JP2019140889A - Photovoltaic power generation system distributed below panel - Google Patents

Abstract

To realize "increase of power generation amount" and "facilitation of conveyance", by placing a power conditioner and a transformer below a solar cell panel.SOLUTION: A photovoltaic power generation system 1 has a solar cell panel 2, a power conditioner 3 for converting a DC current from the solar cell panel 2 into a low voltage AC current L, a transformer 4 for transforming the low voltage AC current L from the power conditioner 3 into a higher voltage AC current H, and a transmission section 5 for transmitting the high voltage AC current H from the transformer 4. The power conditioner 3 and the transformer 4 may be placed below the solar cell panel 2, the transmission section 5 may also be placed below the solar cell panel 2, the power conditioner 3 and the transformer 4 may be placed below the solar cell panel 2, and between the installation surface P of the solar cell panel 2 and the solar cell panel 2, or the power conditioner 3 and the transformer 4 may be placed, respectively, below different solar cell panels 2.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power conditioner that converts a direct current from a solar cell panel into a low-voltage alternating current, a transformer that transforms a low-voltage alternating current from the power conditioner into a higher-voltage high-current alternating current, and a high-voltage from the transformer. Photovoltaic power generation system with a power transmission unit that transmits alternating current, a transformer that transforms input alternating current into higher-voltage alternating current, and power that converts direct current from outside the cabinet into low-voltage alternating current The present invention relates to a conditioner, a transformer that transforms a low-voltage AC current from a power conditioner into a higher-voltage AC current, and a switchboard having a power transmission unit that transmits the high-voltage AC current from the transformer to the outside of the panel casing.

Conventionally, a solar power generation system having a plurality of solar battery panels is known (see Patent Document 1).
The installation structure of this solar power generation system is such that a plurality of solar cell array structures including a solar cell array to which a plurality of solar cell panels are connected and a gantry to which the solar cell array is fixed are arranged next to each other. The interval formed between the solar cell array structures is set to be less than the width of the work space for the operator to perform work or less than the width of the pass space for the operator to pass, At least one of the matching solar cell array structures is movable so that the interval is increased to the width of the working space or the width of the traffic space by changing the inclination angle of the solar cell array with respect to the installation surface of the gantry. Department.

JP 2018-11484 A

However, in the photovoltaic power generation system described in Patent Document 1, a power conditioner (DC / AC converter) or a transformer (voltage converter) is included in the white building shown in FIGS. As described in Paragraph 0071 of Patent Document 1, since these buildings are large in size, it is not necessary to provide the crossing space S so that the shadow of the building is not applied to the solar panel. Must not.
That is, the solar power generation system of Patent Document 1 cannot install solar cell panels by the amount of intersection space S, and the power generation amount of the solar power generation system is reduced accordingly.
Furthermore, the solar power generation system disclosed in Patent Document 1 is large when a road for carrying a structure for storing a power conditioner or a transformer is narrow, such as a golf course site or a mountainous land. In the first place, it becomes difficult to transport the building to the place where the photovoltaic system is installed.

  In view of such points, the present invention is a photovoltaic power generation system capable of achieving “increase in power generation” and “ease of transportation” by arranging a power conditioner, a transformer, and the like below a solar cell panel, etc. It aims at providing a transformer and a switchboard.

  A photovoltaic power generation system 1 according to the present invention includes a solar cell panel 2, a power conditioner 3 that converts a DC current from the solar cell panel 2 into a low-voltage AC current L, and a low-voltage AC current from the power conditioner 3. A photovoltaic power generation system including a transformer 4 that transforms L into a higher-voltage AC current H and a power transmission unit 5 that transmits the high-voltage AC current H from the transformer 4, and includes at least the power conditioner 3 The first feature is that the transformer 4 is disposed below the solar cell panel 2.

  A second feature of the photovoltaic power generation system 1 according to the present invention is that, in addition to the first feature, the power transmission unit 5 is also disposed below the solar cell panel 2.

  A third feature of the photovoltaic power generation system 1 according to the present invention is that, in addition to the first or second feature, at least the power conditioner 3 and the transformer 4 are below the solar cell panel 2 and It exists in the point arrange | positioned between the installation surface P of the said solar cell panel 2, and the said solar cell panel 2. FIG.

  The fourth feature of the photovoltaic power generation system 1 according to the present invention includes, in addition to the first to third features, a plurality of switchboards 100 including at least the power conditioner 3 and the transformer 4, and the plurality of these The switchboard 100 is arranged below the solar cell panel 2 and in a distributed manner.

  A fifth feature of the photovoltaic power generation system 1 according to the present invention is that, in addition to the first feature, there are a plurality of the solar battery panels 2, and at least the power conditioner 3 and the transformer 4 are different from each other in the solar power system. It exists in the point arrange | positioned under the battery panel 2. FIG.

  The sixth feature of the photovoltaic power generation system 1 according to the present invention is that a solar cell panel 2, a power conditioner 3 that converts a direct current from the solar cell panel 2 into a low-voltage alternating current L, and the power conditioner 3 A solar power generation system having a transformer 4 that transforms the low-voltage AC current L from the transformer 4 into a higher-voltage AC current H, and a power transmission unit 5 that transmits the high-voltage AC current H from the transformer 4, The transformer 4 and the power transmission unit 5 are located below the solar cell panel 2.

  A seventh feature of the solar power generation system 1 according to the present invention is that, in addition to the sixth feature, there are a plurality of the solar battery panels 2, and the power conditioner 3 includes the transformer 4 and the power transmission unit 5. It exists in the point arrange | positioned under the solar cell panel 2 different from the solar cell panel 2 arrange | positioned below.

  The eighth feature of the photovoltaic power generation system 1 according to the present invention is that, in addition to the sixth or seventh feature, at least the transformer 4 and the power transmission unit 5 are located below the solar cell panel 2 and It exists in the point arrange | positioned between the installation surface P of the solar cell panel 2, and the said solar cell panel 2. FIG.

  The ninth feature of the photovoltaic power generation system 1 according to the present invention is that, in addition to the sixth to eighth features, a plurality of switchboards 100 ′ including at least the transformer 4 and the power transmission unit 5 are provided. The switchboard 100 ′ is disposed below the solar cell panel 2 and in a distributed manner.

  A tenth feature of the photovoltaic power generation system 1 according to the present invention is that, in addition to the first to ninth features, the height of the transformer 4 is 1500 mm or less.

Due to these features, by disposing at least the power conditioner 3 and the transformer 4 below the solar cell panel 2, unlike the patent document 1, the switchboard 100 including the power conditioner 3, the transformer 4, and the like. Since the shadow is not applied to the solar cell panel 2 and it is not necessary to provide a space therefor, it is possible to install more solar cell panels 2 and increase the power generation amount of the solar power generation system 1 ( “Increase in power generation”).
And since the switchboard 100, such as the power conditioner 3 and the transformer 4, is miniaturized so that it can be arrange | positioned under the solar cell panel 2, the solar power generation system 1 is used for a golf course ruins, a mountainous land, etc. Even when the road to which the switchboard 100 is carried in is narrow when installed in the vehicle, it can be easily transported (“easy transport”).
In the present invention, disposing at least the power conditioner 3 and the transformer 4 below the solar cell panel 2 is also referred to as “panel disposition”.

  Further, since the power transmission unit 5 is also disposed below the solar cell panel 2, the shadow of the power transmission unit 5 is eliminated, so that more solar cell panels 2 can be installed. Increase in quantity ”.

Furthermore, by disposing at least the power conditioner 3 and the transformer 4 below the solar cell panel 2 and between the solar cell panel 2 and the installation surface P thereof, the solar cell panel 2 and the installation surface P are arranged. The dead space between them can be used effectively.
The “installation surface P of the solar cell panel 2” in the present invention is the surface on which the solar cell panel 2 is installed, the upper surface of a building such as a factory or a building (a roof surface), a house. It may be any surface such as the top surface of the roof.
In the present invention, at least the power conditioner 3 and the transformer 4 are disposed below the solar cell panel 2 and between the solar cell panel 2 and the installation surface P. Among the “downward arrangement”, it can be said that it is particularly “the installation surface / panel lower arrangement”.

And it has two or more switchboards 100 provided with at least the power conditioner 3 and the transformer 4, and the figure of patent document 1 is arrange | positioned under the solar cell panel 2 and disperse | distributing a plurality of switchboards 100. If a building that houses the inverter or transformer is installed at only one location in the approximate center of the photovoltaic power generation system, as in 15 to 21, the most solar panels are located far from this building. Unlike the case where the cables connecting these solar cell panels and buildings are very long, it is only necessary to connect the cables from the solar cell panels 2 in the vicinity of each of the plurality of distribution boards 100. Can be shortened.
In the present invention, disposing a plurality of switchboards 100 below and in the solar cell panel 2 is a “panel-down-distributed arrangement” among the above-described “panel-down-positioning”. It can also be said.

In addition, by disposing at least the power conditioner 3 and the transformer 4 below the different solar cell panels 2, the lower side of the plurality of solar cell panels 2 can be used more efficiently. "Easy transportation" can be achieved.
At the same time, since the power conditioner 3 and the transformer 4 can be transported separately, even when the road to be carried in is narrow, it is easy to install under the different solar cell panels 2 ("Easy installation"). .

In addition, by disposing at least the transformer 4 and the power transmission unit 5 below the solar cell panel 2, unlike the patent document 1, the shadow of the switchboard 100 ′ including the transformer 4 and the power transmission unit 5 is Since there is no need for the battery panel 2 and there is no need to provide a space therefor, it is possible to install more solar battery panels 2 and increase the amount of power generation. At the same time, the transformer 4 Since the power distribution panel 100 ′ including the power transmission unit 5 and the like is so small that it can be disposed below the solar battery panel 2, the solar power generation system 1 is installed on a golf course site, a mountainous land, or the like. Even when the road into which the switchboard 100 is carried is narrow, “easier transportation” can be realized.
In the present invention, disposing at least the transformer 4 and the power transmission unit 5 below the solar cell panel 2 is also referred to as “panel disposition”.

