JP2021058077A - Power distribution system, self consumption type power generation plant, transformer, and control box - Google Patents

Abstract

To implement both of "improvement of member cooling performance" and "reduction in the number of members" and the like by, for example, opening three direction sides and the like of a power conditioner and a transformer to the outside of a system.SOLUTION: A power distribution system 1 includes a power conditioner 2 for converting current from the outside of the system to AC current and a transformer 3 for transforming AC current from the power conditioner 2. At least three direction sides of the power conditioner 2 and the transformer 3 are opened to the outside of the system in a plan view, a longer direction L of a cabinet 5 having a control unit 4 for the power conditioner 2 and the like built-in is in approximately parallel with a longer direction L' of the power conditioner 2 in a plan view, the power conditioner 2 and the transformer 3 are arranged vertically side by side, a breaker W is arranged in a cover body 3Q in which an iron core 3X and coil 3Y of the transformer 3 are arranged, and a power-generating plant 21 including the power distribution system 1 and a connection unit 22 connected to a system K and a load F includes a power generation unit 26 connected to the load F via the power distribution system 1.SELECTED DRAWING: Figure 1

Description

The present invention relates to a power distribution system having a power conditioner and a transformer, a power plant having this power distribution system, a transformer, and a cabinet for control (so-called control box).

Conventionally, a switchboard is known (see Patent Document 1).
This switchboard includes a power conditioner having an inverter that converts DC power from a solar panel into AC power, a transformer that boosts the AC power output from the power conditioner to high-pressure AC power, and the transformer. A circuit breaker arranged between existing power systems is housed in one switchboard.

Japanese Unexamined Patent Publication No. 2016-103976

However, the switchboard described in Patent Document 1 houses a transformer and a power conditioner having a very large calorific value inside one board, and the inside of the board becomes hot, so that the transformer and the existing one are existing. Equipment such as a circuit breaker that separates the power systems of the above is indispensable, and there is a problem that the number of members is increased.

In view of these points, the present invention realizes both "improvement of member cooling performance" and "reduction of the number of members" by opening the three-direction side of the power conditioner and the transformer to the outside of the system. The purpose is to provide power distribution systems, power plants, transformers, and cabinets.

The power distribution system 1 according to the present invention is a power distribution system including a power conditioner 2 that converts a direct current or an alternating current from the outside of the system into an alternating current, and a transformer 3 that transforms the alternating current from the power conditioner 2. The first feature is that at least three directions of the power conditioner 2 and the transformer 3 are open to the outside of the system in a plan view.
The "at least three directions in the plan view" in the present invention means the member supporting the power conditioner 2 and the transformer 3 in the plan view of the power distribution system 1 (when the power distribution system 1 is viewed from above). In the part supported by the power distribution frame frame 6 etc.), the side supported by the supporting member is referred to as the "rear side", and the opposite side (opposing side) is referred to as the "front side". Stands directly above the power distribution system 1 and faces from the rear side to the front side, the side on the right hand side of the user is referred to as the "right side", and the side on the left hand side of the user is referred to as the "left side". In this case, at least three of these four sides, "rear side", "front side", "right side", and "left side", are referred to as "at least three directions in a plan view".
Further, regarding the cabinet 5 and the like, regardless of which side is supported by the member actually supported by the cabinet 5 or the like, the user or the like stands directly above the power conditioner 2 and the transformer 3. And when facing from the rear side to the front side, the "rear side", "front side", "right side" and "left side" of the cabinet 5 etc. are the same as the power conditioner 2 and the transformer 3 based on the user and the like. Is decided.
Further, the "rear side", "front side", "right side" and "left side" of the power conditioner 2 and the transformer 3 do not necessarily have to be flat (flat), and may have curved surfaces, irregularities, or power. The plan view shape of the conditioner 2 and the transformer 3 may be substantially circular or substantially elliptical, but in this case as well, as described above, the user or the like is tentatively placed directly above the power conditioner 2 and the transformer 3. When standing and facing from the rear side to the front side, the "rear side", "front side", "right side" and "left side" of the power conditioner 2 and the transformer 3 are determined based on the user or the like.

The second feature of the power distribution system 1 according to the present invention is, in addition to the first feature, at least a cabinet 5 incorporating a control unit 4 for controlling the power conditioner 2, and at least the above in plan view. The cabinet 5 and the power conditioner 2 have a longitudinal direction, and the longitudinal direction of the cabinet 5 is at least substantially parallel to the longitudinal direction of the power conditioner 2.

The third feature of the power distribution system 1 according to the present invention is that, in addition to the above-mentioned first or second feature, the power conditioner 2 and the transformer 3 are arranged side by side in the vertical direction.

The fourth feature of the power distribution system 1 according to the present invention is that, in addition to the above-mentioned first to third features, all four-direction sides of the power conditioner 2 and / or the transformer 3 are sent to the outside of the system in a plan view. It is in the open point.

The fifth feature of the power distribution system 1 according to the present invention is, in addition to the above-mentioned first to fourth features, the power distribution system has a transformer output circuit that outputs an AC current transformed by the transformer 3 and this transformer output. It has a circuit breaker capable of blocking the electric circuit, and a plate-shaped member is arranged between the circuit breaker and the iron core and the coil of the transformer 3.

