JP3233774U - Green power generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a green power generation device which can be utilized _{for CO 2} reduction efforts toward the suppression of global warming and the realization of a low-carbon / decarbonized society.
A green power generation device is connected to junction boxes 15 and 16 into which electric power generated by a solar power generation device 10 and / and a wind power generation device 30 is input via junction boxes 15 and 16, and is connected to the sun. A storage battery 50 that stores the power generated by the optical power generation device 10 and / and the wind power generation device 30, a power conditioner 52 that converts the DC power stored in the storage battery 50 into AC power that can be used at home, and a power conditioner. Electricity is supplied to each room of the house from a green power meter 53 connected to 52 and measuring the total power generation amount of the solar power generation device 10 and / and the wind power generation device 30, and a distribution board 58 connected to the green power meter 53. It has a branch circuit for sending power, and also has a power meter 60 for selling and purchasing power that sells power from the distribution board 58 to an external power transmission line network.
[Selection diagram] Fig. 2

Description

This idea is related _{to green power generation equipment that generates electricity from an energy source that does not emit CO 2,} and can be used _{for CO 2} reduction efforts, especially for the suppression of global warming and the realization of a low-carbon and decarbonized society. Regarding power generation equipment.

In recent years, there have been active movements to reduce the displacement of gases that pollute the atmosphere as a measure against global warming. For example, the Kyoto Protocol has come into effect. Therefore, the construction of a new thermal power plant that uses natural gas as fuel for power supply is being considered. However, while pipelines are common in Europe and the United States for supplying natural gas, in Japan they are transported as liquefied natural gas by a dedicated tanker. The price of this liquefied natural gas is generally contracted with the price of crude oil.
In Europe and the United States, due to the impact of the shale gas revolution, the price of natural gas transported by pipeline has plummeted, falling below the profitable price of shale gas. However, the price of liquefied natural gas has remained significantly different from the price of natural gas transported by pipeline. Therefore, instead of energy based on the combustion of fossil fuels and the like, clean energy, in particular, the use of electric power energy created from solar power generation and wind power generation using natural energy has become widespread. Power generated by energy sources that do not emit _{CO 2} , such as solar power, wind power, hydropower, and geothermal power, is called green power generation.

As such a green power generation device, for example, in Patent Document 1 according to the proposal of the present applicant, solar power generation suitable for installation in a vacant lot existing in an urban area near the city due to a decrease in the urban resident population. A power generation device that combines wind power generation and wind power generation is disclosed.

Further, Non-Patent Document 1 proposes a household distributed energy system composed of a fuel cell, a photovoltaic power generation, and a storage battery from the viewpoint of a consumer.

Utility model registration No. 3192427

Yoshiro Shibata, "Economic Analysis of Household Distributed Energy Systems Consisting of Fuel Cells, Photovoltaic Power Generation, and Storage Batteries", published by The Institute of Energy Economics, Japan, Energy Economy September 2012

_{The present invention solves the above-mentioned problems and can be utilized for CO 2} reduction efforts toward the suppression of global warming and the realization of a low-carbon / decarbonized society, such as solar power, wind power, hydraulic power, and geothermal power. It is an object of the present invention to provide a green power generation device generated by an energy source that does not emit CO _2.

The green power generation device of the present invention that achieves the above object is, for example, as shown in FIGS. 1 and 2, a solar power generation device 10, a wind power generation device 30, junction boxes (15, 16), a storage battery 50, and a power conditioner 52. , A green power generation device that combines a distribution board 58 and a power meter 60 for selling / purchasing power, and a connection to which power generated by the solar power generation device 10 and / and the wind power generation device 30 is input. The boxes (15, 16), the storage battery 50 connected via the junction box, the storage battery 50 for storing the electric power generated by the solar power generation device 10 and / and the wind power generation device 30, and the storage battery 50. A power conditioner 52 that converts stored DC power into AC power that can be used at home, and a total power generation that is connected to the power conditioner 52 and measures the total power generation amount of the solar power generation device 10 and / and the wind power generation device 30. A distribution board 58 connected to a power meter 63 and a total power generation meter 63, which has a branch circuit for transmitting electricity from the distribution board 58 to each room of the household, and is external from the distribution board 58. It is equipped with a power meter 60 for selling / purchasing power to sell power to the power transmission line network of the above.

In the green power generation device of the present invention, for example, as shown in FIGS. 3 to 5, the photovoltaic power generation device 10 is preferably a composite power generation device in which the photovoltaic power generation device 10 and the wind power generation device 30 are combined. , A plurality of photovoltaic power generation panels 12 that photoelectrically convert sunlight, and a stand 20 that holds the light receiving surface of the photovoltaic power generation panel in the direction in which sunlight is incident, and at least one of the photovoltaic power generation panels 12. Is preferably attached to the gantry 20 with a gap for air circulation provided between the solar power generation panel adjacent to the solar power generation panel.

