from the fuel cell system 30 to the indoor electric equipment. From the gas system 14, the reformer 34
Route 66 and Route 6 for indoor gas equipment respectively
Gas is supplied to the reformer 34 and the indoor water supply equipment from the water supply system 18 through the path 70 and the path 68, respectively.

The consumption detecting section 62 detects the power consumption by the power purchase and the power generation from the paths 72 and 74, detects the gas consumption from the paths 66 and 64, and detects the water consumption by the paths 70 and 6.
8 to detect. Each consumption amount detected by the consumption detection unit 62 is stored in the information storage unit 60, and the transmission processing unit 58
Is transmitted to the management device 24 via the communication unit 46. The information presentation unit 50 causes the display device 48 to display each consumption amount stored in the information storage unit 60. The power, gas, and water consumption amounts may be displayed collectively, or may be displayed in a time-series manner or compared in a timely manner. The information presentation unit 50 may receive practical information and an advertisement, which will be described later, from the management device 24 via the Internet 20 and cause the display device 48 to display the information.

The processing unit 52 including the communication unit 46, the information presenting unit 50, the transmission processing unit 58, and the information storage unit 60 can be realized by hardware such as a microcomputer CPU, a memory, and other LSIs. Typically, the functions are realized by a data processing program or the like, but here, only the functions based on their cooperation are shown by blocks. Therefore, it is understood by those skilled in the art that these functional blocks can be realized by various combinations of hardware and software.

FIG. 3 shows the configuration of the consumption detecting section 62. The consumption detection unit 62 includes a power amount detector 80 and a gas amount detector 8.
2, and a water amount detector 84. The power amount detector 80 is a wattmeter, and measures the power amount in the paths 72 and 74 in FIG. The gas amount detector 82 is a mass flow meter, and measures a gas flow rate in the paths 64 and 66. The water detector 84 is also a mass flow meter, and the path 68,
The water flow at 70 is measured. These wattmeters and mass flow meters have a known configuration provided in a conventional fuel cell system, and measure the power output from the fuel cell system or the gas and clean water supplied to the fuel cell system. Not only for energy consumption but also for the measurement of the total consumption by the user, realizing comprehensive energy management.

FIG. 4 shows the configuration of the information storage unit 60. The information storage unit 60 stores the power consumption 120 and the gas consumption 12
2 and water consumption 124 are stored in time series. For example, accumulation may be performed in units of year, month, day, day of the week, time, and the like. From here, the information presenting unit 50 reads the consumption amount at an arbitrary time and displays it on the display device 48. When the fee is constant, each consumption amount may be converted into a fee and held.

FIG. 5 shows the configuration of the management device 24. This configuration is also realized by a combination of hardware such as a microcomputer and software. Communication unit 9
0 is a distributed power generation system 1 via the Internet 20
2 and also directly with a power company 28, a gas company 26, a water utility 29, an advertising agency 25 and an advertising provider 27. Data transmission / reception with the distributed power generation system 12 is performed, for example, by using TCP / IP (Transmission Control Pro).
This is performed using a connection-type transport layer protocol such as tocol / Internet Protocol).

The consumption confirming unit 92 confirms each consumption amount for each user from each of the plurality of distributed power generation systems 12 and records it in the information storage unit 94. The information storage unit 94 has a function corresponding to the information storage unit 60 in FIG. 2 and holds each consumption trend for each user. User list is User list 9
6 is stored.

The power confirmation unit 102 is a distributed power generation system 1
2 and the power consumption is obtained and recorded in the power consumption trend 108. The gas confirmation unit 104 acquires the gas consumption from the distributed power generation system 12 and records it in the gas consumption trend 110.
The clean water confirmation unit 106 acquires clean water consumption from the distributed power generation system 12 and records it in the clean water consumption trend 112.

The advertisement receiving unit 118 receives an advertisement from the advertisement agency 25 or the advertisement providing company 27 and receives the advertisement.
00 is stored. The selecting unit 98 includes a power consumption trend 108,
Practical information and an advertisement are selected from the practical information holding unit 99 and the advertisement holding unit 100 based on one of the gas consumption trend 110 and the water consumption trend 112. The user management unit 114 classifies the users into a plurality of types based on the power consumption trend 108, the gas consumption trend 110, and the water consumption trend 112 in advance and records them in the user list 96. The selection unit 98 may select practical information or an advertisement. The selected practical information and advertisement are sent to the information presentation unit 11.
6 is displayed on the display device 48 connected to the distributed power generation system 12 of the user. The information presenting unit 116 is configured as shown in FIG.
Has a function corresponding to the information presenting unit 50.