The sixth feature of the power distribution system 1 according to the present invention is that, in addition to the above-mentioned first to fifth features, the power distribution system has a transformer output circuit that outputs an AC current transformed by the transformer 3 and this transformer output. It has a circuit breaker capable of blocking the electric circuit, and the distance between the circuit breaker and the iron core and the coil of the transformer 3 is 30 cm or less.

The seventh feature of the power distribution system 1 according to the present invention is, in addition to the above-mentioned first to sixth features, the power distribution system includes a transformer output circuit that outputs an AC current transformed by the transformer 3 and this transformer output. It has a circuit breaker capable of blocking the electric circuit, and the circuit breaker and the iron core and the coil of the transformer 3 are arranged inside the same cover body.

The eighth feature of the power distribution system 1 according to the present invention is a power conditioner 2 that converts a DC current or an AC current from the outside of the system into an AC current, and a transformer 3 that transforms the AC current from the power conditioner 2. The distribution system has a transformer output circuit that outputs an alternating current transformed by the transformer 3 and a breaker that can cut off the transformer output circuit, and the breaker and the above. The iron core and coil of the transformer 3 are located inside the same cover body.
The ninth feature of the power distribution system 1 according to the present invention is that, in addition to the seventh or eighth feature, a heat shield plate is arranged between the circuit breaker and the iron core and coil of the transformer 3. At the point.

Due to these features, unlike Patent Document 1, the power conditioner 2 and the transformer 3 are built in in the first place by opening the three-direction sides of the power conditioner 2 and the transformer 3 to the outside of the system in a plan view. Since there is no board itself and most of the members are open to the outside of the system, it is naturally difficult for heat to be trapped, and at the same time, the number of members is reduced by the amount that equipment such as a circuit breaker as in Patent Document 1 is unnecessary. It is possible (both "improvement of member cooling performance" and "reduction of the number of parts").

Further, by making the longitudinal direction L of the cabinet 5 incorporating the control unit 4 such as the power conditioner 2 substantially parallel to the longitudinal direction L'of the power conditioner 2 or the like in a plan view, the front and rear of the overall shape of the power distribution system 1 If the length becomes shorter (that is, it becomes thinner), and if the rear surface of the power distribution system 1 is attached to the wall surface of a building such as a factory, office, or store, or if it follows the wall surface, the protrusion from the wall surface or the like is suppressed. It is unlikely to interfere with traffic (“suppression of obstruction such as traffic”).
At the same time, in the thin power distribution system 1, it can be said that the exposed front surface is widened and maintenance is easy (“improvement of maintainability”).

Further, by arranging the power conditioner 2 and the transformer 3 side by side in the vertical direction, the flat space occupied by the power distribution system 1 can be reduced, and further "suppression of obstruction such as passage" can be achieved.
At the same time, it can be said that it becomes easy to open the four-direction sides of the side surface portions of the power conditioner 2 and the transformer 3 having a large heat generation amount at the same time.

Then, in a plan view, by opening all four directions of the power conditioner 2 and the transformer 3 to the outside of the system, further "improvement of member cooling performance" can be achieved.
In the present invention, "opening all four directions to the outside of the system" means that the member supporting the power conditioner 2 and the transformer 3 and the like is a power distribution frame frame 6 and the like. It can be said that the surface of the transformer 3 or the like in the direction attached to the distribution frame frame 6 or the like can also be opened to the outside of the system from between the distribution frame frame 6 or the like.

In addition, a circuit breaker W (a circuit breaker 25'described later) capable of cutting off a transformer output circuit V (transformer output circuit 3e described later, a branch circuit 25, etc.) that outputs an AC current transformed by the transformer 3 and a control A circuit breaker 35 or the like for a part, so to speak, a cabinet provided with a plate-shaped member P (transformer output circuit breaker W inside) between the so-called transformer output circuit breaker W) and the iron core (core) and coil of the transformer 3. (Box body) 5 itself, a plate-shaped member constituting the cabinet 5, a cover body 3Q itself of the transformer 3, a plate-shaped member constituting the cover body 3Q, a heat shield plate 3g, a mounting plate 3h, etc., which will be described later. So-called intermediate plate-shaped member P) is arranged, and the distance (so-called circuit breaker-circuit breaker / coil distance) α between the transformer output circuit breaker W and the iron core and coil of the transformer 3 is 30 cm or less. Alternatively, by arranging the transformer output circuit breaker W and the iron core and coil of the transformer 3 inside the same cover body 3Q (transformer cylinder body 3a, upper lid 3c, base 3f, etc., which will be described later), each of them in the power distribution system 1 It can be said that the devices can be easily connected, and wiring can be simplified and costs can be reduced. In particular, when the transformer output circuit breaker W is intentionally arranged inside the cover body 3Q which is the same as the iron core and the coil whose surface tends to be hot, the transformer output circuit V from the coil of the transformer 3 (for example, which will be described later). It is not necessary to cover the iron core / coil-circuit breaker cable V'etc. with a connection plug or an insulator, and it is possible to directly conduct the transformer output circuit breaker W. Therefore, the transformer and the transformer of the transformer 3 are transformed. The connection with the output circuit breaker W becomes easier, and of course, the wiring becomes simpler, and the cost is further reduced because there is no need to cover it with a connection plug or an insulator. Since there is no transformer output circuit breaker W outside 3Q, it can be said that the space of the power distribution system 1 as a whole can be saved.
In addition, a heat shield plate 3g may be arranged between the transformer output circuit breaker W and the iron core and coil of the transformer 3, and in this case, it is the same as the transformer output circuit breaker W and the iron core and coil of the transformer 3. It can be said that the influence on the transformer output circuit breaker W can be reduced even if it is arranged inside the cover body 3Q or the circuit breaker-iron core / coil distance α is 30 cm or less.