In addition, by arranging the power conditioner 3 below the solar cell panel 2 different from the solar cell panel 2 where the transformer 4 and the power transmission unit 5 are arranged below, the transformer 4 and the power transmission unit 5 are provided. Further, the switchboard 100 'can be further reduced in size, and further "easy transportation" and "easy installation" can be achieved.
In addition, at least the transformer 4 and the power transmission unit 5 are arranged below the solar cell panel 2 and between the installation surface P of the solar cell panel 2 and the solar cell panel 2, or at least the transformer 4 A plurality of distribution boards 100 ′ including the power transmission unit 5 may be provided, and the plurality of distribution boards 100 ′ may be arranged below the solar cell panel 2 and dispersedly.
The height of the transformer 4 may be 1500 mm or less.

  The transformer 4 according to the present invention is a transformer that transforms an input alternating current into a higher-voltage alternating current, and the first feature is that the height of the transformer is 1500 mm or less. .

  With this feature, by setting the height of the transformer 4 to 1500 mm or less, it becomes easy to dispose the switchboard 100 including such a transformer 4 below the solar cell panel 2.

  The switchboard 100 according to the present invention includes a panel casing 10, a power conditioner 3 that converts a DC current or an AC current from outside the panel casing 10 into a low voltage AC current L, and a low voltage AC from the power conditioner 3. A switchboard comprising a transformer 4 that transforms a current L into a higher-voltage AC current H, and a power transmission unit 5 that transmits the high-voltage AC current H from the transformer 4 to the outside of the panel housing 10. The power transmission unit 5 is provided in the housing 10, the transformer 4 is provided outside the panel housing 10, and the power conditioner 3 is provided outside the panel housing 10. The first feature is that it is provided in a power-con housing 11 different from 10.

  The second feature of the switchboard 100 according to the present invention is that the panel casing 20, the power conditioner 3 that converts a DC current or an AC current from the outside of the panel casing 20 into a low-voltage AC current L, and the power conditioner 3 is a switchboard including a transformer 4 that transforms the low-voltage AC current L from 3 into a higher-voltage AC current H, and a power transmission unit 5 that transmits the high-voltage AC current H from the transformer 4 to the outside of the panel housing 20. The power conditioner 3 and the power transmission unit 5 are provided in the panel casing 20, the transformer 4 is attached to the panel casing 20 from the outside, and the power conditioner 3 to the transformer 4. It has a low voltage cable 6L for flowing a low voltage AC current L and a high voltage cable 6H for flowing a high voltage AC current H from the transformer 4 to the power transmission unit 5. The transformer 4 and the power transmission unit 5 are arranged in this order in this order. Is arranged in Both the power conditioner 3 is that is located on the direction substantially orthogonal in a predetermined direction in a plan view of the transformer 4 and the power transmission unit 5.

  A third feature of the switchboard 100 ′ according to the present invention is a panel housing 10 ′ and a transformer 4 that transforms the low-voltage AC current L from outside the panel housing 10 ′ into a higher-voltage AC current H. The switchboard includes a power transmission unit 5 that transmits the high-voltage AC current H from the transformer 4 to the outside of the panel housing 10 ′, and the power transmission unit 5 is provided in the panel housing 10 ′. The transformer 4 is provided outside the housing 10 '.

With these features, by providing the power transmission unit 5 in the panel casing 10 and providing the transformer 4 outside the panel casing 10, it is sufficient to cool only the power transmission unit 5 in the panel casing 10. In addition, the power required for cooling can be reduced as compared with the case where it is provided in the panel casing 10, and the power conditioner 3 is incorporated in a power conditioner casing 11 different from the panel casing 10 outside the panel casing 10. By providing, it is easy to cope with the capacity change of the power conditioner 3 (for example, even when the capacity of the power conditioner 3 is increased, a power conditioner housing 11 incorporating the power conditioner 3 corresponding to the capacity is newly provided. At the same time, the attached power conditioner 3 can be secured by the power conditioner case 11.
Further, the power conditioner 3 and the power transmission unit 5 are provided in the panel casing 20, and the transformer 4 is attached to the panel casing 20 from the outside, so that only the power conditioner 3 and the power transmission unit 5 are installed in the panel casing 20. The transformer 4 also has a low-voltage cable 6L for flowing low-voltage AC current L and a high-voltage cable 6H for flowing high-voltage AC current H, as compared with the case where the transformer 4 is also provided in the panel housing 20. The transformer 4 and the power transmission unit 5 are arranged side by side in a predetermined direction in this order, and the power conditioner 3 is arranged in a direction substantially orthogonal to the predetermined direction of the transformer 4 and the power transmission unit 5 in plan view. Thus, the power transmission unit 5 can be disposed in a position close to the transformer 4 from a different direction from the power conditioner 3 in the panel casing 20, and as a result, the power transmission unit 5 in the panel casing 20. High voltage from transformer to transformer 4 The cable 6H does not overlap with the low voltage cable 6L from the power conditioner 3 to the transformer 4 in a plan view, and the high voltage cable 6H can be shortened. (“Improved maintenance” and “Inadvertent contact suppression”).
In addition, by providing the power transmission unit 5 in the panel casing 10 ′ and providing the transformer 4 outside the panel casing 10 ′, only the power transmission unit 5 may be cooled in the panel casing 10 ′. In addition, since the power required for cooling is suppressed as compared with the case where it is provided in the panel casing 10 ′, the power conditioner 3 is not incorporated in the panel casing 10 ′. A power conditioner 3 is provided in a separate power conditioner housing 11, or a power conditioner is provided below a solar cell panel 2 different from the solar cell panel 2 in which the transformer 4 and the power transmission unit 5 are disposed below. 3 can be arranged, and it is easy to cope with a change in the capacity of the power conditioner 3 (for example, even if the capacity of the power conditioner 3 increases, a power conditioner housing that incorporates the power conditioner 3 corresponding to the capacity. 11 new Or attached to Bankatamitai 10 ', it is only necessary to add more power conditioner 3 in the downward different solar panels 2, etc.).

  According to the switchboard according to the present invention, an “increase in the amount of power generation” and “ease of transportation” can be realized by arranging a power conditioner, a transformer, and the like below the solar cell panel.

1 is a schematic diagram showing a photovoltaic power generation system according to a first embodiment of the present invention. It is a front view which shows the photovoltaic power generation system of 1st Embodiment, the switchboard which concerns on 1st Embodiment of this invention, and its transformer. It is a left view which shows the photovoltaic power generation system of 1st Embodiment, the switchboard of 1st Embodiment, and a transformer. It is a right view which shows the photovoltaic power generation system of 1st Embodiment, the switchboard of 1st Embodiment, and a transformer. It is a rear view which shows the switchboard and transformer of 1st Embodiment. It is a top view which shows the switchboard and transformer of 1st Embodiment. It is a top view which shows the switchboard which concerns on 2nd Embodiment of this invention. It is a schematic diagram which shows the solar energy power generation system which concerns on 2nd Embodiment of this invention. It is a front view which shows the photovoltaic power generation system of 2nd Embodiment, the switchboard which concerns on 3rd Embodiment of this invention, and its transformer. It is a left view which shows the photovoltaic power generation system of 2nd Embodiment, the switchboard of 3rd Embodiment, and a transformer. It is a right view which shows the photovoltaic power generation system of 2nd Embodiment, the switchboard of 3rd Embodiment, and a transformer. It is a rear view which shows the switchboard and transformer of 3rd Embodiment. It is a top view which shows the switchboard and transformer of 3rd Embodiment. It is a front view which shows the photovoltaic power generation system of 2nd Embodiment, the switchboard which concerns on 4th Embodiment of this invention, and its transformer. It is a left view which shows the photovoltaic power generation system of 2nd Embodiment, the switchboard of 4th Embodiment, and a transformer. It is a right view which shows the photovoltaic power generation system of 2nd Embodiment, the switchboard of 4th Embodiment, and a transformer. It is a top view which shows the switchboard and transformer of 4th Embodiment.

Embodiments of the present invention will be described below with reference to the drawings.
<Overall Configuration of Solar Power Generation System 1 of First Embodiment>
1-3, the solar power generation system 1 which concerns on 1st Embodiment of this invention is shown.
The solar power generation system 1 includes a solar cell panel 2, a power conditioner 3, a transformer 4, and a power transmission unit 5.

The solar power generation system 1 of the first embodiment includes at least a power conditioner 3 and a transformer 4, and may further include a power distribution panel 100 including a power transmission unit 5 and a panel casing 10, 20. In addition, even if it has a power distribution panel G, a power distribution cable G that conducts electricity between the power transmission panel M and a power distribution network N that ends with a steel tower, a power pole, etc., and a watt-hour meter that measures the amount of power flowing through the power distribution cable G I do not care.
This watt-hour meter is provided not only when selling power to the distribution network N but also when purchasing power from the distribution network N.

One solar power generation system 1 according to the first embodiment may include a plurality of solar cell panels 2, power conditioners 3, transformers 4, power transmission units 5, switchboards 100, and the like.
Furthermore, when there are a plurality of solar cell panels 2 or the like, the solar power generation system 1 may have a plurality of junction boxes (with a breaker or the like) that conduct with a predetermined number of the plurality of solar cell panels 2. First, each switchboard 100 is electrically connected to the plurality of junction boxes. However, the function of the junction box may be built in the switchboard 100. In this case, each switchboard 100 includes a plurality of solar battery panels 2. Of these, it is directly connected to every predetermined number.

In addition, the voltage when the power is finally transmitted from the power transmission panel M to the distribution network N may be a voltage (for example, 6600 V) that can be sold or purchased. However, a higher voltage (for example, a special high voltage (extra high)). For example, 22000V or the like may be used. In this case, the power transmission board M is provided with a transformer (extra high) that boosts to an extra high.
Further, the solar panel 2, the switchboard 100, the transmission board M, and the like are arranged according to the size and shape of the land to be installed. For example, the power generation of one switchboard 100 is, for example, 1500 kW (each power conditioner The solar power generation system 1 may be provided with a plurality of switchboards 100 (for example, 30 units or more and 15000 kW (15 MW) or more, 60 units and 30000 kW (30 MW)).
Of the photovoltaic power generation system 1 according to the first embodiment, first, the switchboard 100 including the power conditioner 3 and the transformer 4 will be described in detail.