The user management unit 114 may provide preferential treatment for each of electricity, gas, and water charges in order to return the advertising revenue from the present system to the user. In this case, the distributed power generation system 12 or the management device 24 may have a configuration for acquiring the number of times and time when the user has actually viewed the advertisement. Points may be given to the user according to the number of times or the time, and the points may be recorded in the user list 96. Discounts and refunds for each fee are made according to the number of points. To make the selection of the advertisement more suitable for the user's request, the preferences and attributes of each user may be acquired in advance and recorded in the user list 96, and the advertisement may be selected based on the preferences and attributes.

FIG. 6 schematically illustrates the internal configuration of the information storage unit 94. Each consumption trend for each user stored in the information storage unit 94 is an average consumption amount for each time zone regarding electric power, gas, and clean water, and is described in a graph with time on the horizontal axis. . For example, the power consumption trend of the user “003” peaks at “18:00 to 21:00”, and the power consumption trend of the user “052” peaks at “0:00 to 3:00”. These peaks vary from user to user and
Peak times may differ between electric power, gas, and clean water. In addition, there is a difference between the consumption amount during the peak time and the increase / decrease amount of the consumption amount between the peak time and the other times. These may be stored for each season or for weekdays and holidays.

Each consumption trend can be considered as a characteristic of each user, and based on this, each information such as the number of households, a life cycle, and a lifestyle can be estimated. For example, when the total consumption is large, it can be determined that “the number of households is large”, and a specific number of people may be calculated based on statistics. For example, when the daytime consumption is extremely smaller than at night, it may be determined that “they tend to go out during the day”, and when the amount of consumption at midnight is large, it may be determined that the “night-time lifestyle”. For households that tend to have a night-life, information about a snack menu sold at a so-called convenience store may be distributed. For example, if a single household has a specific day of the week that is significantly less than the normal power and gas usage after weekday evening, it is determined that the day of the week is a day for learning, club activities, and the like. Such a user may refrain from distributing information during a time period when the amount of electric power or gas used is small, or may distribute information useful for learning and club activities during another time period.

FIG. 7 shows the internal structure of the user list 96. In the user list 96, types obtained by classifying users are recorded for each user. For example, the user "00
"3" is classified into types of "large number of households" and "high power consumption".

FIG. 8 shows the internal configuration of the practical information holding unit 99. The practical information stored in the practical information storage unit 99 is recorded in such a manner that the user's consumption trend and type conditions are associated with the practical information. As a result, for a user who satisfies the condition that “the amount of electricity at midnight is large”, practical information such as “It is advantageous to use the midnight discount system” is selected.

FIG. 9 shows the internal configuration of the advertisement holding unit 100. The advertisement stored in the advertisement holding unit 100 is recorded in such a manner that the advertisement is associated with the user's consumption trends and type conditions. Thus, for example, for a user who satisfies the conditions of “one household” and “night”, “24
"Time convenience caching" advertisement is selected.

FIG. 10 illustrates a display screen 150 of the display device 48 connected to the energy management system 10.
The display screen 150 has a consumption display area 152, a practical information display area 154, and an advertisement display area 156. The consumption display area 152 displays at least one of power, gas, and water consumption. The consumption at any time can be displayed through the operation of the user, and a comparison with another month may be displayed. Electricity rates, gas rates, and water rates may be displayed, or comments on consumption and rates may be added.

In the practical information display area 154, “When the air conditioner is in use, selected based on the consumption trend of the user,
It is effective to close the curtain. "Is displayed. In the advertisement display area 156, an advertisement such as “Car B” selected based on the consumption trend of the user is displayed. Thus, the user can receive useful information distribution.

The present invention has been described based on the embodiments. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications can be made to the combination of each component and each processing process, and that such modifications are also within the scope of the present invention. . Hereinafter, such an example will be described.

The user management unit 114 in the management device 24
An electricity rate, a gas rate, or a water rate may be calculated and managed, or a configuration for processing a charge for these rates may be provided.

One of the electric power company 28, the gas company 26, the water company 29, the advertising agency 25, and the advertising providing company 27 and the management company 22 are realized by substantially the same entity, and a series of processes are integrated. You may. In that case,
The system may be operated by constructing a Web server or other host inside each company.

The electric power company 28, the gas company 26, the water company 29, the advertising agency 25, the advertisement providing company 27 and the management company 22 do not necessarily have to be dedicated lines. Absent. The design also depends on the degree of security required for communication between the two.

The screen example shown in FIG. 10 mainly assumes a dedicated display device 48. When such information is displayed on the television screen, it may be displayed in the form of subtitles such as breaking news at the top or bottom of a normal screen. In addition, as a display format that is particularly emphasized, a video display area may be reduced to create a margin around the image display area, and subtitles may be displayed in the margin. This subtitle may be displayed with a contrast like white characters on a black background.