The power plant 21 according to the present invention is a power plant having the above-mentioned power distribution system 1 and connection units 22 connected to the system K and the load F, respectively, and the power generation unit 26 is connected to the power distribution system 1 via the power distribution system 1. The first feature is that it is connected to the load F.

Due to this feature, in the power generation plant 21, by connecting the power generation unit 26 to the load F via the power distribution system 1, the power generated from the power generation unit 26 can be immediately supplied to the load F, and the loss is reduced.
It can be said that such a power generation plant 21 is a "self-consumption type power plant" suitable for consuming the electric power generated by the user of the plant 21 by itself.

The transformer 3 according to the present invention is a transformer that transforms an AC current, and the transformer can cut off an electric circuit conducting with the iron core and coil of the transformer, this electric circuit, and this transformer output electric circuit. The first feature is that it has a breaker, and the breaker and the iron core and the coil of the transformer are arranged inside the same cover body.

With this feature, it is possible to cut off the electric circuit (transformer output electric circuit 3e described later and the transformer output electric circuit V that outputs the AC current transformed by the transformer 3 such as the branch electric line 25) that is conductive with the iron core 3X and the coil 3Y of the transformer 3. Circuit breaker W (circuit breaker 25'for wiring described later, circuit breaker 35 for control unit, etc.) and the iron core 3X and coil 3Y of the transformer 3 are covered with the same cover body 3Q (transformer cylinder body 3a and upper lid described later). By arranging it inside 3c, base 3f, etc.), it can be said that when used in the power distribution system 1 or the power generation plant 21, each device can be easily connected, and wiring can be simplified and costs can be reduced.
It can be said that such a transformer 3 is a "self-consumption type transformer" suitable for consuming the electric power generated by the user of the transformer 3 by himself / herself.

The cabinet 5 according to the present invention is a cabinet incorporating at least a control unit 4 for controlling an external power conditioner, and the cabinet does not have a built-in circuit breaker capable of interrupting an electric circuit, or the circuit breaker. The first feature is that only one is built-in.

Due to this feature, the number of circuit breakers built in the cabinet 5 and capable of blocking the electric circuit can be set to 0 or only 1 (for example, only the circuit breaker 35 for the control unit described later) to distribute power. When used in the system 1 or the power plant 21, it can be said that each device can be easily connected, wiring can be simplified, costs can be reduced, and the cabinet 5 itself can be miniaturized.
It can be said that such a cabinet 5 is a cabinet (box) incorporating the above-mentioned control unit 4, and is a "self-consumption type" suitable for consuming the electric power generated by the user of the cabinet 5 by himself / herself. It can be said that it is a control box (control cabinet).

According to the power distribution system, power plant, transformer, and cabinet according to the present invention, by opening the three-direction side of the power conditioner and the transformer to the outside of the system, "improvement of member cooling performance" and "members" It is possible to achieve both "reduction of the number" and the like.

It is a top view which shows the power distribution system (the state which removed the roof material) which concerns on 1st Embodiment of this invention. It is a front view which shows the power distribution system which concerns on 1st Embodiment. It is a right side view which shows the power distribution system which concerns on 1st Embodiment. It is a left side view which shows the power distribution system which concerns on 1st Embodiment. It is a plan perspective view of the cabinet used for the power distribution system which concerns on 1st Embodiment. It is a front perspective view of the cabinet (the state which opened and closed doors are removed) of 1st Embodiment. It is a right side perspective view of the cabinet of 1st Embodiment. It is a left side perspective view of the cabinet of 1st Embodiment. It is a drawing substitute photograph which illustrates the power distribution system (integrated type) which concerns on 2nd Embodiment of this invention, the transformer which concerns on this invention used in this system, and the cabinet which concerns on this invention. (A) is a perspective view showing a power distribution system (with a cabinet removed) according to a second embodiment and a transformer according to the present invention used in this system, and (b) is a perspective view showing a transformer according to the present invention. (C) is a simulated perspective view showing the surface temperature distribution of the iron core and the coil of the transformer according to the present invention, and (d) is a perspective perspective view showing the inside of the transformer according to the present invention. It is a simulation cross-sectional view which shows the temperature distribution. (A) is a perspective perspective view showing the transformer and the opening state according to the present invention, and (b) is a perspective perspective view showing the upper part (around the upper lid) of the cover body in the transformer according to the present invention. ) Is a perspective view showing the lower part (periphery of the base) of the cover body in the transformer according to the present invention. (A) is a simulation cross-sectional view showing the power distribution system (with the cabinet removed) according to the second embodiment and the temperature distribution inside the transformer according to the present invention used in this system, and (b) is a simulation cross-sectional view. It is a simulation plan sectional view which shows the wind velocity vector distribution in the transformer which concerns on this invention, and (c) is the simulation side sectional view which shows the wind velocity vector distribution in the transformer which concerns on this invention. Simulation surface temperature distribution diagram of a transformer cover body according to the present invention, and a circuit breaker (transformer output circuit breaker) and a plate-shaped member (intermediate plate-shaped member such as a heat shield plate and a mounting plate) inside the cover body. The positional relationship between the circuit breaker, the plate-shaped member, the iron core, the coil, etc. inside the cover body of the transformer according to the present invention is shown, and in (a), the distance between the circuit breaker and the heat shield plate is 3.5 cm. (B) shows the case where the heat shield plate and the iron core, the coil, etc. are separated by 5 cm from the case of (a), and (c) shows the case where the circuit breaker and the mounting plate are separated from the case of (b). The case where and is separated by 1 cm is shown. It is a drawing substitute photograph which illustrates the appearance and outline of the cabinet which concerns on this invention. It is a drawing substitute photograph which illustrates the inside of the cabinet which concerns on this invention. It is a drawing substitute photograph which illustrates the power distribution system (split type) which concerns on 3rd Embodiment of this invention, and this system includes the transformer which concerns on this invention, and the cabinet which concerns on this invention. Is shown. It is a schematic diagram which shows the power plant which concerns on 1st Embodiment of this invention. It is a circuit diagram which shows the power plant which concerns on 1st Embodiment (the state which used the power distribution system which concerns on 1st Embodiment). It is a schematic diagram which shows the power plant which concerns on 2nd Embodiment of this invention. It is a circuit diagram which shows the power plant which concerns on 2nd Embodiment (the state which used the power distribution system which concerns on 2nd Embodiment). It is a schematic diagram which shows the power plant which concerns on 3rd Embodiment of this invention. It is a circuit diagram which shows the power plant which concerns on 3rd Embodiment (the state which used the power distribution system which concerns on 1st Embodiment).