<First embodiment of switchboard 100>
2 to 6 show a switchboard 100 according to the first embodiment of the present invention.
As described above, the switchboard 100 according to the first embodiment includes at least the power conditioner 3 and the transformer 4, and can also be said to include the panel casing 10 and the power transmission unit 5.

In addition to these, the switchboard 100 includes a backflow prevention diode 12, a switch 13, and the like, and further, a circuit breaker (breaker), a fuse, a relay (relay), a cable (wiring cord), a terminal, a connector, and the like. The electrical equipment, sensors (ammeters, voltmeters), electronic equipment such as a CPU, and the like may be provided in a state of being built in the panel housing 10.
In addition, the switchboard 100 of 1st Embodiment does not have the part which collects several alternating current cables (cable which flows alternating current), but the part which collects several direct current cables (cable which flows direct current) (A so-called DC current collector) may be included.

The switchboard 100 is provided with the power transmission unit 5 in the above-described panel casing 10, the transformer 4 is provided outside the panel casing 10, and the power conditioner 3 is also provided outside the panel casing 10. Yes.
The switchboard 100 also has an air conditioner that circulates the air in the panel casing 10, an uninterruptible power supply (UPS), the power conditioner 3 described above, an air conditioner, an auxiliary machine that supplies current to the UPS, and the like. Also good.

Here, in the case of the solar power generation system 1 to be described later, it is the solar battery panel 2 that supplies the direct current to the power conditioner 3 of the switchboard 100 from the outside of the panel casing 10. In this case, the current is from a generator (motor) rotated by wind power, hydraulic power, wave power or the like.
If the output current from the motor is an alternating current, the power conditioner 3 only needs to include both a converter device that converts alternating current to direct current and an inverter device that converts this direct current to alternating current. If DC is a direct current, the power conditioner 3 only needs to have an inverter device, but the following describes a case where a direct current flows into the power conditioner 3 as in the solar battery panel 2.

<Solar cell panel 2 etc.>
As shown in FIGS. 1 to 4, the solar cell panel 2 has a panel shape (flat plate shape), and is irradiated with light so that direct current power is generated between the positive electrode (+ electrode) and the negative electrode (−electrode). The average power generated is about 100 to 300 W (for example, 250 W).
Among these, the negative pole of another solar battery panel 2 is connected to the positive pole of another solar battery panel 2, the negative pole of another solar battery panel 2 is connected to the positive pole of another solar battery panel 2, Hereinafter, by repeating this, a plurality of (for example, 5 to 20) solar cell panels 2 are connected in series to form one solar cell string 2 ′.

Thus, the voltage between the positive electrode (power output terminal) and the negative electrode (ground terminal) as a whole of the solar battery string 2 ′ in which a plurality of solar battery panels 2 are connected in series is the solar cell panel 2. This is the sum of the DC voltages generated in the above, and varies depending on the weather, time of day, deterioration of each solar cell panel 2, failure, displacement of the installation position, etc., but is about 200 to 1000V.
The power output from the power output terminal of the solar cell string 2 ′ is the sum of the power of each solar cell panel 2 and is about 500 to 6000 W (for example, 14 solar cell panels 2 with an output power of 250 W). When connected, 3500W = 3.5kW).

Here, connecting the solar cell panels 2 in series means that if any one of the solar cell panels 2 is defective, the current is interrupted in the solar cell panel 2. It becomes difficult to output the electric power generated by the other solar cell panel 2.
Therefore, by providing a bypass diode (not shown) for each of the solar cell panels 2 connected in series, the solar cell panel 2 in which a problem has occurred is configured to bypass (detour) the current.

The bypass diode is connected in parallel to the solar cell panel 2 in the direction in which current flows from the negative electrode to the positive electrode. Specifically, the cathode (cathode) of the bypass diode is connected to the positive electrode of the solar cell panel 2. The anode (anode) of the bypass diode is connected to the negative electrode of the solar cell panel 2.
The mount 14 for installing such a solar cell panel 2 will be described below.

<Base 14>
As shown in FIGS. 1 to 4, the gantry 14 is a structure that supports the above-described solar cell panel 2, and the solar cell panel 2 is installed on the installation surface P via the gantry 14.
The installation surface P may be any surface as long as the solar battery panel 2 can be installed. For example, a golf course site, a mountainous land, a vacant land, a building, a company building, Any surface such as an upper surface (a roof surface) of a building such as a factory or an upper surface of a roof of a house may be used.

The gantry 14 may have any structure as long as it can support the solar cell panel 2 such as a frame shape, a box shape (housing shape), or a bar shape.
The gantry 14 may support the solar cell panel 2 by tilting it in a predetermined direction (for example, lowering toward the south) in order to increase the power generation amount of the photovoltaic power generation system 1.

When the gantry 14 tilts the solar cell panel 2, the angle may be any number as long as a sufficient power generation amount can be obtained, but is, for example, 10 degrees or 5 degrees.
Further, the gantry 14 may be configured such that the inclination angle of the solar cell panel 2 after installation may be variable, or may be the gantry 14 that allows the solar cell panel 2 to be folded or movable.
The power conditioner 3 and the like disposed below the solar cell panel 2 supported by the gantry 14 will be described below.

<Power conditioner 3>
As shown in FIGS. 1 to 6, the power conditioner 3 generates a direct current from the outside of the panel housing 10 such as the solar battery panel 2 (or an alternating current from the outside of the panel housing 10 as described above). What converts into the low voltage | pressure alternating current L may be used.
The power conditioner 3 is provided (attached) to a panel casing 10 to be described later in a state of being built in a power conditioner casing 11 different from the panel casing 10, and is a solar cell panel. 2, an inverter device that converts a DC current or the like from a low-voltage AC current L (for example, 100 to 200 V, etc.), a control unit that controls the AC voltage or frequency converted by the inverter device, and an air circuit breaker (ACB) ) Etc.
These inverter device, control unit, circuit breaker, and the like are disposed in a power-con housing 11 described later, and the power-con housing 11 is provided with a rotating fan-like air blowing means for releasing the air inside. May be.

Such a power conditioner 3 is also called a power conditioner for short, as can be seen from a part of the name of the power conditioner housing 11.
Although it can be said that the power conditioner 3 is “panel downward arrangement” as described above, at this time, for example, a certain power conditioner 3 is arranged below a certain solar cell panel 2. Any configuration may be employed such that a certain power conditioner 3 is arranged below a plurality of solar cell panels 2.
In the present invention, “below the solar cell panel 2” means a side closer to the installation surface P than the back surface of the solar cell panel 2 (a surface closer to the installation surface P in the solar cell panel 2). If this installation surface P is the upper surface (the roof surface) of a building such as a factory or building, or the upper surface of a roof of a house, this boundary surface is defined as a boundary surface in the space along the back surface of the solar cell panel 2. If the installation surface P is on the side of the space divided by the location, and the installation surface P is the upper surface (the roof surface) of a building such as a factory or building, or the upper surface of the roof of a house, the factory or building concerned It also includes the inside of buildings such as, and those that exist inside the house.

Further, it can be said that the power conditioner 3 is the above-described “installation surface / panel downward arrangement”. In this case, the power conditioner 3 is disposed in the space where the mount 14 is vacated and surrounded by the mount 14. The Rukoto.
Furthermore, if one photovoltaic power generation system 1 according to the first embodiment has a plurality of power conditioners 3, it can be said that the above-mentioned “panel downward dispersion arrangement” is used. A plurality of power conditioners 3 are dispersed and arranged at predetermined intervals one by one below each of the solar cell panels 2 or over a certain number of solar cell panels 2. Any configuration may be employed such that a plurality of power conditioners 3 are arranged in a distributed manner.

<Transformer 4>
1 to 6 show a transformer 4 according to the present invention.
The transformer 4 transforms (boosts) the low-voltage AC current L from the above-described power conditioner 3 to a higher-voltage AC current H, and this transformer 4 is provided outside the panel casing 10 described later. It is done.
On the upper surface of the transformer 4, a cable (low voltage cable 6L) from the power conditioner 3 and a connection portion (connection terminal) to the cable (high voltage cable 6H) to the power transmission unit 5 are provided.

The transformer 4 is a so-called transformer, and converts the low-voltage AC current L (for example, 100 to 200 V) from the power conditioner 3 into a high-voltage AC current H (for example, 6600 V or 22000 V) suitable for power transmission. To do.
Similarly to the above-described power conditioner 3, the transformer 4 may also be “panel lower arrangement” such as “installation surface / panel lower arrangement” or “panel lower dispersion arrangement”. The point is to suppress the height of the transformer 4 while securing the capacity of the transformer 4.

In that respect, the transformer 4 has a sufficient capacity while the height is lower than the conventional one, depending on how the iron cores are assembled.
The specific height of such a transformer 4 is not particularly limited, but may be, for example, 1500 mm or less, preferably 1400 mm or less, more preferably 1200 mm or less, more preferably 1150 mm or less (1100 mm or the like). It may be.
The capacity of the transformer 4 is not particularly limited, but may be 330 kW, for example. Moreover, the transformer 4 may have a radiation fin.

<Power transmission unit 5>
As shown in FIGS. 1-6, the power transmission part 5 transmits the high voltage alternating current H from the transformer 4 mentioned above to the panel housing | casing 10 exterior.
The power transmission unit 5 is provided in a panel housing 10 described later, and includes a vacuum circuit breaker (VCB) 5a, a lightning arrester (SAR), and the like.

In the power transmission unit 5, the high-voltage AC current H from the transformer 4 is connected to the distribution network N via the distribution cable G as the outside of the panel housing 10 after passing through the vacuum circuit breaker 5 a described above, Any configuration may be used as long as it is finally connected to the power distribution network N and can transmit power, such as connecting to the power distribution network N via a power transmission panel M that collects and transmits power from the plurality of power distribution panels 100.
Similarly to the above-described power conditioner 3, the power transmission unit 5 may also be “panel lower arrangement” such as “installation surface / panel lower arrangement” or “panel lower dispersion arrangement”.

The vacuum circuit breaker 5a in the power transmission unit 5 may be rotatable in the front-rear direction, for example, to improve maintainability.
In addition, the power transmission part 5 can be said to be an extra high part and a transmitter, when transmitting extra high voltage electric power (for example, 22000V etc.).