In the green power generation device of the present invention, for example, as shown in FIGS. 3 to 5, preferably, the wind power generation device 30 is a vertical type in which the rotation axis 34 of the wind turbine 32 is located perpendicular to the ground, and the sun. A wind turbine 32 having a plurality of wind receiving members rotated by the wind passing through the air flow gap 14 of the optical power generation panel 12 and a generator 36 for converting the rotational energy of the wind turbine 32 into electrical energy to generate electricity are provided. It is good.
It is characterized by.

In the green power generation device of the present invention, preferably, the storage battery is a first storage battery that supplies the required power of the consumer, and has a storage capacity of one hour or more of the required power of the consumer. Having a storage battery, a second storage battery connected to the first storage battery and the external power transmission line network side, and having a storage capacity of one day or more of the required power of the consumer. good. Preferably, the second storage battery is a storage battery for an electric vehicle.
In the green power generator of the present invention, preferably, the total power generation meter 63 is a photovoltaic power generation and a wind power generation for dealing with at least one of a green power certificate transaction, a J credit system, or a non-fossil certificate. It is good to have a total power generation meter.

If a green power meter or a total power generation meter is further provided in the green power generation device according to the present invention, the environmental value of power generated by the solar power generation system or the wind power generation device can be bought and sold separately from the surplus power purchase system of the power company. It is possible to deal with a system called "green electricity certificate transaction".

It is a main part block diagram which shows one preferable embodiment of the green power generation apparatus for a dwelling unit which concerns on this invention. It is a main part functional block diagram which shows one preferable embodiment of the green power generation apparatus for a dwelling unit which concerns on this invention. It is a structural perspective view which shows one preferable embodiment of the composite type power generation device used for the green power generation device which concerns on this invention. It is a side view of the composite power generation apparatus shown in FIG. 3, and in particular, the wind power generation apparatus 30 is shown in detail. In the rear view of the composite power generation apparatus shown in FIG. 3, the brace portion is particularly shown in detail. It is a block diagram which shows various shapes of the wind turbine used for a wind power generation apparatus.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a configuration diagram of a main part showing a preferred embodiment of a green power generation device for a dwelling unit according to the present invention. In the figure, the green power generation device for a dwelling unit according to the present invention includes a dwelling unit 70, a solar power generation device, a wind power generation device, a storage battery (stationary type) 50, an electric vehicle 54, an electric vehicle charging / discharging facility 56 (V2H equipment), and the like. It is equipped with a distribution board 58, a power meter 60 for selling / purchasing power, and the like. FIG. 2 is a main function block diagram showing a preferred embodiment of the green power generation device for a dwelling unit according to the present invention. In FIG. 2, in addition to the matters specifying the invention of FIG. 1, what is specified includes a green power meter 53, a solar / wind breaker 57, an electric device 72, and a power monitor 74.

The photovoltaic power generation device includes a photovoltaic power generation panel 12 and a junction box 15.
The solar power generation panel 12 is a combination of solar power generation cells of about 10 cm square, and the unit of one panel is called a solar cell module. A circuit in which solar cell modules are connected in series is called a solar cell string, and in order to increase the supplied voltage, it is better to use a string in which as many solar cell modules are connected as possible. A combination of solar cell strings in parallel is called a solar cell array.
The junction box 15 is a device for collecting electric energy (DC) generated by the solar cell module. A solar cell string in which the solar cell modules are connected in series is used as one line, and each line is passed through a backflow prevention diode or the like. Collect in one junction box. In the junction box, devices such as a DC switch for input, a backflow prevention element, a terminal block for output, a switch or circuit breaker, and a lightning protection element are generally included. The switch has an ON / OFF switch like a breaker, and it is a mechanism that can check the flow of electricity and maintain it. It also has a built-in lightning protection element to prevent the equipment from being damaged by a lightning strike. The junction box may be integrated with the power conditioner.

The wind power generator includes a wind turbine, a generator, a junction box 16, and a watt-hour meter (for total wind power generation) 42. The wind power generator will be described in detail later.
The junction box 16 is provided between the wind power generator and the storage battery. The junction box is not just a box (terminal block), but is equipped with a current meter for monitoring the amount of power generated, a brake switch for applying an electromagnetic brake to the wind generator, and a fuse for safety. The electromagnetic brake can be applied by short-circuiting the output from the wind power generator (separated from the storage battery side). This principle corresponds to putting an infinite load on the generator.

The storage battery (stationary type) 50 stores electricity and is connected to the distribution board 58 via the power conditioner 52. The power conditioner 52 is called a PCS (Power Conditioning System), which converts the DC power stored in the storage battery into AC power that can be used at home, and also generates DC power generated by a solar power generation device or a wind power generation device. Alternatively, the AC power is converted into DC power used for charging the storage battery via the distribution board 58. The storage capacity of the storage battery (stationary type) 50 should be sufficient to cover the power consumption of the dwelling unit, which is a consumer, for about 5 days. In this case, the storage capacity of the storage battery of the electric vehicle 54 may be added to the storage capacity of the storage battery (stationary type) 50.