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
<Overall configuration of the power distribution system 1 of the first embodiment>
FIGS. 1 to 8 and 17 to 22 show the power distribution system 1 according to the first embodiment of the present invention.
The power distribution system 1 has a power conditioner 2 and a transformer 3, which will be described later.
The power distribution system 1 also has members (such as a power distribution frame frame 6 to be described later) that support these power conditioners 2 and transformers 3.

The power distribution system 1 may have a control unit 4 and a cabinet 5, which will be described later, or an electric device 11.
In the power distribution system 1, a power conditioner 2 and a transformer 3 are attached to supporting members such as a power distribution frame frame 6, and a control unit 4 and an electric device 11 and the like built in a cabinet 5 described later are provided. You may be.

The power distribution system 1 may have a small front-rear length (depth) value (even if it is thin), and the specific front-rear length value of such a power distribution system 1 is not particularly limited, but for example, It may be 300 mm or more and 1500 mm or less, preferably 400 mm or more and 1200 mm or less, and more preferably 500 mm or more and 1000 mm or less (700 mm or the like).
Furthermore, since the back side of the power distribution system 1 (power distribution frame frame 6 etc.) is substantially flush with each other, no space is required on the back side and the power distribution system 1 (power distribution frame frame 6 etc.) is installed as close as possible to the wall surface (outer wall etc.) of the factory or building. It can be said that it can be done.

Further, the power distribution system 1 may have a lower vertical length (height), and the specific vertical length of such a power distribution system 1 is not particularly limited, but is, for example, 2500 mm or less (900 mm or more and 2500 mm or less). ), It may be preferably 2300 mm or less (900 mm or more and 2300 mm or less), and more preferably 2100 mm or less (1200 mm or more and 2100 mm or less, 1980 mm, etc.).
The power distribution system 1 may be provided with a plurality of power distribution systems 1 dispersed in one photovoltaic power generation device 23'(below the solar cell 26', etc.).

<Power conditioner 2>
As shown in FIGS. 1 to 8 and 17 to 22, the power conditioner 2 includes a direct current from the outside of the power distribution system 1 such as the power generation unit 26 (solar cell 26') described later, and an alternating current motor of the wind power generation device. This is a device that converts AC current from the above into AC power that matches the voltage and phase of the system K and outputs it.
The power conditioner 2 is an inverter device that converts a direct current or the like from a solar cell 26'or the like into an alternating current (for example, 100 V or more and 600 V or less) and a control that controls the voltage and frequency of the alternating current converted by this inverter device. A unit and an aerial circuit breaker (ACB) or the like may be provided.

In the power conditioner 2, the housing in which the inverter device, the control unit, the circuit breaker, and the like are built may be provided with a rotating fan-shaped air blowing means for releasing the air inside the power conditioner 2.
In addition, such a power conditioner 2 is also referred to as a power conditioner 2 for short.

The power conditioner 2 is controlled so as to limit (suppress) the power generation H output from the power conditioner 2 to a predetermined value (target upper limit value or the like) by a signal from the control unit 4 described later. (So to speak, "a signal from the electric device 11 or the like may be configured to stop the conversion in the power conditioner 2 (by stopping the conversion in this way, the power generation H is output from the power conditioner 2". It can be said that it will disappear).
As described above, the number of power conditioners 2 may be one or more in one power distribution system 1.
When there are a plurality of power conditioners 2, when the conversion of the power conditioner 2 is stopped by the signal from the electric device 11 or the like described above, the conversion of all the power conditioners 2 may be stopped at once. Then, first, the conversion of at least a part of the power conditioner 2 may be stopped.

The power conditioner 2 is installed in the power distribution frame frame 6 or the like of the power distribution system 1 in a state of being built in a housing (power conditioner housing) different from the members supported by the power distribution system 1, or the power conditioner 2. When built in a housing, a plurality of power conditioner housings (that is, power conditioners 2) are distributed and provided in one photovoltaic power generation device 23'(below the solar cell 26', etc.). May be provided separately.
The power conditioner 2 may be attached to the power distribution frame frame 6 or the like at the site where the power distribution system 1 is installed.