<Backflow prevention diode 12>
As shown in FIG. 5, the backflow prevention diode 12 is a solar cell having a lower potential than the others when a potential difference occurs between each of the solar cell strings 2 ′ in which a plurality of solar cell panels 2 are connected in series. This is for preventing the current from flowing back into the string 2 ′.
The backflow prevention diode 12 has an anode (anode) connected to the positive electrode of the solar cell string 2 ′ and a cathode (cathode) connected to the switch 13 described later.

One backflow prevention diode 12 may be provided for each of the solar cell strings 2 ′, but as a member, two backflow prevention diodes 12 may be combined into one.
Each backflow prevention diode 12 may be provided in any panel housing 10 to be described later. For example, it is opposite to a panel front door 10d to be described later in the panel housing 10 (main body portion 10a). It may be provided on the inner side of the side surface (rear surface or further back of the power transmission section 5), and a rear panel door 10e described later is also provided on the rear surface (rear material) of the panel housing 10. In this case, each backflow prevention diode 12 is provided on the inner side (back side) of the rear panel door 10e.

<Switch 13>
As shown in FIGS. 2 and 3, the switch 13 is an electric device that opens and closes (ON / OFF) the electric circuit from each solar cell panel 2 and the like, and several such switches 13 are collected. The cable is connected to the above-described power conditioner 3 (there are two power conditioners 3 in FIGS. 2 to 6, and thus to each power conditioner 3) through the lower surface of the panel housing 10 described later. .
One switch 13 may be provided for each of the solar cell strings 2 ′ in which a plurality of solar cell panels 2 are connected in series.

Moreover, the switch 13 has a connection part (opening / closing connection part) which connects the code | cord | chord (conductive wire) from the solar cell panel 2 grade | etc., And the code | cord | chord to the backflow prevention diode 12 mentioned above.
In this switching connection part, the side connecting the cord (conductor) from the solar battery panel 2 or the like is the power source side (primary side), and the side connecting the cord to the backflow prevention diode 12 is the load side (secondary side) And

Note that the switch 13 may be provided in any of the panel casings 10 described later. For example, the switch 13 is provided inside each of the left and right side surfaces in the panel casing 10 (main body portion 10a). May be.
If the backflow prevention diode 12 and the switch 13 described so far are also provided in the switchboard 100, the switchboard 100 also incorporates the function of a conventional junction box.

<Board Case 10 of First Embodiment>
As shown in FIGS. 1 to 6, the panel housing 10 of the first embodiment incorporates the power transmission unit 5, the backflow prevention diode 12, the switch 13, or the like described above, or the power condition described above on the outside thereof. A transformer 3 and a transformer 4 are provided.
The panel housing 10 has a substantially rectangular parallelepiped portion (main body portion) 10a and a portion extending from the upper left and right sides (upper right side in FIGS. 2 to 6) of the main body portion and covering the upper side of the transformer 4 described above. (Transformation upper portion) 10b and a portion (transformation-side portion) 10c extending downward from the end opposite to the main body portion 10a of the transformation upper portion 10b.

The panel casing 10 of the first embodiment is provided with a panel front door 10d that can be opened and closed on the front surface (front material), and “front and rear” in the panel casing 10 includes the panel front door 10d. The side is “front”, and the side opposite to the side with the front panel door 10d is “rear”.
Furthermore, “left and right” in the panel housing 10 means “left” when the left side of the panel housing 10 is moved from “rear” to “front”, and “left” and “front” when the head is moved from “rear” to “front”. The right hand side is “right”.

In the main body portion 10a of the panel housing 10 of the first embodiment, a backflow prevention diode 12, a switch 13 and the like are incorporated in addition to the power transmission unit 5 described above.
The transformer upper portion 10b of the panel housing 10 covers a connection terminal with a cable from the power conditioner 3 (low voltage cable 6L) and a cable to the power transmission unit 5 (high voltage cable 6H). The high voltage cable 6H will pass.

A low-voltage cable 6L passes through the transformer-side portion 10c of the panel housing 10 of the first embodiment, and a power-con housing 11 described later is attached.
For example, in FIGS. 2 to 6, the transformer 4 is attached to the panel casing 10 on the right side of the body portion 10 a of the panel casing 10, and the transformer-side portion 10 c covers the panel casing 10. Is on the right side of the transformer 4.
In addition, the upper surface (roof) of each part 10a-10c in the panel housing 10 may incline backward (it may become low as it goes back from the front), and the rear surface of the panel housing 10 The (rear material) may also be provided with a panel rear door 10e that can be opened and closed.

<Power-con housing 11>
2-6, the power conditioner housing | casing 11 is a housing | casing separate from the panel housing | casing 10 described so far, and incorporates the above-mentioned power conditioner 3. As shown in FIG.
Only one power conditioner casing 11 (that is, the power conditioner 3) may be provided for one panel casing 10 (one switchboard 100), or a plurality of power conditioner cases 11 may be provided. A case where two power-con housings 11 are provided in one panel housing 10 will be mainly described.

The power conditioner casing 11 is provided (attached) to the side portion of the above-described panel casing 10 (on the left side of the main body portion 10a and the right side of the transformer side portion 10c in FIGS. 2 to 6).
The power-con housing 11 also has an openable / closable door (power-con door) 11a. However, the power-con door 11a is different from the front door 10d of the panel housing 10, and each of the power-con doors 11a is provided in the panel housing 10. Open and close outward.
The power conditioner housing 11 may be provided with a blowing means such as a rotating fan that allows the air inside to escape to the outside.

The power conditioner casing 11 and the panel casing 10 (that is, the switchboard 100) are disposed below the solar cell panel 2 (more specifically, an empty space surrounded by the gantry 14).
A plurality of distribution boards 100 of the first embodiment having such a configuration are provided in one photovoltaic power generation system 1 of the first embodiment, and in each of the distribution boards 100, from the direct current at a position as close as possible to the solar cell panel 2. By completing the conversion, boosting, and power transmission of the AC and connecting the switchboards 100 with cables that pass an AC current boosted to 6600 V or the like, the power transmission loss in the photovoltaic power generation system 1 of the first embodiment is minimized. Can be reduced.

<Second embodiment of switchboard 100>
FIG. 7 shows a switchboard 100 according to the second embodiment of the present invention.
The second embodiment is different from the first embodiment in that the power conditioner 3 is also provided in the panel housing 20.
That is, the switchboard 100 of the second embodiment does not have the power conditioner housing 11.

Furthermore, the second embodiment differs from the first embodiment in that the power conditioner 3 is arranged in a direction substantially orthogonal to the predetermined direction in which the transformer 4 and the power transmission unit 5 are arranged in this order in a plan view. It is a point.
Therefore, the power conditioner 3 is disposed at a position where the transformer 4 and the power transmission unit 5 are substantially L-shaped (see FIG. 7) or substantially T-shaped in a plan view.

The switchboard 100 of the second embodiment having such a configuration is most different in the panel housing.
Therefore, first, the panel housing 20 of the second embodiment will be described.

<Board Case 20 of Second Embodiment>
As shown in FIG. 7, in the panel casing 20 of the second embodiment, the power conditioner 3 is also provided in the panel casing 20, and the predetermined direction of the transformer 4 and the power transmission unit 5 is a plan view. As long as the power conditioner 3 is disposed in a substantially orthogonal direction, the configuration and shape thereof are not limited. For example, the panel housing 20 is formed in a substantially rectangular parallelepiped shape.

In the plan view of the panel housing 20 of the second embodiment having a substantially rectangular parallelepiped shape, one of the four corners is missing (notched portion 20a is provided).
The cutout portion 20a of the panel housing 20 may have a shape and size that allows the transformer 4 to be attached from the outside of the panel housing 20. For example, the notch 20a has a substantially rectangular shape (in practice, a substantially rectangular parallelepiped). May be configured).

Inside the panel casing 20 of the second embodiment, in addition to the power conditioner 3 and the power transmission section 5, a current collector, an air conditioner that circulates the air in the panel casing 20, an uninterruptible power supply (UPS), a power Auxiliary equipment that supplies current to conditioner 3, air conditioner, UPS, breaker, fuse, relay (relay), cable (wiring cord), terminal, connector and other electrical equipment, sensors (ammeter, voltage) And a support member that supports these may be provided.
The panel housing 20 may be provided with a door that can be opened and closed. Outside the corner (outer surface) of the panel housing 20, an air conditioner outdoor unit or the like is installed other than the corner where the transformer 4 is mounted. It may be done.

<Power conditioner 3>
As shown in FIG. 7, the power conditioner 3 is disposed in a position close to the transformer 4 in the panel housing 20 in a plan view.
By arranging in this way, the low-voltage cable 6L that flows the low-voltage alternating current L from the power conditioner 3 to the transformer 4 becomes as short as possible.

<Transformer 4>
As shown in FIG. 7 and described above, the transformer 4 is attached (arranged) to the notch 20a outside the panel housing 20 in a plan view.
The transformer 4 may have any connection terminal to the low voltage cable 6L or the high voltage cable 6H described above, but may be provided on the upper surface of the transformer 4, for example. The height of the panel casing 20 is set lower than the height of the panel casing 20, the notch 20 a is not provided in the panel casing 20 higher than the transformer 4, and the inside of the panel casing 20 is disposed above the transformer 4. The cables 6L and 6H may be passed through the opening by using a configuration such as providing an opening communicating with the outside.

<Power transmission unit 5>
As shown in FIG. 7, the power transmission unit 5 is also provided at a position in the panel housing 20 and close to the transformer 4 other than the position where the above-described power conditioner 3 is provided in plan view ( Is placed).
In this case, the power conditioner 3 is arranged in a direction substantially orthogonal to the predetermined direction in which the transformer 4 and the power transmission unit 5 are arranged in this order, and this state is the power conditioner in the plan view. 3, the transformer 4, and the power transmission unit 5 can be said to be arranged at positions substantially L-shaped.

  By arranging in this way, the high-voltage cable 6H that flows the high-voltage alternating current H from the transformer 4 to the power transmission unit 5 is shortened as much as possible, and at the same time, the high-voltage cable 6H is flat with the low-voltage cable 6L in the panel housing 20. The possibility of inadvertent contact with the high-pressure part during inspection by the user is reduced.