The electric vehicle 54 is equipped with a storage battery and travels on the road by charging, and is connected to the storage battery (stationary type) 50 via the electric vehicle charging / discharging facility 56 (V2H device). The electric vehicle 54 is provided with an electric vehicle charging / discharging facility 56 so that the electric vehicle 54 can also be used as a movable storage battery. The electric vehicle charging / discharging facility 56 supplies DC power required for charging to the electric vehicle 54 by supplying power from the storage battery (stationary type) 50, and also supplies the electric power stored in the electric vehicle 54 to the storage battery (stationary type). It has a charge / discharge function of supplying the distribution board 58 with the same voltage as the commercial AC power via the 50 and the power conditioner 52.

The green electricity meter 53 is an electricity meter for dealing with a system called "green electricity certificate transaction" that buys and sells the environmental value of electricity by a solar power generation system, in addition to the surplus electricity purchase system of the electric power company. It measures the total amount of power generated by a power generation system, and is also called a total power generation meter.
A green power certificate is a certificate of the "environmental value" of electricity generated by renewable energy, and a certificate issuer issues a green power certificate with the approval of a third-party approval body. _{In addition, if the government certifies the CO 2} emission reduction value based on the amount of power generated and the amount of heat generated on the green power certificate, it can be used for greenhouse gas emission calculation, reporting, and publication systems based on the Warmth Law. The system that has been adopted is the "Green Energy CO ₂ Reduction Equivalent Amount Certification System".

The solar / wind breaker 57 is a breaker provided in a solar power generation device or a wind power generation device, and has three types of breakers: an ampere breaker, an earth-leakage circuit breaker, and a molded case circuit breaker, each of which has a different mechanism. The ampere breaker is a mechanism that automatically shuts off electricity when more power than expected flows at one time, preventing breakdowns and accidents due to overcurrent. An earth-leakage circuit breaker is a breaker for preventing electric leakage that flows to a part where electric power should not flow. When an electric leakage is detected, the breaker is turned off and the electricity of the entire house is stopped. The role of the molded case circuit breaker is to protect the circuit that sends electricity from being overloaded.

The distribution board 58 is a board (board) in which two or more switches are assembled and attached. There are service breakers, earth leakage breakers, safety breakers, etc. in the distribution board, which play a role in checking the electric capacity and ensuring the safety of indoor wiring. The service breaker is a breaker that determines the contracted capacity, and the electricity is automatically stopped when more electricity than the contract is applied. The earth leakage breaker, also called an earth leakage breaker, quickly detects the leakage of wiring and electrical appliances in the building and automatically shuts off the electricity. It usually operates with an electric leakage of about 15 to 30 mA. A safety breaker is also called a circuit breaker for wiring, and when a short circuit occurs due to a failure of the electrical equipment or cord attached to each branch circuit that sends electricity from the distribution board to each room, or when it is overused and overcurrent flows. In case the electricity is cut off automatically.

The electricity sales / purchase power meter 60 can be divided into two power meters, a power purchase power meter (supply meter) and a power sale power meter (reverse power flow meter). The distribution board 58 and the commercial power grid are separated from each other. The power meter 60 for selling / purchasing power sells power to the commercial power side when the power generated by the solar power generation device, the wind power generation device, and the fuel cell 70 on the dwelling unit side exceeds the private demand of the dwelling unit 70. When there is a shortage, the amount of power purchased from the commercial power side is measured and integrated.
The dwelling unit 70 is provided with an indoor lamp line. The dwelling unit 70 is provided with electrical equipment 72 such as lighting / home appliances, an air conditioner, an IH cooker, and a floor heater, and is supplied with power from an indoor power line. The power monitor 74 manages and measures the current consumption of the electric device 72.

In the device configured in this way, the electric power generated by the solar power generation device and the wind power generation device is supplied for private power consumption in the dwelling unit via the distribution board 58, and the storage battery (stationary type) 50 is used. It is used for charging, and if there is surplus power, it is sold via the power selling / purchasing power meter 60. If the power supply generated by the solar power generation device or the wind power generation device is insufficient for the private power consumption in the dwelling unit, the power supply from the storage battery (stationary type) 50 and the purchase power from the commercial power are used together.
In addition, the green power generation device is a combination of a solar power generation device that generates in-house power generation, a wind power generation device, a storage battery (stationary type), and an electric vehicle with an appropriate power capacity, depending on the state of power consumption and commercial supply power in each dwelling unit. For example, a solar power generation device, a wind power generation device, and a storage battery (stationary type) may be combined, and the fuel cell and the electric vehicle may be used for future expansion and may have a system configuration that is not provided at this time.

A lightning arrester may be installed in an area with a high probability of lightning. The lightning arrester, also called an arrester, is installed to suppress the abnormal voltage that enters the premises during a lightning strike and the abnormal voltage of the switching surge that occurs when the load is opened or closed. It is installed near the entrance to discharge abnormal voltage caused by lightning strikes and circuit opening and closing to the ground, and has the role of protecting the insulation of green power generation equipment.
Lightning strikes generate shocking overvoltages and overcurrents that have a significant negative impact on green power generators. The lightning arrester has a protective function of suppressing the overvoltage accompanied by the impact generated by the lightning surge, protecting the insulation of the green power generation device, and quickly shutting off the follow-on flow. By bypassing the lightning surge to the ground with a lightning protection device, an abnormal voltage is not applied to the green power generation device, and deterioration of insulation can be suppressed.