<L of the power conditioner 2 in the longitudinal direction, etc.>
As shown in FIGS. 1 to 4, the longitudinal direction L of the power conditioner 2 is the direction from the left side to the right side of the power conditioner 2 (that is, the "left-right direction" in the plan view of the power distribution system 1 (power conditioner 2). It can be said that.
It can be said that the plan view shape of the power conditioner 2 is a substantially rectangular shape that is long (horizontally long) in the left-right direction.

The plan view shape of the power conditioner 2 is other than the horizontally long substantially rectangular shape, and even if the corners of the rectangle are rounded or have rounded corners, if the longitudinal direction L exists in those plan view shapes. In addition, when the plan view shape of the power conditioner 2 is substantially elliptical, it can be said that the major axis direction is the longitudinal direction L.
The power conditioner 2 may have a small front-rear length (depth) value (even if it is thin) as well as horizontally long, and the specific front-rear length value of such a power conditioner 2 is Although not particularly limited, for example, it may be 100 mm or more and 1000 mm or less, preferably 150 mm or more and 700 mm or less, and more preferably 200 mm or more and 500 mm or less (about 330 mm or the like).

Further, the vertical length (height) of the power conditioner 2 may be set to a low level, and the specific vertical length of the power conditioner 2 is not particularly limited, but is, for example, 1000 mm or less (200 mm or more). It may be 1000 mm or less), preferably 850 mm or less (300 mm or more and 850 mm or less), and more preferably 700 mm or less (400 mm or more and 700 mm or less, about 550 mm, etc.).
A plurality of power conditioners 2 may be provided in one power distribution system 1.

<Transformer 3 of Example 1>
As shown in FIGS. 1 to 8 and 17 to 22, the transformer 3 used in the power distribution system 1 according to the first embodiment (so-called transformer 3 of the first embodiment) is one or more as described above. It is a device that transforms the alternating current from the power conditioner 2.
The transformer 3 may transform (step down) the alternating current from the power conditioner 2 to a lower voltage alternating current. In this case, the transformer 3 can be said to be a so-called step-down transformer.
The transformer 3 may have any configuration as long as it transforms the AC current in the distribution system 1 described above into a lower AC current. For example, the transformer 3 is a dry type and is covered with a transformer cylinder 3a having an open top and bottom. It may be attached to the power distribution frame frame 6 or the like. The transformer cylinder 3a is also a cover body 3Q (or a part of the cover body 3Q) in the power distribution system 1 according to the second embodiment of the present invention and the transformer 3 according to the present invention, which will be described later. I can say.

The fact that the transformer 3 is dry means that there is no oil (insulating oil) inside, and even with this, the rear surface of the power distribution system 1 is attached to the wall surface of a building such as a factory, office, or store. It can be said that it can be done.
The transformer cylinder 3a of the transformer 3 has a substantially rectangular shape in a plan view, and an iron core (core), a coil, a terminal, and the like are arranged therein. It can be said that the iron core, the coil, the terminal, and the like are the power distribution system 1 according to the second embodiment of the present invention described later, the iron core 3X, the coil 3Y, and the like in the transformer 3 according to the present invention.

The lower part of the front surface of the transformer cylinder 3a is notched so as to open in a substantially rectangular shape even when the transformer 3 (distribution system 1) is installed (the notch 3b is formed), and the transformer 3 has a notch 3b. Even after installation, air can enter and exit the inside of the transformer cylinder 3a through the notch 3b.
On the other hand, the upper opening of the transformer cylinder 3a is covered with an upper lid 3c, which is a top plate having a substantially rectangular shape in a plan view and four side plates erected downward from each of the four sides of the top plate. It has (so-called eaves) (that is, it can be said to be a box with a shallow bottom that opens downward). It can also be said that the upper lid 3c is (or is a part of) the cover body 3Q in the power distribution system 1 according to the second embodiment of the present invention and the transformer 3 according to the present invention, which will be described later.

Here, even if the upper lid 3c of the transformer 3 covers the upper opening of the transformer cylinder 3a, the transformer cylinder 3a is formed from between the eaves portion of the upper lid 3c and the outer surface of the transformer cylinder 3a. Air can go in and out inside and outside.
Therefore, in the transformer 3, the air flowing into the transformer cylinder 3a from the lower part through the notch 3b described above is warmed by the heat generated by the iron core and the coil of the transformer 3 and rises, and becomes the upper outer surface of the transformer cylinder 3a. It can be said that the iron core, the coil, and the like of the transformer 3 are cooled by the discharge from between the eaves of the upper lid 3c to the outside of the transformer cylinder 3a.

Since the eaves portion of the upper lid 3c is erected below the top plate, it is difficult for moisture to enter the inside of the transformer cylinder 3a even in rainy weather.
The upper lid 3c may be provided with a hanging member such as a hook or a ring that can be lifted by a crane or the like on the upper surface thereof. When the upper lid 3c covers the upper opening of the transformer cylinder 3a, the upper surface of the upper lid 3c may be tilted backward, tilted forward, or the like.

The transformer cylinder 3a of the transformer 3 may be provided with a cable hole 3d for drawing a cable in the lower rear portion of the side surface (right side surface) thereof.
Further, the transformer cylinder 3a of the transformer 3 may be provided with a cable hole 3d for drawing a cable in the lower part of the front surface thereof.