<Current collector etc.>
As shown in FIG. 7, the above-described current collector, air conditioner, UPS, auxiliary machine, and the like are arranged in the panel casing 20 on the side farther from the transformer 4 than the power conditioner 3 and the power transmission unit 5. Has been.
The switchboard 100 according to the second embodiment may be “disposed below the panel” such as “disposition on the installation surface / panel” or “distributed disposition on the panel” as in the first embodiment.
Other configurations of the switchboard 100 of the second embodiment, the photovoltaic power generation system 1 of the first embodiment using the switchboard 100, the transformer 4 in the switchboard 100 of the second embodiment, and the like, the operational effects and usage modes are as follows: This is the same as the switchboard 100 of the first embodiment.

<Overall Configuration of Solar Power Generation System 1 of Second Embodiment>
8 to 10 show a photovoltaic power generation system 1 according to the second embodiment of the present invention.
This solar power generation system 1 also has a solar cell panel 2, a power conditioner 3, a transformer 4, and a power transmission unit 5.

The photovoltaic power generation system 1 of the second embodiment may include a power distribution panel 100 ′ including at least a transformer 4 and a power transmission unit 5, and further including a panel housing 10 ′. You may have M, the power distribution panel G and the power distribution cable G which conduct | electrically_connects the power distribution network N which makes a steel tower, a utility pole, etc. terminal, and the watt-hour meter which measures the electric energy which flows through this power distribution cable G.
This watt-hour meter is provided not only when selling power to the distribution network N but also when purchasing power from the distribution network N.

One solar power generation system 1 according to the second embodiment may include a plurality of solar cell panels 2, power conditioners 3, transformers 4, power transmission units 5, switchboards 100 ′, and the like.
Furthermore, when there are a plurality of solar cell panels 2 or the like, the solar power generation system 1 may have a plurality of junction boxes (with a breaker or the like) that conduct with a predetermined number of the plurality of solar cell panels 2. First, each switchboard 100 ′ is electrically connected to the plurality of junction boxes. However, the function of this junction box may be built in the switchboard 100 ′. In this case, each switchboard 100 ′ has a plurality of solar panels. The battery panel 2 is directly connected to every predetermined number.

In addition, the voltage when the power is finally transmitted from the power transmission panel M to the distribution network N may be a voltage (for example, 6600 V) that can be sold or purchased. However, a higher voltage (for example, a special high voltage (extra high)). For example, 22000V or the like may be used. In this case, the power transmission board M is provided with a transformer (extra high) that boosts to an extra high.
In addition, the solar panel 2, the switchboard 100 ′, the power transmission board M, and the like are arranged according to the size and shape of the land to be installed. For example, the power generation of one switchboard 100 ′ is, for example, 1500 kW (each power The solar power generation system 1 may be provided with a plurality of switchboards 100 (for example, 30 units or more and 15000 kW (15 MW) or more, and 60 units 30000 kW (30 MW)).
Of the photovoltaic power generation system 1 according to the second embodiment, first, the power distribution panel 100 ′ including the transformer 4 and the power transmission unit 5 will be described in detail.

<Third embodiment of switchboard 100 '>
8 to 13 show a switchboard 100 ′ according to a third embodiment of the present invention.
As described above, the switchboard 100 ′ of the third embodiment includes at least the transformer 4 and the power transmission unit 5, and can also be said to include the panel casing 10 ′.

In addition to these, the switchboard 100 ′ includes a backflow prevention diode 12, a switch 13, and the like, and further, a circuit breaker (breaker), a fuse, a relay (relay), a cable (wiring cord), a terminal, and a connector Electrical devices such as sensors, sensors (ammeters, voltmeters), electronic devices such as CPUs, and the like may also be provided in a state of being built in the panel housing 10 ′.
In addition, the switchboard 100 ′ of the third embodiment may include a portion for collecting a plurality of AC cables (cables for passing an AC current) (so-called AC current collector).

In the switchboard 100 ′, the power transmission unit 5 is provided in the above-described panel casing 10 ′, and the transformer 4 is provided outside the panel casing 10 ′. However, the power conditioner is outside the same panel casing 10 ′. 3 is not provided.
The switchboard 100 ′ may also include an air conditioner that circulates the air in the panel housing 10 ′, and an auxiliary device that supplies current to the uninterruptible power supply (UPS), the above-described air conditioner, UPS, and the like.

Here, in the case of the solar power generation system 1, it is the solar battery panel 2 that supplies the alternating current from the outside of the panel housing 10 ′ of the switchboard 100 ′. , Current from a generator (motor) rotated by hydraulic power, wave power, or the like.
If the output current from the motor is an alternating current, the power conditioner 3 only needs to include both a converter device that converts alternating current to direct current and an inverter device that converts this direct current to alternating current. If DC is a direct current, the power conditioner 3 only needs to have an inverter device, but the following describes a case where a direct current flows into the power conditioner 3 as in the solar battery panel 2.

<Power conditioner 3>
As shown in FIG. 8, the power conditioner 3 may convert a direct current from the solar battery panel 2 or the like (or an alternating current from the motor as described above) into a low-voltage alternating current L.
The power conditioner 3 is built in a power conditioner casing 11 different from the panel casing 10 ′ of the third embodiment to be described later, and a solar cell panel in which a transformer 4 and a power transmission unit 5 to be described later are disposed below. 2 and an inverter device that converts a direct current from the solar cell panel 2 into a low-voltage alternating current L (for example, 100 to 200 V) and the inverter device. It includes a control unit that controls the voltage and frequency of alternating current to be converted, an air circuit breaker (ACB), and the like.
These inverter device, control unit, circuit breaker, and the like are disposed in a power-con housing 11 described later, and the power-con housing 11 is provided with a rotating fan-like air blowing means for releasing the air inside. May be.

Such a power conditioner 3 is also called a power conditioner for short, as can be seen from a part of the name of the power conditioner housing 11.
Although it can be said that the power conditioner 3 is “panel downward arrangement” as described above, in this case, for example, one sheet that is different from the solar battery panel 2 in which the transformer 4 and the power transmission unit 5 are arranged below. A plurality of solar cell panels different from the solar cell panel 2 in which a certain power conditioner 3 is disposed below the solar cell panel 2 or the transformer 4 and the power transmission unit 5 are disposed below. 2, any one configuration such as one power conditioner 3 being arranged over the lower part of 2 may be used.

Further, it can be said that the power conditioner 3 is the above-described “installation surface / panel downward arrangement”. In this case, the power conditioner 3 is disposed in the space where the mount 14 is vacated and surrounded by the mount 14. The Rukoto.
Furthermore, if one photovoltaic power generation system 1 according to the second embodiment has a plurality of power conditioners 3, it can be said that the above-mentioned “panel downward dispersion arrangement” is used. A plurality of power conditioners 3 are dispersed and arranged at predetermined intervals one by one below each of the solar cell panels 2 or over a certain number of solar cell panels 2. Any configuration may be employed such that a plurality of power conditioners 3 are arranged in a distributed manner.

<Transformer 4>
8 to 13 show a transformer 4 according to the present invention.
The transformer 4 transforms (boosts) the low-voltage AC current L from the above-described power conditioner 3 to a higher-voltage AC current H, and this transformer 4 is a panel housing according to a third embodiment to be described later. Provided outside the body 10 '.
On the upper surface of the transformer 4, a cable (low voltage cable 6L) from the power conditioner 3 and a connection portion (connection terminal) to the cable (high voltage cable 6H) to the power transmission unit 5 are provided.

The transformer 4 is a so-called transformer, and converts the low-voltage AC current L (for example, 100 to 200 V) from the power conditioner 3 into a high-voltage AC current H (for example, 6600 V or 22000 V) suitable for power transmission. To do.
As described above, the transformer 4 can be said to be disposed below the solar cell panel 2 different from the solar cell panel 2 on which the power conditioner 3 is disposed below. -"Panel lower arrangement" such as "Panel lower arrangement" or "Panel lower distributed arrangement" may be used. However, in any arrangement, the photovoltaic power generation system 1 of the second embodiment also has a point. The height of the transformer 4 is suppressed while securing the capacity of the transformer 4.

In that respect, the transformer 4 has a sufficient capacity while the height is lower than the conventional one, depending on how the iron cores are assembled.
The specific height of such a transformer 4 is not particularly limited, but may be, for example, 1500 mm or less, preferably 1400 mm or less, more preferably 1200 mm or less, more preferably 1150 mm or less (1100 mm or the like). It may be.
The capacity of the transformer 4 is not particularly limited, but may be, for example, 300 kW, 330 kW, 500 kW, or the like. Moreover, the transformer 4 may have a radiation fin.

<Power transmission unit 5>
As shown in FIGS. 8 to 13, the power transmission unit 5 transmits the high-voltage AC current H from the transformer 4 described above to the outside of the panel housing 10 ′.
The power transmission unit 5 is provided in a panel housing 10 ′ described later, and includes a vacuum circuit breaker (VCB) 5a, a lightning arrester (SAR), and the like.

In the power transmission unit 5, the high-voltage alternating current H from the transformer 4 is connected to the distribution network N via the distribution cable G as the outside of the panel housing 10 ′ after passing through the vacuum circuit breaker 5 a and the like. Any configuration may be used as long as it is finally connected to the distribution network N and can transmit power, such as being connected to the distribution network N via the transmission panel M that collects and transmits power from the plurality of distribution boards 100 ′ of the third embodiment. .
Similarly to the transformer 4, the power transmission unit 5 can be said to be disposed below the solar cell panel 2 different from the solar cell panel 2 where the power conditioner 3 is disposed below, as described above. The unit 5 may also be “panel lower arrangement” such as “installation surface / panel lower arrangement” and “panel lower dispersion arrangement”.

The vacuum circuit breaker 5a in the power transmission unit 5 may be rotatable in the front-rear direction, for example, to improve maintainability.
In addition, the power transmission part 5 can be said to be an extra high part and a transmitter, when transmitting extra high voltage electric power (for example, 22000V etc.).