FIG. 3 is a configuration perspective view showing an embodiment of a composite power generation device in which a solar power generation panel and a wind power generation device are combined, which is suitable for use in the green power generation device according to the present invention. FIG. 4 is a side view of the composite power generation device shown in FIG. 3, and FIG. 5 is a rear view of the composite power generation device shown in FIG. As a general rule, this composite power generation device includes a gantry 20 erected on the foundations 25a and 25b provided on the ground or the roof of a building, and a photovoltaic power generation panel 12 installed on the roof portion of the gantry 20. The wind power generator 30 installed at the bottom of the photovoltaic power generation panel 12 and the power regulator 40 installed on the foundation 25c at the bottom of the gantry 20 are provided.

[Configuration of photovoltaic power generation equipment]
As shown in FIGS. 3 to 5, the photovoltaic power generation device 10 is appropriately combined with a rectangular photovoltaic power generation panel 12 having a standard output, and is provided with a gap in consideration of power generation of the wind power generation device. be. The photovoltaic power generation panel 12 has a power generation capacity of about 150 W to 300 W per panel, for example, when the cell conversion efficiency is 10% to 20% and the length and width are about 1.0 mx 1.6 m. In relation to mounting the photovoltaic power generation panel 12 on the gantry 20, for example, in the upper stage, 2 x 4 panels are arranged vertically x horizontally as a set, and 0.2 to 0 for a set of adjacent photovoltaic power generation panels 12. Provide a gap of .8 m. For the lower row, 1 x 4 sheets are arranged as a set in the vertical x horizontal direction. The ventilation port 14 between the panels may have a gap of about 1.0 m, which is about the size of one panel of the photovoltaic power generation panel 12.

For example, among the upper stages of the photovoltaic power generation panel 12, the panels 12a1, 12a2, 12a3, and 12a4 located at the highest level are assembled in this order. Among the upper stages of the photovoltaic power generation panel 12, panels 12b1, 12b2, 12b3, and 12b4 are assembled in this order on the ventilation port 14 side between the panels. Panels 12c1, 12c2, 12c3, and 12c4 are assembled in this order on the lower stage of the photovoltaic power generation panel 12.
Regarding the number of installed solar power generation panels 12 in the width direction, the case where four horizontal panels are arranged as a set is shown here, but the number may be three or five or more as appropriate.

The inter-panel ventilation port 14 acts as a gap for air flow. In areas where the wind speed is often moderate at about 3 to 5 m / sec, the gap height V for air circulation is preferably between 0.2 and 0.4 m. As shown in FIG. 3, the height V of the opening in the vertical direction is related to the dimension H of the opening provided in the photovoltaic power generation panel 12, when the inclination angle of the photovoltaic power generation panel 12 is 15 degrees. Corresponds to about four times that, and when the inclination angle of the photovoltaic power generation panel 12 is 30 degrees, it corresponds to about twice that. In areas where the wind speed is often relatively strong, such as about 10 to 15 m / sec, the gap for air circulation is preferably between 0.4 and 0.8 m. The gap height V for air circulation is installed so that air can freely enter from the light receiving surface side of the photovoltaic power generation panel 12 toward the back side thereof, and a typhoon or a seasonal wind is installed on the back surface side of the photovoltaic power generation panel 12. When a strong wind or a typhoon blows up due to such factors, the possibility that the photovoltaic power generation panel 12 is lifted upward and damaged is reduced.

Further, the solar power generation device 10 may be provided with a plurality of sets of the solar power generation panels 12 as shown in FIG. 3 at appropriate intervals in the left-right front-rear direction. The gaps between the adjacent sets of photovoltaic power generation panels 12 should be appropriately spaced so that maintenance work can be easily performed. For example, the width of one worker is 0.8 m to 1.5 m for two workers. The space is good.
Here, for installation in Japan, for example, it is preferable to determine the tilt angle of the photovoltaic power generation panel 12 from the horizontal in consideration of the position of the sun in summer and winter, and the tilt angle is set lower toward the south. .. For example, in Sapporo City, Hokkaido, the inclination angle from the horizontal is about 35 degrees, in Tokyo and Osaka Prefecture near 35 degrees north latitude, about 30 degrees, and in Naha City and Ogasawara Islands near 26 degrees north latitude, about 20 degrees. It is good to provide it so that it becomes. When installed in a snowy area, the inclination angle of the photovoltaic power generation panel 12 is preferably set to a large angle of about 30 degrees so that snow can easily fall from the panel.
Further, the direction in which the gantry 20 faces may be determined so that the photovoltaic power generation panel 12 faces the south. It is said that if the photovoltaic power generation panel 12 swings 5 degrees to the left or right from the direction facing south, the amount of power generation decreases by about 10%, and if it swings 10 degrees to the left or right, the amount of power generation decreases by about 20%.