The transformer 3 is provided in the branch electric circuit 25 (the electric circuit between the load F and the power conditioner 2 or the electric circuit between the main electric circuit M and the power conditioner 2) as the whole power plant 21 described later. It can be said that it is.
The output from the transformer 3 (so-called power generation H) may be directly connected to the load F via a molded case circuit breaker (MCCB, simply referred to as a breaker). The circuit breaker for wiring has a power distribution system 1 according to a second embodiment of the present invention, which will be described later, and a transformer output circuit V that outputs an AC current transformed by the transformer 3 in the transformer 3 according to the present invention. It can also be said that the transformer output circuit breaker W can be cut off (or is one of the transformer output circuit breakers W).

The value of the voltage transformed by the transformer 3 is not particularly limited, but is, for example, a lower voltage suitable for the load F to consume an alternating current (for example, 100 V or more and 600 V or less) from outside the distribution system 1. It may be converted into an alternating current (for example, 200V or the like).
Such a transformer 3 may have a configuration in which, for example, a three-phase three-wire (3φ3W) input of 100V or more and 600V or less is stepped down to 200V or the like and output, and the step-down is performed. It can be said that the output three-phase three-wire power flows to the load F or the like via the branch electric circuit 25 described later. The branch electric circuit 25 is a power distribution system 1 according to a second embodiment of the present invention described later, or a transformer output electric circuit V that outputs an alternating current transformed by the transformer 3 in the transformer 3 according to the present invention. (Or, it is a part of the electric circuit V).

Here, the transformer 3 may be configured not only to output three-phase three-wires flowing through the branch electric circuit 25, but also to output a single-phase two-wire (1φ2W) at the same time. In this case, the three-phase transformer 3 may be configured. An input of 100 V or more and 600 V or less with three wires (3φ3W) may be stepped down to 105 V or the like with a single-phase two wire and output to the cabinet 5 described later via the cabinet electric circuit 3e. At the same time as the output of the three-phase three-wire to the branch electric circuit 25, the single-phase three-wire (1φ3W) may be output instead of the single-phase two-wire (1φ2W). It can be said that the cabinet electric circuit 3e is an electric circuit (from the transformer 3) that outputs the alternating current transformed by the transformer 3 to the cabinet 5. Further, the cabinet electric circuit 3e is also a power distribution system 1 according to a second embodiment of the present invention described later, and a transformer output electric circuit V that outputs an alternating current transformed by the transformer 3 in the transformer 3 according to the present invention. (Or, it is a part of the electric circuit V).
The capacity of the transformer 3 is also not particularly limited, but may be, for example, 1 kVA or more and 500 kVA or less, preferably 10 kVA or more and 200 kVA or less, and more preferably 20 kVA or more and 100 kVA or less.

<Vertical direction L of transformer 3 of Example 1 ">
As shown in FIGS. 1 to 4, the longitudinal direction L of the transformer 3 of the first embodiment is the plan view shape (substantially rectangular shape) of the transformer 3 in the plan view of the power distribution system 1 (transformer 3). Since the left-right length of the transformer 3 is longer than the front-back length (for example, the left-right length is about 720 mm and the front-back length is about 640 mm), the longitudinal direction L of the transformer 3 is the direction from the left side to the right side of the transformer 3. (That is, "left-right direction").
That is, in the plan view shape of the transformer 3, if the length in one direction is longer than the length in the other direction, the transformer 3 has the longitudinal direction L "in the plan view.
It can be said that the plan view shape of the transformer 3 is a substantially rectangular shape that is long (horizontally long) in the left-right direction.

It should be noted that the plan view shape of the transformer 3 is other than the horizontally long substantially rectangular shape, and even if the corners of the rectangle are rounded or have rounded corners, if the longitudinal direction L ”exists in those plan view shapes. In addition, when the shape of the transformer 3 in a plan view is substantially elliptical, it can be said that the major axis direction is the longitudinal direction L.
The transformer 3 may have a small front-rear length (depth) value (even if it is thin) as well as a horizontally long value, and the specific front-rear length value of such a transformer 3 is particularly high. Although there is no limitation, it may be, for example, 200 mm or more and 2000 mm or less, preferably 300 mm or more and 1500 mm or less, and more preferably 400 mm or more and 1000 mm or less (about 640 mm or the like).

Further, the transformer 3 may have a sufficient capacity while making the vertical length (height) lower depending on how the iron core is assembled, and the specific vertical length of such a transformer 3 is particularly high. Although there is no limitation, it may be, for example, 1500 mm or less (900 mm or more and 1500 mm or less), preferably 1400 mm or less (900 mm or more and 1400 mm or less), more preferably 1200 mm or less (95 mm or more and 1200 mm or less), and more preferably 1150 mm or less (1150 mm or less). It may be 950 mm or more and 1150 mm or less, 1100 mm, etc.).
A plurality of transformers 3 may be provided in one power distribution system 1.
The control unit 4 in the power distribution system 1 may control not only the power conditioner 2 described above but also the connection unit (system panel) 22 described later, and the control unit 4 controls the system K described later. Since the received power J received from the system board 22 and the generated power H output from the power generation plant 21 described later are used, the control unit 4 will be described later.