<Backflow prevention diode 12>
As shown in FIG. 12, the backflow prevention diode 12 is a solar cell having a lower potential than the other when a potential difference occurs between each of the solar cell strings 2 ′ in which a plurality of solar cell panels 2 are connected in series. This is for preventing the current from flowing back into the string 2 ′.
The backflow prevention diode 12 has an anode (anode) connected to the positive electrode of the solar cell string 2 ′ and a cathode (cathode) connected to the switch 13 described later.

One backflow prevention diode 12 may be provided for each of the solar cell strings 2 ′, but as a member, two backflow prevention diodes 12 may be combined into one.
Each backflow prevention diode 12 may be provided in any of the panel housings 10 ′ of the third embodiment to be described later. For example, the backflow prevention diodes 12 will be described later in the panel housing 10 ′ (main body portion 10a ′). It may be provided inside the surface opposite to the front panel door 10d ′ (rear surface or further back of the power transmission section 5), and further to the rear surface (rear surface material) of the panel housing 10 ′. When the rear panel door 10e ′ is provided, the backflow prevention diodes 12 are provided on the inner side (back side) of the rear panel door 10e ′.

<Switch 13>
As shown in FIGS. 9 and 10, the switch 13 is an electric device that opens and closes (ON / OFF) the electric circuit from each solar cell panel 2 or the like.
One switch 13 may be provided for each of the solar cell strings 2 ′ in which a plurality of solar cell panels 2 are connected in series.

Moreover, the switch 13 has a connection part (opening / closing connection part) which connects the code | cord | chord (conductive wire) from the solar cell panel 2 grade | etc., And the code | cord | chord to the backflow prevention diode 12 mentioned above.
In this switching connection part, the side connecting the cord (conductor) from the solar battery panel 2 or the like is the power source side (primary side), and the side connecting the cord to the backflow prevention diode 12 is the load side (secondary side) And

The switch 13 may be provided in any of the panel casings 10 ′ of the third embodiment to be described later. For example, the right and left in the panel casing 10 ′ (main body portion 10a ′) may be provided. It may be provided inside each side surface.
If the backflow prevention diode 12 and the switch 13 described so far are also provided in the switchboard 100 ′ of the third embodiment, the switchboard 100 ′ also incorporates the function of a conventional junction box.

<Board Case 10 ′ of Third Embodiment>
As shown in FIGS. 8 to 13, the panel housing 10 ′ of the third embodiment incorporates the power transmission unit 5, the backflow prevention diode 12, the switch 13, or the like described above, or the transformer described above on the outside thereof. A device 4 is provided.
The panel casing 10 'extends from a substantially rectangular parallelepiped portion (main body portion) 10a' and the upper left and right sides (upper right side in FIGS. 9 to 13) of the main body portion and above the transformer 4 described above. A covering portion (transformation upper portion) 10b ′ and a portion (transformation side portion) 10c ′ extending downward from an end opposite to the main body portion 10a ′ of the transformation upper portion 10b ′ are provided.

The panel casing 10 ′ of the third embodiment is provided with a panel front door 10d ′ that can be opened and closed on the front surface (front material), and “front and rear” in the panel casing 10 ′ is a panel front door. The side with 10d 'is referred to as "front", and the side opposite to the side with front panel door 10d' is referred to as "rear".
Further, “left and right” in the panel housing 10 ′ refers to the left hand side when moving from “back” to “front” in the panel housing 10 ′ and from “back” to “front”. The right hand side of the hour is “right”.

In the main body portion 10a ′ of the panel housing 10 ′ of the third embodiment, a backflow prevention diode 12, a switch 13 and the like are incorporated in addition to the power transmission unit 5 described above.
The transformer upper portion 10b ′ of the panel casing 10 ′ covers a connection terminal with a cable (high voltage cable 6H) to the power transmission unit 5, and the high voltage cable 6H passes therethrough.

Here, unlike the panel casing 10 of the first embodiment described above, the power conditioner casing 11 as described above is not attached to the panel casing 10 ′ of the third embodiment.
For example, in FIGS. 9 to 13, the transformer 4 is attached to such a panel casing 10 ′ on the right side of the main body portion 10 a ′ of the panel casing 10 ′. 10 c ′ covers the right side of the transformer 4.
In addition, the upper surface (roof) of each part 10a'-10c 'in the panel housing | casing 10' may incline backward (even if height becomes low as it goes from the front to the back), A panel rear door 10e ′ that can be opened and closed may also be provided on the rear surface (rear material) of 10 ′.

The panel housing 10 ′ of this third embodiment (that is, the power distribution panel 100 ′ of the third embodiment) is disposed below the solar cell panel 2 described above (more specifically, an empty space surrounded by the gantry 14). The
There are a plurality of distribution boards 100 ′ of the third embodiment having such a configuration in one photovoltaic power generation system 1 of the second embodiment, and in each distribution board 100 ′, at a position as close as possible to the solar cell panel 2, Conversion from DC to AC, boosting, and power transmission are completed, and the power distribution loss in the photovoltaic power generation system 1 of the second embodiment is possible by connecting the switchboards 100 'with cables that carry AC current boosted to 6600V, etc. It can be reduced as much as possible.
Other switchboard 100 ′ of the third embodiment, solar power generation system 1 of the second embodiment using this switchboard 100 ′, solar battery panel 2 and mount 14 in the solar power generation system 1 of the second embodiment, Configurations, operational effects, and usage modes of the transformer 4 and the like in the switchboard 100 ′ of the third embodiment are the same as those of the photovoltaic power generation system 1 of the first embodiment and the switchboard 100 of the first embodiment.

<Fourth embodiment of switchboard 100 '>
8 and 14 to 17 show a switchboard 100 ′ according to a fourth embodiment of the present invention.
The switchboard 100 ′ of the fourth embodiment includes at least the transformer 4 and the power transmission unit 5 as in the third embodiment described above, and can also be said to include a panel casing 10 ′.

In addition to these, the switchboard 100 ′ includes a breaker (breaker) 15, a control unit 16, and the like, and further, electric devices such as fuses, relays (relays), cables (wiring cords), terminals, connectors, and the like. Alternatively, sensors (ammeters, voltmeters), electronic devices such as CPUs, and the like may also be provided in a state of being built in the panel housing 10 ′.
In addition, the switchboard 100 ′ of the fourth embodiment may include a portion (so-called an AC current collector) that collects a plurality of AC cables (cables for passing an AC current).

In the switchboard 100 ′, the power transmission unit 5 is provided in the above-described panel casing 10 ′, and the transformer 4 is provided outside the panel casing 10 ′. However, the power conditioner is outside the same panel casing 10 ′. 3 is not provided.
The switchboard 100 ′ may also include an air conditioner that circulates the air in the panel housing 10 ′, and an auxiliary device that supplies current to the uninterruptible power supply (UPS), the above-described air conditioner, UPS, and the like.

Here, in the case of the solar power generation system 1, it is the solar battery panel 2 that supplies the alternating current from the outside of the panel housing 10 ′ of the switchboard 100 ′. , Current from a generator (motor) rotated by hydraulic power, wave power, or the like.
If the output current from the motor is an alternating current, the power conditioner 3 only needs to include both a converter device that converts alternating current to direct current and an inverter device that converts this direct current to alternating current. If DC is a direct current, the power conditioner 3 only needs to have an inverter device, but the following describes a case where a direct current flows into the power conditioner 3 as in the solar battery panel 2.

<Power conditioner 3>
As shown in FIG. 8, the power conditioner 3 may convert a direct current from the solar battery panel 2 or the like (or an alternating current from the motor as described above) into a low-voltage alternating current L.
The power conditioner 3 is built in a power conditioner casing 11 different from the panel casing 10 'of the fourth embodiment described later, and a solar cell panel in which a transformer 4 and a power transmission unit 5 described later are disposed below. 2 and an inverter device that converts a direct current from the solar cell panel 2 into a low-voltage alternating current L (for example, 100 to 200 V) and the inverter device. It includes a control unit that controls the voltage and frequency of alternating current to be converted, an air circuit breaker (ACB), and the like.
These inverter device, control unit, circuit breaker, and the like are disposed in a power-con housing 11 described later, and the power-con housing 11 is provided with a rotating fan-like air blowing means for releasing the air inside. May be.

Such a power conditioner 3 is also called a power conditioner for short, as can be seen from a part of the name of the power conditioner housing 11.
Although it can be said that the power conditioner 3 is “panel downward arrangement” as described above, in this case, for example, one sheet that is different from the solar battery panel 2 in which the transformer 4 and the power transmission unit 5 are arranged below. A plurality of solar cell panels different from the solar cell panel 2 in which a certain power conditioner 3 is disposed below the solar cell panel 2 or the transformer 4 and the power transmission unit 5 are disposed below. 2, any one configuration such as one power conditioner 3 being arranged over the lower part of 2 may be used.

Further, it can be said that the power conditioner 3 is the above-described “installation surface / panel downward arrangement”. In this case, the power conditioner 3 is disposed in the space where the mount 14 is vacated and surrounded by the mount 14. The Rukoto.
Furthermore, if one photovoltaic power generation system 1 according to the second embodiment has a plurality of power conditioners 3, it can be said that the above-mentioned “panel downward dispersion arrangement” is used. A plurality of power conditioners 3 are dispersed and arranged at predetermined intervals one by one below each of the solar cell panels 2 or over a certain number of solar cell panels 2. Any configuration may be employed such that a plurality of power conditioners 3 are arranged in a distributed manner.

<Transformer 4>
8 and 14 to 17 show a transformer 4 according to the present invention.
The transformer 4 transforms (boosts) the low-voltage AC current L from the above-described power conditioner 3 to a higher-voltage AC current H. The transformer 4 is a panel housing of a fourth embodiment to be described later. Provided outside the body 10 '.
On the upper surface of the transformer 4, a cable (low voltage cable 6L) from the power conditioner 3 and a connection portion (connection terminal) to the cable (high voltage cable 6H) to the power transmission unit 5 are provided.

The transformer 4 is a so-called transformer, and converts the low-voltage AC current L (for example, 100 to 200 V) from the power conditioner 3 into a high-voltage AC current H (for example, 6600 V or 22000 V) suitable for power transmission. To do.
As described above, the transformer 4 can be said to be disposed below the solar cell panel 2 different from the solar cell panel 2 on which the power conditioner 3 is disposed below. -"Panel lower arrangement" such as "Panel lower arrangement" or "Panel lower distributed arrangement" may be used. However, in any arrangement, the photovoltaic power generation system 1 of the second embodiment also has a point. The height of the transformer 4 is suppressed while securing the capacity of the transformer 4.