[Structure of pedestal]
The gantry 20 is preferably made of a metal structural material such as a steel frame, an iron pipe, or an extruded aluminum material. For example, a steel frame or an iron pipe is preferably galvanized to improve weather resistance. The gantry 20 may have a structure that simplifies the wooden frame construction method. The height of the gantry 20 is appropriately determined in relation to the installation location of the photovoltaic power generation panel 12 and the wind power generation device 30, but it is preferable that the height of the gantry 20 is about 1 m at the lowest location of the photovoltaic power generation panel 12. For example, when the wind power generation device 30 is installed under the solar power generation panel 12, the height of the gantry 20 needs to be higher than the height of the wind power generation device 30. Further, when the wind power generation device 30 is installed adjacent to the solar power generation panel 12, it is preferable that the height of the wind power generation device 30 is higher than the height of the wind turbine so as not to hinder the ventilation of the wind power generation device 30.
The place where the composite power generation device is installed is not limited to the gantry 20 shown in FIG. 3, and for example, sunshine can be secured to some extent on the roof of a building, under an elevated railway or an elevated highway. It can also be installed in an appropriate building or structure where sunshine and ventilation can be secured to some extent.

Next, the detailed structure of the gantry 20 will be described. The gantry 20 has four corners, a pillar portion 22, a joist portion 24 located on the foundation side of the pillar portion 22, a girder / rafter portion 26 located on the roof side of the pillar portion 22, and a brace portion for reinforcing the framework structure. It has 28. The pillar portion 22 is composed of a short front pillar portion 22a on the front side and a tall rear pillar portion 22b on the back side. Assuming that the inclination angle of the photovoltaic power generation panel 12 is 15 °, for example, the height of the front pillar portion 22a is 1.0 m, the height of the rear pillar portion 22b is 2.0 m, and the height of the front pillar portion 22a and the rear pillar portion 22b. The interval between the two is about 3 to 4 m.

The joist portion 24 includes a front joist portion 24a on the front side, a rear joist portion 24b on the back side, a right side joist portion 24c on the left and right side surfaces, a left side joist portion 24d, and an intermediate joist portion for fixing the wind power generator 30. It is composed of 24e. The dimension of the front joist portion 24a in the longitudinal direction is, for example, about 5 to 6 m. Further, the longitudinal dimension of the rear joist portion 24b is the same as the longitudinal dimension of the front joist portion 24a, for example. The front root thick portion 24a and the rear root thick portion 24b are supported by foundations 25a and 25b having a height of about 0.2 m, respectively, in a state of floating from the ground. The distance between the front joist portion 24a and the rear joist portion 24b is, for example, about 2.5 to 3.5 m. For the foundations 25a and 25b, for example, a general-purpose product made of concrete having a quadrangular pyramid shape or a truncated cone shape may be used.
The right side joist portion 24c and the left side joist portion 24d form a frame structure by connecting the front joist portion 24a and the base side end portion of the rear joist portion 24b, and both ends thereof are formed on the foundations 25a and 25b. It is fixed.

The intermediate joist portion 24e is provided at the installation position of the wind power generator 30, and both ends of the intermediate joist portion 24e are fixed to the corresponding positions of the right side joist portion 24c and the left side joist portion 24d, respectively, with fixing brackets. .. The width of the intermediate joist portion 24e is preferably slightly wider than that of the flange portion 39 because the flange portion 39 of the wind power generation device 30 is attached, and the width is, for example, about 0.1 m to 0.3 m. A foundation 23 for supporting the weight of the wind power generation device 30 may be provided in the middle of the intermediate joist portion 24e. For the foundation 23, for example, a general-purpose product having a quadrangular pyramid shape or a truncated cone shape made of concrete may be used.

The girder / rafter portion 26 is a structural material that connects the front pillar portion 22a and the rear pillar portion 22b on the roof side, and is made of, for example, a steel frame or an iron pipe, and supports the solar power generation panel 12 at a predetermined inclination angle. The girder / rafter portion 26 may be any as long as it is integrated with the frame material provided in the photovoltaic power generation panel 12 and maintains the strength. For example, the inter-panel ventilation port 14 may be held by the frame structure.
The lower girder 26a is a structural member that connects the top ends of the left and right front pillar portions 22a. The upper girder 26b corresponds to a purlin and is a structural member connecting the top ends of the left and right rear pillars 22b. The rafter 26c is a structural member that connects the left and right front pillar portions 22a and the top end portions of the rear pillar portions 22b. In FIG. 5, each rafter 261 to 268 provided in a set of two for each of the photovoltaic power generation panels 12a1, 12a2, 12a3, 12a4 is shown between the left and right rafters 26c. Each of the solar power generation panels 12 is fixed to the roof side of the gantry 20 by each of the rafters 261 to 268, and has a structure that can withstand strong winds and snow.