<Cabinet 5 of Example 1>
As shown in FIGS. 1 to 8, the cabinet 5 used in the power distribution system 1 according to the first embodiment (so-called cabinet 5 of the first embodiment) includes the control unit 4 mentioned above and the control unit 4 described later. It is a box body in which an electric device 11 or the like is provided inside.
In addition, the cabinet 5 includes a ground fault overvoltage relay (OVGR, Over Voltage Relay) 33, a wiring breaker (MCCB), a communication device (router, etc.) 36, an uninterruptible power supply (UPS) 37, an outlet 38, and the like. It may be held inside.

The ground fault overvoltage relay 33 may be connected to the main electric circuit M in the connection portion (system board) 22 described later via the zero phase detector (ZPD, Zero Phase potential Device) 22z. The outlet 38 may have any configuration, but may be, for example, a grounded square outlet.
A plurality of electric devices 11 and circuit breakers for wiring, which will be described later, may be provided inside one cabinet 5. For example, a plurality of electric devices 11 (for example, two, electric devices for reverse power, etc.) may be provided. 11 and the electric device for power generation 11), one electric device 11 may be an electric device for reverse power or the like, and the other electric device 11 may be an electric device for power generation. If there are a plurality of circuit breakers for wiring (for example, two circuit breakers 25'for the branch electric circuit 25 and a circuit breaker 35 for the control unit 4, etc.), one of them is from the transformer 3. The output three-phase three-wire (branch circuit breaker 25 described later) is cut off (it can be said that it is a power generation circuit breaker 25'), and the other is the one that cuts off the single-phase two-wire output from the transformer 3. Become. The wiring breaker 25'for the branch electric circuit 25 and the wiring breaker 35 for the control unit 4 and the like are the power distribution system 1 according to the second embodiment of the present invention and the transformer 3 according to the present invention, which will be described later. It can be said that it is a transformer output breaker W (or one of the transformer output breakers W) capable of cutting off the transformer output circuit V that outputs the AC current transformed by the transformer 3 in the above.
Further, the cabinet (box body) 5 itself provided with such a transformer output circuit breaker W and the plate-shaped members constituting the cabinet 5 are, of course, the transformer output circuit breaker W and the iron core and coil of the transformer 3. Since it exists (is arranged) between (iron core 3X and coil 3Y) and the like, the intermediate plate-shaped member in the power distribution system 1 according to the second embodiment of the present invention and the transformer 3 according to the present invention will be described later. It can also be said that it is P (or is a part of the intermediate plate-shaped member P).
Further, the distance between the transformer output circuit breaker W provided inside the cabinet 5 and the iron core and coil (iron core 3X and coil 3Y) of the transformer 3 relates to the second embodiment of the present invention described later. It can be said that the circuit breaker-iron core / coil distance α in the power distribution system 1 is set.
Here, if the cabinet 5 and the transformer 3 described above are supported from the rear side by the distribution frame frame 6 described later together with the power conditioner 2 described above (if they are integrated), of course, the cabinet The distance between the 5 and the transformer 3 and the like (distance between the circuit breaker, the iron core, the coil distance α, etc.) is always equal to or less than a predetermined value (so to speak, they exist in the vicinity of each other).
That is, if the cabinet 5 and the transformer 3 are close to each other, the circuit breaker W provided inside the cabinet 5 and the circuit breaker between the iron core 3X and the coil 3Y of the transformer 3-. Naturally, the iron core / coil distance α is also equal to or less than a predetermined value. For example, the circuit breaker-iron core / coil distance α is 30 cm (300 mm) in any one of the side view and the front view of the power distribution system 1. It may be 1 cm or more and 30 cm or less (10 mm or more and 300 mm or less), preferably 3 cm or more and 24 cm or less (30 mm or more and 240 mm or less), and more preferably 6 cm or more and 18 cm or less (60 mm or more and 180 mm or less). More specifically, it can be said that 8.5 cm, 13.5 cm, 14.5 cm, or the like may be used.

The cabinet 5 has an opening / closing door 5a on the front surface thereof, and the structure of the opening / closing door 5a is a single door that opens sideways (left opening (when the shaft is on the right side and opens from the left side of the opening / closing door) or right. It may open (open) or vertically (particularly, open upward), and may have two doors and double doors, or three or more doors.
The arrangement of each device inside the cabinet 5 is not particularly limited, but for example, the control unit 4 and the electrical device 11 (display unit and operation unit of the device housing 14) are on the front side (opening / closing door 5a side). ) It may be arranged closer to each other. In this case, when the opening / closing door is opened, the control unit 4 and the electric device 11 come in front of the user and the like, so that the control unit 4 and the electric device 11 can be operated and the electric machine can be operated. It can be said that the display unit 14a of the vessel 11 and the like can be easily visually recognized. The plate material that supports the two electric devices 11 and the one ground fault overvoltage relay 33 may be rotatable around the vertical axis (see the alternate long and short dash line in FIG. 5).

On the other hand, inside the cabinet 5, the molded case circuit breaker or the like may be arranged as close to the rear side (the side away from the opening / closing door 5a) as much as possible. It can be said that this is to make it difficult to accidentally contact the door.
Even if the molded case circuit breaker is placed on a support stand or the like near the front side (opening / closing door 5a side) to the minimum that can be operated, the front surface of the molded case circuit breaker is covered with a plate material or the like, and only the operation lever May be configured to be exposed from the opening.