In that respect, the transformer 4 has a sufficient capacity while the height is lower than the conventional one, depending on how the iron cores are assembled.
The specific height of such a transformer 4 is not particularly limited, but may be, for example, 1500 mm or less, preferably 1400 mm or less, more preferably 1200 mm or less, more preferably 1150 mm or less (1100 mm or the like). It may be.
The capacity of the transformer 4 is not particularly limited, but may be, for example, 300 kW, 330 kW, 500 kW, or the like. Moreover, the transformer 4 may have a radiation fin.

<Power transmission unit 5>
As shown in FIGS. 8 and 14 to 17, the power transmission unit 5 transmits the high-voltage AC current H from the transformer 4 described above to the outside of the panel housing 10 ′.
The power transmission unit 5 is provided in a panel housing 10 ′ described later, and includes a vacuum circuit breaker (VCB) 5a, a lightning arrester (SAR), and the like.

In the power transmission unit 5, the high-voltage alternating current H from the transformer 4 is connected to the distribution network N via the distribution cable G as the outside of the panel housing 10 ′ after passing through the vacuum circuit breaker 5 a and the like. The connection to the distribution network N through the transmission panel M that collects and transmits the power from the plurality of distribution boards 100 ′ of the fourth embodiment, or the direct connection to the distribution network N, etc. However, any configuration that can transmit power is acceptable.
The distribution cable G from the power transmission section 5 (the high-voltage AC current H circuit (high-voltage cable 6H)) passes through the substantially rectangular hole 5b on the rear side of the bottom surface of the panel housing 10 ′ of the fourth embodiment. It is good also as connecting to the power transmission panel M or conducting to the power distribution network N.
Similarly to the transformer 4, the power transmission unit 5 can be said to be disposed below the solar cell panel 2 different from the solar cell panel 2 where the power conditioner 3 is disposed below, as described above. The unit 5 may also be “panel lower arrangement” such as “installation surface / panel lower arrangement” and “panel lower dispersion arrangement”.

The vacuum circuit breaker 5a in the power transmission unit 5 may be rotatable in the front-rear direction, for example, to improve maintainability.
In addition, the power transmission part 5 can be said to be an extra high part and a transmitter, when transmitting extra high voltage electric power (for example, 22000V etc.).

<Breaker 15>
As shown in FIGS. 14 to 17, the breaker 15 is an electric device that can cut off the low-voltage AC current L from the power conditioner 3, and is also called a circuit breaker (MCCB (MCB)).
The breaker 15 may have a casing (outer shell) covered with a synthetic resin box, and a handle for manually turning on / off the power may be provided on the front surface, or a tripping mechanism and an arc extinguishing device may be incorporated. .

The breaker 15 may be configured so that the handle stops at an intermediate position between ON and OFF, or stops at an OFF position when the breaker 15 performs an interruption operation due to an abnormal overcurrent or the like.
The casing of the breaker 15 is provided with a cut-off connection part (cut-off connection terminal) for connecting a circuit (low-voltage cable 6L) of the low-voltage AC current L to its end part (upper end, lower end, etc.). The side connecting the circuit of the low-voltage AC current L from the side closer to the conditioner 3 is the power source side (primary side), and the side connecting the circuit of the low-voltage AC current L from the side closer to the transformer 5 is the load side ( (Secondary side).

There is no particular limitation on the number of break connection portions in one breaker 15 as long as the circuit of the low-voltage AC current L can be interrupted. One (three poles), four (four poles) for a three-phase four-wire system, or two (two poles) for a single-phase two-wire system.
That is, the breaker 15 is an “AC breaker”.

The breaker 15 may be provided in any of the panel housings 10 ′ according to the fourth embodiment to be described later. For example, the front lower portion in the panel housing 10 ′ (main body portion 10a ′). The number of breakers 15 provided in one panel housing 10 ′ is not particularly limited, but may be one, for example. , 14 or more.
Moreover, the circuit (low voltage cable 6L) of the low voltage alternating current L between the breaker 15 and the power conditioner 3 is a substantially rectangular shape which is long on the side (left and right direction) on the front side of the lower surface of the panel housing 10 ′ of the fourth embodiment. It is good also as connecting to the power conditioner 3 outside the panel housing | casing 10 'through the hole 15a.

When there are a plurality of such breakers 15, a plurality of electric circuit bodies 15 b having a longitudinal direction and flowing the collected current are disposed at positions farther from the front panel door 10 d ′ of the panel casing 10 ′ described later than these breakers 15. You may have.
The electric circuit body 15b is not particularly limited as long as it has a longitudinal direction and can flow the collected current, but the material may be a rod-shaped plate made of a conductor such as copper, aluminum, silver, gold, or nichrome.

  The number of electric circuit bodies 15b is not particularly limited as long as there are a plurality of electric circuit bodies 15b. However, since the low voltage alternating currents L from the plurality of power conditioners 3 flow, for example, the number of electric circuit bodies 15b is the number of electric circuits (low voltage cables). 6L), if it is a three-phase three-wire system (R phase, S phase, T phase), it can be three (three poles), or a three-phase four-wire system (R phase, S phase, T phase, N phase) ) May be four (four poles), or may be two (two poles) if it is a single-phase two-wire system.

<Control unit 16>
As shown in FIGS. 14 to 17, the control unit 16 includes an air conditioner that circulates air in the panel housing 10 ′, an uninterruptible power supply (UPS), the above-described air conditioner, an auxiliary machine that supplies current to the UPS, and the like. It can be said that it is a control table.
The control unit 16 may also be provided in any of the panel housings 10 ′ of the fourth embodiment to be described later. For example, in the panel housing 10 ′ (main body portion 10a ′), the control unit 16 described above is provided. It may be provided on the side farther from the transformer 4 than the power transmission unit 5.

The control unit 16 is connected to the board via a control cable passing through a substantially rectangular hole 16a provided on the lower surface of the panel housing 10 ′ of the fourth embodiment on the side farther from the transformer 4 than the power transmission unit 5. It is good also as controlling from the housing | casing 10 'outside.
If the breaker 15 and the control unit 16 described so far are also provided in the switchboard 100 ′ of the fourth embodiment, the switchboard 100 ′ also incorporates the function of a conventional AC current collection box.

<Board Case 10 ′ of Fourth Embodiment>
As shown in FIGS. 14 to 17, the panel housing 10 ′ of the fourth embodiment incorporates the above-described power transmission unit 5 or the like, or provides the above-described transformer 4 on the outside thereof.
The panel casing 10 'extends from a substantially rectangular parallelepiped portion (main body portion) 10a' and the upper left and right sides (upper right side in FIGS. 14 to 17) of the main body portion and above the transformer 4 described above. Unlike the panel housing 10 ′ of the third embodiment, the transformer side portion 10c ′ is not provided, although the cover portion (transformation upper portion) 10b ′ is included.

The panel housing 10 ′ of the fourth embodiment is provided with a front panel door 10d ′ that can be opened and closed on the front surface (front material), and two panel front doors 10d ′ are provided. good.
Further, “front and rear” in the panel housing 10 ′ means that the side where the panel front door 10d ′ is present is “front”, and the side opposite to the side where the panel front door 10d ′ is present is “rear”.
Further, “left and right” in the panel housing 10 ′ refers to the left hand side when moving from “back” to “front” in the panel housing 10 ′ and from “back” to “front”. The right hand side of the hour is “right”.

In addition to the power transmission unit 5 described above, a breaker 15, a control unit 16, and the like are built in the main body portion 10 a ′ of the panel housing 10 ′ of the fourth embodiment.
The transformer upper portion 10b ′ of the panel casing 10 ′ covers a connection terminal with a cable (high voltage cable 6H) to the power transmission unit 5, and the high voltage cable 6H passes therethrough.

Here, unlike the above-described panel casing 10 of the first embodiment, the above-described power conditioner casing 11 is not attached to the panel casing 10 ′ of the fourth embodiment.
For example, in FIGS. 14 to 17, the transformer 4 is attached to the panel casing 10 ′ on the right side of the main body portion 10 a ′ of the panel casing 10 ′.
In addition, the upper surface (roof) of each part 10a ', 10b' in the panel housing 10 'has the highest midway part in the front-rear direction when viewed from the side, and is inclined backward from the highest part ( The height may be reduced as it goes from the front to the rear), and an openable / closable panel rear door may be provided on the rear surface (rear material) of the panel housing 10 ′.

The panel housing 10 ′ according to the fourth embodiment (that is, the switchboard 100 ′ according to the fourth embodiment) is disposed below the solar cell panel 2 described above (more specifically, an empty space surrounded by the gantry 14). The
There are a plurality of distribution boards 100 ′ of the fourth embodiment having such a configuration in one photovoltaic power generation system 1 of the second embodiment, and in each distribution board 100 ′, at a position as close as possible to the solar cell panel 2, By finishing the voltage boosting / power transmission and connecting the switchboards 100 ′ with cables that pass an alternating current boosted to 6600 V or the like, the power transmission loss in the solar power generation system 1 of the second embodiment can be reduced as much as possible.
Other switchboard 100 ′ of the fourth embodiment, solar power generation system 1 of the second embodiment using this switchboard 100 ′, solar battery panel 2 and mount 14 in the solar power generation system 1 of the second embodiment, The configuration, operation effect, and usage of the transformer 4 in the switchboard 100 ′ of the fourth embodiment are the solar power generation system 1 of the first embodiment, the switchboard 100 of the first embodiment, and the switchboard of the third embodiment. The same as 100 ′.