The brace 28 is a front brace 28a1 and 28a2 made of two brace steel bars on the front side and a right side brace 28b1 and 28b2 made of two brace steel bars on the right side. And the back brace parts 28c1 to 28c2 made of two brace steel bars on the back side, the left side brace parts 28d1 and 28d2 made of two brace steel bars on the left side side, and the roof. It is composed of roof brace portions 28e1 to 28e2 made of two brace steel bars on the side. The anterior brace portions 28a1 and 28a2 are shown in FIG. The right side brace portions 28b1 and 28b2 are shown in FIGS. 3 and 4. The back brace portions 28c1 to 28c2 and the roof brace portions 28e1 to 28e2 are shown in FIG. The left side brace portions 28d1 and 28d2 are shown in FIG. The brace 28 may be galvanized steel rod or painted to prevent iron corrosion.

[Structure of wind power generator]
The wind power generator 30 is a vertical type in which the rotation shaft 34 of the wind turbine 32 is located perpendicular to the ground, and is a plurality of wind receiving members that are rotated by the wind that has passed through the air flow gap of the solar power generation panel 12. 32, a generator 36 that converts the rotational energy generated by the wind turbine 32 into electrical energy to generate electric energy, a fixed shaft portion 38 provided under the generator 36, and an end portion of the fixed shaft portion 38. The provided flange portion 39 is provided.
The installation height of the wind turbine 32 is preferably set to a height suitable for receiving the wind that has passed through the air circulation gap V of the solar power generation panel 12. The flange portion 39 of the wind power generator 30 is fixed to and supported by the intermediate joist portion 24e. The wind power generation device 30 may be provided for each of the solar power generation panels 12. For example, in the present embodiment, four units 301, 302, 303, and 304 are laterally arranged according to the inter-panel ventilation port 14. There are four units in the.

Here, the wind turbine may be one that is generally used as a vertical wind turbine. FIG. 6 is a configuration diagram showing various shapes of a wind turbine used in a wind power generator. FIG. 6A is a paddle type, B is a Savonius type, C is a gyromill type, and D is a Darius type. Shown. These wind turbine shapes are suitable for installation in urban areas, are safe and have low noise. In addition, the paddle type has high startability and is suitable for installation in urban areas. The Darius type uses lift and has a low torque coefficient, but a high power coefficient and a high peripheral speed ratio, making it suitable for wind power generation. Here, the peripheral speed ratio means the ratio between the tip speed of the blades of the wind turbine and the speed of the wind hitting the wind turbine.
On the other hand, the Savonius type has a low power coefficient but a high torque coefficient, so it can be started even in a weak wind and is suitable for driving a pump.

Further, as other shapes of the wind turbine used in the wind power generation device, a cross flow type, a straight airfoil type, and an S type rotor type are known. These shapes are higher in equipment price and inferior in terms of power generation efficiency as compared with those shown in FIG. 6, but the present invention excludes other types of wind turbine shapes. is not it.

The amount of power generated by a vertical wind turbine is determined by the following factors.
(1) The amount of energy obtained from the wind is proportional to the wind receiving area of the wind turbine. Therefore, since the wind receiving area of the vertical wind turbine is proportional to the rotor diameter, when the rotor diameter of the wind turbine is doubled, the power of the obtained wind is also doubled. In this respect, it differs from a horizontal windmill in which the receiving area is proportional to the square of the rotor diameter.
(2) The amount of energy obtained from the wind is proportional to the air density. The air density changes depending on the air pressure at the site and the amount of water in the air. Normally, the density of air on flat ground is approximately 1.2 [kg / m ³ ].
(3) The amount of energy obtained from the wind is proportional to the cube of the wind speed. That is, if the wind speed is doubled, the amount of energy obtained from the wind is eight times, and if the wind speed is tripled, the amount of energy obtained from the wind is 27 times. Therefore, the amount of energy obtained from the wind fluctuates greatly depending on the wind speed, that is, the output of the wind power generator also fluctuates greatly accordingly.

[Power regulator configuration]
The power regulator 40 converts the voltage or AC frequency suitable for supplying power to a commercial power system for selling power, and is also called a power conditioner. By incorporating an appropriate secondary battery in the power regulator 40, the output voltage of the photovoltaic power generation panel 12 and the wind power generation device 30 can be adjusted to a voltage suitable for charging, and charging has a function of preventing overcharging. It is advisable to incorporate a circuit as well.
The power supply destination of the charged secondary battery may be a device suitable for the current capacity of the secondary battery of the power regulator 40. These devices include, for example, street lights, electric lighting for fish, work lighting for house cultivation, electric lighting for vegetables, crow damage prevention sensors for fruit tree farmers, anti-theft sensors, road indicator lights and safety lights. It is ideal for supplying power to non-electrified areas. When the load requires an AC power supply, a DC-AC conversion circuit is connected to the secondary battery.
Further, instead of installing the secondary battery of the power regulator 40, a storage battery (stationary type) 50 or an electric vehicle 54 may be used.

[Operation of green power generator]
According to the device configured in this way, power is generated by the solar power generation panel 12 in an environment where daytime sunlight can be received. Further, when the wind has an appropriate wind speed, power is generated by the wind power generator 30. In the wind power generator 30, it is important to select the installation location so that the wind turbine does not rotate at all or is not profitable even though it is installed.