[0045]

According to the present invention, energy information can be effectively used.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of an energy management system according to an embodiment.

FIG. 2 is a configuration diagram of a distributed power generation system according to an embodiment.

FIG. 3 is a configuration diagram of a consumption detection unit in the distributed power generation system.

FIG. 4 is a configuration diagram of an information storage unit in the distributed power generation system.

FIG. 5 is a configuration diagram of a management device in a management company.

FIG. 6 is an internal configuration diagram of an information storage unit in the management device.

FIG. 7 is an internal configuration diagram of a user list in the management device.

FIG. 8 is an internal configuration diagram of a practical information holding unit in the management device.

FIG. 9 is an internal configuration diagram of an advertisement holding unit in the management device.

FIG. 10 is a diagram illustrating a display screen of a display device connected to the energy management system.

[Explanation of symbols]

10 energy management system, 12 distributed power generation system, 20 Internet, 24 management device,
Reference Signs List 30 fuel cell system, 36 fuel cell, 46 communication unit, 48 display device, 50 information presentation unit, 60
Information storage unit, 90 communication unit, 94 information storage unit,
99 practical information, 100 advertisements, 108 power consumption trends, 110 gas consumption trends, 112 clean water consumption trends, 116 information presentation section, 120 power consumption, 1
22 Gas consumption, 124 Water consumption.

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H02J 13/00 301 H02J 13/00 301A // H01M 8/10 H01M 8/10 (72) Inventor Katsuya Oda 2-5-5 Keihanhondori, Moriguchi-shi, Osaka Sanyo Electric Co., Ltd. (72) Inventor Kotoku Akiyama 2-5-5 Keihanhondori, Moriguchi-shi, Osaka Sanyo Electric Co., Ltd. F-term (reference) 5G064 AA04 AA07 AC09 BA02 CB08 DA02 DA03 DA05 5G066 AA02 AE05 AE07 HB07 KA12 5H026 AA06 5H027 AA06 BA01 DD00 KK00 KK51

Claims (11)

[Claims] 1. A decentralized power generation system having a power generation device, a consumption detection unit for detecting consumption of power and gas used by a user of the power generation system, and a unitary detection of the power and gas consumption. And an information presenting unit for displaying the information on a display device. 2. In a distributed power generation system having a power generation device, a consumption detection unit that detects a power consumption amount used by a user of the power generation system, and records the power consumption amount in time series. A distributed power generation system, comprising: an information storage unit; and an information presentation unit that reads a history of the power consumption from the information storage unit and displays the history on a display device. 3. A distributed power generation system having a power generation device that uses gas for power generation, a consumption detection unit that detects a consumption amount of gas used by a user of the power generation system, and a consumption of the gas. A distributed power generation system, comprising: an information storage unit that records an amount of gas in time series; and an information presentation unit that reads a history of the gas consumption from the information storage unit and displays the history on a display device. 4. The distributed power generation system according to claim 1, wherein the power generation device includes a fuel cell. 5. The information presenting unit displays the consumption amount on a display device that is electronically connected while maintaining a physically separated state from the power generation system. 5. The distributed power generation system according to any one of items 1 to 4. 6. A management device connected to a distributed power generation system having a power generation device via a network and capable of remotely confirming a power consumption amount used by a user of the distributed power generation system, wherein the management device includes: Transmitting and receiving practical information including information related to the power consumption amount to a user of the distributed power generation system via a display device connected to the distributed power generation system. . 7. A management system which is connected via a network to a distributed power generation system having a power generation device that uses gas for power generation, and which can remotely confirm the consumption of gas used by a user of the distributed power generation system. The management device transmits and receives practical information including information related to the gas consumption to and from a user of the distributed power generation system via a display device connected to the distributed power generation system. An energy management system, characterized in that: 8. The management device manages a power or gas consumption trend of the user based on the consumption amount, and causes the display device to display practical information according to the consumption trend. The energy management system according to claim 6. 9. The management device classifies users according to the consumption trend, selects an advertisement corresponding to the classification, and displays the advertisement on the display device as the practical information. Item 9. An energy management system according to Item 8. 10. A distributed power generation system having a power generation device, connected via a network, for remotely managing, via the network, consumption of at least a part of resources used by a user of the distributed power generation system; An energy management system characterized in that information contributing to saving of fees is selected according to the consumption and displayed on the screen of the distributed power generation system. 11. Detecting consumption trends relating to at least a part of resources used by a user of a distributed power generation system having a power generation device, and classifying the users of the distributed generation system into a plurality of types according to the consumption trends. Information distribution method that distributes advertisements according to their classification.