<Others>
The present invention is not limited to the embodiment described above. Each configuration of the photovoltaic power generation system 1, the transformer 4, the switchboard 100, 100 ′, etc., or the overall structure, shape, dimensions, and the like can be appropriately changed in accordance with the spirit of the present invention.
The solar power generation system 1 does not need to have the gantry 14, and in this case, the solar battery panel 2 may be supported by the panel housings 10, 10 ', 20 of the switchboards 100, 100'.
The solar power generation system 1 does not have the power transmission panel M, and may be connected to the distribution network N directly from the power transmission unit 5 via the power distribution cable G, and the function of the power transmission panel M is controlled by the power transmission unit 5. You can do it.
In one solar power generation system 1, the switchboard 100 of the first embodiment and the switchboard 100 ′ of the third embodiment or the fourth embodiment may be mixed.
More specifically, one photovoltaic power generation system 1 has both the distribution board 100 of the first embodiment and the distribution board 100 ′ of the third embodiment and the fourth embodiment, and these distribution boards 100, 100 ′. The power conditioner 3 may be arrange | positioned under the solar cell panel 2 different from the solar cell panel 2 arrange | positioned below.

The “panel lower arrangement” in which the power conditioner 3, the transformer 4, the switchboard 100, 100 ′ and the like are arranged below the solar battery panel 2 is the power conditioner 3, transformer 4, power transmission unit 5, switchboard 100. , 100 ′, etc. are not only arranged between the solar cell panel 2 and the installation surface P, but also below the installation surface P, that is, the solar cell panel 2 is installed on the roof of a building, the roof of a house, etc. If it is, it may be arranged below the panel and inside the building or house.
Moreover, if the power conditioner 3, the transformer 4, the power transmission part 5, etc. are arrange | positioned under the solar cell panel 2, the power conditioner 3, the transformer 4, the power transmission part 5, etc. are necessarily integrated as a switchboard. The power conditioner 3 may be disposed below one solar cell panel 2, the transformer 4 may be disposed below another solar cell panel 2, and the power transmission unit 5 may be disposed on another solar cell. The structure of arrange | positioning under the panel 2 etc. may be sufficient.

In FIG. 2, two power conditioner casings 11 (that is, the power conditioner 3) are provided for one switchboard 100 (the switchboard 100 of the first embodiment), which is indicated by a dotted line in FIG. 2. As described above, several power conditioner cases 11 (power conditioners 3) are further attached to the left and right outer sides of the power conditioner case 11 or one right and left outer side, and three or more are attached to one switchboard 100. It is good also as what has the power conditioner 3 of.
A plurality of power conditioners 3 may be incorporated in one power conditioner housing 11.

The switchboards 100 and 100 ′ can also be used when an alternating current is allowed to flow, such as wind power generation, in addition to solar power generation.
The switchboards 100 and 100 ′ may have a built-in storage battery. If there is a surplus in the amount of power generation such as solar power generation, the storage battery is charged and the power generation amount decreases (when it is cloudy, rainy or at night). May use the power from the storage battery to cover the usage of each house (customer).

In addition, the switchboards 100 and 100 ′ may be provided with a hook that can be lifted by a crane or the like on the upper surface of the panel casings 10 and 10 ′, and the entire switchboards 100 and 100 ′ lifted through the hooks You may install it on the foundation (base) constructed beforehand.
The foundation may be made of any material such as concrete or steel (H steel), and the shape of the foundation may be a solid foundation having a uniform thickness or a space below the panel housings 10 and 10 '. It may be a getter foundation having a dent or the like.

  Photovoltaic power generation systems can be used regardless of their power generation amount and scale, and transformers and switchboards generate electricity by a generator (motor) that is rotated by wind power, hydraulic power, wave power, etc. in addition to the solar power generation system. Can be used in any system, and can be used both outdoors and indoors.

DESCRIPTION OF SYMBOLS 1 Photovoltaic power generation system 2 Solar cell panel 3 Power conditioner 4 Transformer 5 Power transmission part 10 Panel housing 10 'Panel housing 11 Power-con housing 20 Panel housing 100 Distribution board 100' Distribution board L Low voltage alternating current H High voltage alternating current 6L Low voltage cable 6H High voltage cable P Solar panel installation surface

A photovoltaic power generation system 1 according to the present invention includes a solar cell panel 2, a power conditioner 3 that converts a DC current from the solar cell panel 2 into a low-voltage AC current L, and a low-voltage AC current from the power conditioner 3. A photovoltaic power generation system including a transformer 4 that transforms L into a higher-voltage AC current H and a power transmission unit 5 that transmits the high-voltage AC current H from the transformer 4 , The solar cell panel 2 is installed on the ground which is the installation surface P via the mount 14, and the transformer 4 is mounted on the ground which is the same installation surface P. A switchboard 100 ′ provided outside the panel 10 ′ and having the power transmission unit 5 built in the panel housing 10 ′ is also installed, and includes a plurality of the solar battery panels 2 and a plurality of the power conditioners 3. The switchboard A plurality of switchboards 100 ′ below the solar cell panel 2 and between the ground surface which is the installation surface P of the solar cell panel 2 and the solar cell panel 2. The plurality of power conditioners 3 are arranged in a dispersed manner, below the solar cell panel 2 different from the solar cell panel 2 on which the switchboard 100 ′ is arranged below, and the installation surface of the solar cell panel 2 A first feature is that the solar cell panel 2 is distributed and disposed between the ground surface as P and the solar cell panel 2 .

A second aspect of photovoltaic power generation system 1 according to the present invention, in addition to the first feature, the a ground installation surface P is golf site, to the point Ru land or vacant lot der mountainous areas .

A third aspect of the solar power generation system 1 according to the present invention, in addition to the first or second feature, the height of the transformer 4 is that Ru der below 1500 mm.

Claims (14)

A solar cell panel (2), a power conditioner (3) for converting a direct current from the solar cell panel (2) into a low-voltage AC current (L), and a low-voltage AC current from the power conditioner (3) ( L) a photovoltaic power generation having a transformer (4) that transforms the higher voltage AC current (H) into a higher voltage and a power transmission unit (5) that transmits the high voltage AC current (H) from the transformer (4) A system,
At least the power conditioner (3) and the transformer (4) are disposed below the solar cell panel (2).   The solar power generation system according to claim 1, wherein the power transmission unit (5) is also disposed below the solar cell panel (2).   At least the power conditioner (3) and the transformer (4) are disposed below the solar cell panel (2) and on the installation surface (P) of the solar cell panel (2), and the solar cell panel (2 The photovoltaic power generation system according to claim 1 or 2, wherein the photovoltaic power generation system is disposed between A plurality of switchboards (100) including at least the power conditioner (3) and the transformer (4);
The sun according to any one of claims 1 to 3, wherein the plurality of switchboards (100) are arranged below the solar cell panel (2) and dispersedly. Photovoltaic system. There are a plurality of the solar cell panels (2),
The solar power generation system according to claim 1, wherein at least the power conditioner (3) and the transformer (4) are arranged below the different solar cell panels (2). A solar cell panel (2), a power conditioner (3) for converting a direct current from the solar cell panel (2) into a low-voltage AC current (L), and a low-voltage AC current from the power conditioner (3) ( L) a photovoltaic power generation having a transformer (4) that transforms the higher voltage AC current (H) into a higher voltage and a power transmission unit (5) that transmits the high voltage AC current (H) from the transformer (4) A system,
At least the said transformer (4) and power transmission part (5) are arrange | positioned under the said solar cell panel (2), The solar power generation system characterized by the above-mentioned. There are a plurality of the solar cell panels (2),
The said power conditioner (3) is arrange | positioned under the solar cell panel (2) different from the solar cell panel (2) in which the said transformer (4) and power transmission part (5) are arrange | positioned below. The solar power generation system according to claim 6.   At least the transformer (4) and the power transmission section (5) are below the solar cell panel (2), and the installation surface (P) of the solar cell panel (2), and the solar cell panel (2). The photovoltaic power generation system according to claim 6 or 7, wherein the photovoltaic power generation system is disposed between the two. A plurality of switchboards (100 ′) including at least the transformer (4) and the power transmission unit (5);
The plurality of the switchboards (100 ') are arranged below the solar cell panel (2) and in a distributed manner, according to any one of claims 6 to 8. Solar power system.   The height of the said transformer (4) is 1500 mm or less, The solar energy power generation system in any one of Claims 1-9 characterized by the above-mentioned. A transformer that transforms an input alternating current into a higher-voltage alternating current,
The transformer has a height of 1500 mm or less. A panel casing (10), a power conditioner (3) for converting a DC current or an AC current from the outside of the panel casing (10) into a low voltage AC current (L), and a power conditioner (3) A transformer (4) that transforms the low-voltage alternating current (L) into a higher-voltage high-voltage alternating current (H), and the high-voltage alternating current (H) from the transformer (4) is transmitted outside the panel housing (10). A switchboard with a power transmission unit (5)
The power transmission section (5) is provided in the panel casing (10),
The transformer (4) is provided outside the panel casing (10),
The power conditioner (3) is provided outside the panel casing (10) in a state of being built in a power conditioner casing (11) different from the panel casing (10). Switchboard to do. A panel casing (20), a power conditioner (3) for converting a direct current or an alternating current from the outside of the panel casing (20) into a low voltage alternating current (L), and a power conditioner (3) A transformer (4) that transforms the low-voltage alternating current (L) into a higher-voltage high-voltage alternating current (H), and the high-voltage alternating current (H) from the transformer (4) is transmitted outside the panel housing (20). A switchboard with a power transmission unit (5)
In the panel housing (20), the power conditioner (3) and the power transmission unit (5) are provided,
The transformer (4) is attached to the panel casing (20) from the outside,
A low-voltage cable (6L) that flows a low-voltage alternating current (L) from the power conditioner (3) to the transformer (4), and a high-voltage alternating current (H) that flows from the transformer (4) to the power transmission unit (5) Has a high voltage cable (6H)
The transformer (4) and the power transmission unit (5) are arranged in a predetermined direction in this order,
The said power conditioner (3) is arrange | positioned on the direction substantially orthogonal in the planar view with the predetermined direction of the said transformer (4) and power transmission part (5), The switchboard characterized by the above-mentioned. A panel housing (10 ′), a transformer (4) for transforming a low-voltage alternating current (L) from outside the panel housing (10 ′) into a higher-voltage AC current (H), and this transformer ( 4) a switchboard comprising a power transmission section (5) for transmitting the high-voltage alternating current (H) from 4) to the outside of the panel housing (10 ′),
The power transmission section (5) is provided in the panel casing (10 ′),
The switchboard (4) characterized in that the transformer (4) is provided outside the panel casing (10 ').