The following points will be examined as the construction conditions for the wind power generation device 30.
(1) The wind is strong (annual average wind speed of 6 m / s or more). Since the amount of energy obtained from the wind is proportional to the cube of the wind speed, it is possible to obtain more energy if the wind is strong. Even when the wind speed is, for example, 25 m / s or more, the wind power generator targeted by the present invention has a small output, so that it is not necessary to stop the rotation of the wind turbine, and there is little possibility that a large load is applied to the wind turbine.
(2) The transmission line is nearby. When a plurality of wind power generation devices 30 are installed, it may be necessary to connect them to the transmission line of the electric power company in order to transmit the electricity produced by the wind power generation device 30. When laying a new transmission line between the wind turbine and the transmission line, the farther the distance is, the more expensive it is and the more profitable it is.

Since the combined power generation device is a power generation method using solar and wind power as energy supply sources, there is an advantage that biased power generation characteristics can be averaged by using generators having different characteristics in combination. For example, photovoltaic power generation is active from spring to autumn when a large amount of solar radiation is obtained, and wind power generation is active during the winter when the amount of solar radiation tends to be insufficient and the average wind speed is high. can. In addition, in cases where the amount of power generated by solar power generation alone is barely enough and the storage battery tends to be discharged, by adding a wind power generator, large power generation by wind power generation can be obtained irregularly, so the storage battery is full. It can be recovered to a charged state and can contribute to extending the life of the storage battery.
Further, in the composite power generation device, when the wind power generation device 30 is installed under the solar power generation panel 12, rain and snow are received by the solar power generation panel 12, so that the wind power generation device 30 is affected by rain and snow. The number of cases is small, and the life of the device can be extended. Further, the photovoltaic power generation panel 12 is preferably arranged so as to be less affected by the snowfall even if there is a snowfall from an adjacent structure so that the solar power generation panel 12 is less affected by the snowfall.

According to the composite power generation device used in the present invention, it is possible to generate power not only in the daytime but also at night by using both photovoltaic power generation and wind power generation, and a ventilation section is provided in the photovoltaic power generation panel. It also enables wind power generation, and is particularly suitable for installation in places with relatively high land prices, such as urban areas near cities.

In the above embodiment, the case where the solar power generation and the wind power generation are installed in the house is shown, but the present invention is not limited to this, and the solar power generation or the solar power generation is performed on a site different from the house. At least one of the wind turbines may be installed.
Further, in the above-described embodiment, a case is shown in which a total power generation meter for photovoltaic power generation and wind power generation is provided to deal with green power certificate transactions as corresponding to a system for buying and selling the environmental value of power. However, the present invention is not limited to this, and other systems that can be utilized by _{companies around the world for CO 2} reduction efforts toward the control of global warming and the realization of a low-carbon and decarbonized society. For example, the J-credit system and non-fossil certificates may be dealt with. The J-credit system is a system in which the national government certifies the amount of emission reduction and absorption of greenhouse gases such as _{CO 2} through the introduction of energy-saving equipment and renewable energy, forest management, etc. as "credits". A non-fossil certificate that is bought and sold in the non-fossil value trading market is a certificate obtained by extracting the "non-fossil value" of electricity generated by a "non-fossil power source" that does not use fossil fuels such as oil and coal. Is.

Further, in the above embodiment, the case where the solar power generation and the wind power generation are combined is shown, but the present invention is not limited to this, and a fuel cell may be further combined.
The fuel cell may, for example, also serve as a hot water supply, and may reform city gas to supply hot water and generate power at the same time. However, the fuel cell is not limited to the hot water supply type and only generates power. It may be. A fuel cell is a device that directly generates electricity by chemically reacting hydrogen and oxygen. Although it has the name of a battery, it does not store charged electricity like a storage battery. Hydrogen, which is the fuel for fuel cells, is generally produced by reforming natural gas or methanol, and oxygen is taken in from the atmosphere. In addition, since heat is generated at the same time as power generation, the efficiency of energy utilization can be improved by utilizing the heat.

Further, in the above embodiment, the case where the surplus power from the private use is sold from the distribution board to the external power transmission line network via the power meter for selling / purchasing power is shown. The idea is not limited to this, and the power capacity stored in the storage battery (stationary type) 50 or the electric vehicle 54 by collecting the market price data of the wholesale power price power by using the power sale and purchase mediation computer. It may be configured to collect data, determine whether to sell, consume, or buy power, and output a command signal to the power selling / buying power meter 60. ..
As a criterion for determining a computer for selling and purchasing electricity, when the wholesale electricity price electricity supplied by the external power transmission line network is the normal transaction price, it is stored in the storage battery (stationary type) 50 or the electric vehicle 54. Since it is within the expected range of the production price of electric power, it will be supplied as necessary electric power for the dwelling unit, which is a consumer. On the other hand, when the wholesale power price power supplied by the external power transmission line network soars, the power stored in the storage battery (stationary type) 50 or the electric vehicle 54 is prioritized over the required power of the dwelling unit which is the consumer. Contributes to the supply of peak power.

That is, the installers of solar power generation and wind power generation equipment can use feed-in tariff (FIT), which allows the power company to purchase the power generated on a sunny day or a windy day. The investment amount of the power generation equipment that combines solar power generation and wind power generation can be recovered. Then, during times when there is no sun or no wind, for example, by buying electricity through the Japan Electric Power Exchange (JEPX), we can supply electricity during peak demand such as cooling demand in summer and heating demand in winter. It is stabilizing.

However, the liberalization of electricity has separated power generation companies and transmission companies, and has restrained power companies from making huge investments in power generation and transmission facilities during peak hours. Nuclear power plants have been shut down, and coal-fired power has also been reduced by "decarbonization," increasing dependence on LNG, which is unstable in price and supply, and losing the ability to adjust the stable supply of electricity during peak demand. It has been.
Therefore, during peak demand, the wholesale electricity price of the Japan Wholesale Electric Power Exchange soars, and the wholesale electricity charge is passed on to the electricity bill for the new electric power company that sets the market-linked charge. For example, the electricity bill for green electricity is determined by adding "spot price x usage amount" to the basic charge, so if the wholesale electricity charge exceeds 20 times the normal price, your own power generation facility (solar power plant) In the case of a consumer who receives electricity from a reseller who sells electricity purchased from JEPX without having (such as), there is a problem that he / she has to pay an unexpected electricity bill.

The idea of equipping a computer for power sales and purchase mediation solves the above-mentioned problems, and the wholesale power price of the Japan Wholesale Power Exchange soars during peak demand such as cooling demand in summer and heating demand in winter. Even if such a situation occurs, it is possible to provide a green power generation device that can suppress the rise in the wholesale power price and, when used in-house, can stabilize the power payment fee of the consumer.

According to the green power generation device of the present invention, CO such as solar power, wind power, hydraulic power, and geothermal power can be utilized _{for CO 2} reduction efforts toward the suppression of global warming and the realization of a low-carbon / decarbonized society. It is possible to provide a green power generation device generated by an energy source that does not emit _2.

10 Photovoltaic power generation device 12 Photovoltaic power generation panel 14 Ventilation port between panels (gap for air flow)
15 Junction box (for solar power generation)
16 junction box (for wind power generation)
20 Stand 30 Wind power generator 40 Power regulator (power conditioner)
42 Electric energy meter (for total wind power generation)
50 Storage battery (stationary type)
52 Power conditioner 53 Green wattmeter (total power generation meter)
54 Electric vehicle 56 Electric vehicle charge / discharge equipment (V2H equipment)
57 Solar / wind breaker 58 Distribution board 60 Power meter for selling / purchasing power 64 Power line 70 Dwelling unit 72 Electrical equipment 74 Power monitor

Claims (6)

It is a green power generation device that combines a solar power generation device, a wind power generation device, a junction box, a storage battery, a power conditioner, a distribution board, and a power meter for selling and purchasing power.
A junction box into which the power generated by the photovoltaic power generation device and / and the wind power generation device is input, and
A storage battery connected via the junction box, which stores the electric power generated by the photovoltaic power generation device and / and the wind power generation device, and the storage battery.
A power conditioner that converts the DC power stored in the storage battery into AC power that can be used at home.
A total power generation meter that is connected to the power conditioner and measures the total power generation of the solar power generation device and / and the wind power generation device.
A distribution board connected to the total power generation meter, which has a branch circuit for transmitting electricity from the distribution board to each room in the home.
A power meter for selling / purchasing power that measures the amount of power sold from the distribution board to the external power transmission line network and the amount of power purchased from the external power transmission line network.
A green power generator equipped with. The photovoltaic power generation device has a plurality of photovoltaic power generation panels that photoelectrically convert sunlight, and a stand that holds the light receiving surface of the photovoltaic power generation panel in the direction in which sunlight is incident, and the photovoltaic power generation panel. The green power generation device according to claim 1, wherein at least one of the above is mounted on the gantry with a gap for air circulation provided between the solar power generation panel and the solar power generation panel adjacent thereto. ,
The wind power generator is of a vertical type in which the rotation axis of the wind turbine is located perpendicular to the ground, and has a plurality of wind receiving members that are rotated by the wind that has passed through the air flow gap of the solar power generation panel. The green power generation device according to claim 1 or 2, further comprising the windmill and a generator that converts the rotational energy generated by the windmill into electrical energy to generate power. The storage battery is
The first storage battery for supplying the required electric power of the consumer, and the first storage battery having a storage capacity of one hour or more of the required electric power of the consumer.
It has a second storage battery that is connected to the first storage battery and the external power transmission line network side and has a storage capacity of one day or more of the required power of the consumer.
The green power generation device according to any one of claims 1 to 3. The green power generation device according to claim 4, wherein the second storage battery is a storage battery for an electric vehicle. The total power generation meter is a total power generation meter for photovoltaic power generation and wind power generation for dealing with at least one of a green power certificate transaction, a J credit system, or a non-fossil certificate. The green power generation device according to any one of 5.

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