<Cabinet 5 of Example 1 in the longitudinal direction L'>
As shown in FIGS. 1 to 8, the longitudinal direction L'of the cabinet 5 is the direction from the left side to the right side of the cabinet 5 (that is, the "left-right direction") in the plan view of the power distribution system 1 (cabinet 5). It can be said that there is.
It can be said that the plan view shape of the cabinet 5 is a substantially rectangular shape (horizontally long) long in the left-right direction.

The plan view shape of the cabinet 5 is other than the horizontally long substantially rectangular shape, and even if the corners of the rectangle are rounded or have rounded corners, it is sufficient that the longitudinal direction L exists in those plan view shapes. In addition, when the plan view shape of the cabinet 5 is substantially elliptical, it can be said that the major axis direction is the longitudinal direction L.
The cabinet 5 may have a small front-rear length (depth) value (even if it is thin) as well as a horizontally long one, and the specific front-rear length value of such a power conditioner 2 is particularly high. Although there is no limitation, it may be, for example, 50 mm or more and 1000 mm or less, preferably 100 mm or more and 700 mm or less, and more preferably 150 mm or more and 500 mm or less (300 mm or the like).

Further, the cabinet 5 may have a lower vertical length (height), and the specific vertical length of such a cabinet 5 is not particularly limited, but is, for example, 1200 mm or less (300 mm or more and 1200 mm or less). It may be 1000 mm or less (400 mm or more and 1000 mm or less), and more preferably 900 mm or less (500 mm or more and 900 mm or less, 700 mm, etc.).
A plurality of cabinets 5 may be provided in one power distribution system 1.

<Power distribution frame Frame body 6>
As shown in FIGS. 1 to 4, the power distribution frame frame body 6 is a member that supports the above-mentioned power conditioner 2, the transformer 3, and the cabinet 5 from the rear side.
The power distribution frame frame 6 may have any configuration as long as it can support the power conditioner 2, the transformer 3, and the cabinet 5 from the rear side. For example, the power distribution frame frame 6 has a pair of left and right pillar members. 6a, 6b, the upper beam member 6c and the lower beam member 6d passed between the left and right column members 6a, 6b, and the upper ends of the left and right column members 6a, 6b passed between the left and right column members 6a, 6b. It may have a roof material 6e attached to the portion and a cabinet support member 6f attached to either the left or right pillar material 6a or 6b (for example, the right pillar material 6b) and supporting the cabinet 5.

<Left and right pillar materials 6a, 6b>
As shown in FIGS. 1 to 4, in the pair of left and right pillar members 6a and 6b, the front sides of the left and right pillar members 6a and 6b are attached to the left and right ends on the rear surface of the transformer 3 described above.
The transformer 3 is supported from the rear side by the left and right pillar members 6a and 6b, and the left and right pillar members 6a and 6b are attached to the rear side of the heaviest transformer 3 in the power distribution system 1. It can be said that the power distribution frame frame body 6 including the pillar members 6a and 6b of the above supports other power conditioners 2, cabinets 5, and the like.
The shapes and configurations of the left and right pillar members 6a and 6b are not particularly limited, but for example, the cross-sectional shape may be a rectangular column having a substantially rectangular shape or a substantially square shape, or the cross-sectional shape may be a substantially circular shape or a substantially elliptical shape. It may be a round columnar shape or the like.

If the left and right pillar members 6a and 6b are round pillars, it can be said that they can be attached to the transformer 3 or the like via a fixture or the like.
Hereinafter, the left and right pillar members 6a and 6b will be mainly described as prismatic.
The left and right pillar members 6a and 6b may be hollow or solid.

The left and right pillar materials 6a and 6b may have members connecting the left and right pillar materials 6a and 6b in addition to the upper beam material 6c, the lower beam material 6d and the roof material 6e, but the rear side of the transformer 3 It can be said that the left and right pillar members 6a and 6b are separated from each other and are open.
As a result, it can be said that most of the rear surface of the transformer 3 is also exposed and is open to the outside of the system in a plan view.

Further, the left and right outer surfaces (right surfaces) of the right pillar member 6b may be substantially flush with the right surface of the transformer cylinder 3a of the transformer 3 described above. Similarly, the left and right outer surfaces (left surface) of the left column member 6a are substantially flush with the left surface of the transformer cylinder 3a of the transformer 3 described above, and the lower surfaces of the left and right column members 6a and 6b are described above. It may be substantially flush with the lower surface of the transformer cylinder 3a of the transformer 3.
The left and right pillar members 6a and 6b have shorter front-rear lengths (thinner thickness) so as to avoid the eaves portion of the upper lid 3c protruding rearward in the transformer 3 in the middle of the vertical direction. It can be said that the thicknesses of the left and right pillar members 6a and 6b are kept thin even at a position higher than the eaves portion of the upper lid 3c.

<Upper beam material 6c and lower beam material 6d>
As shown in FIGS. 1 to 4, in the upper beam member 6c and the lower beam member 6d, the rear surface of the upper beam member 6c and the lower beam member 6d is placed on the upper part of the front surface of the left and right column members 6a and 6b described above. It is attached.
The shapes and configurations of the upper beam member 6c and the lower beam member 6d are not particularly limited, but for example, the cross-sectional shape of the upper beam member 6c is a bar member having a substantially U-shaped cross section, or a prismatic shape having a substantially rectangular shape or a substantially square shape. It may be a round column having a substantially circular shape or a substantially elliptical cross-sectional shape, a plate material, a hollow shape, or a solid shape.

If the upper beam member 6c and the lower beam member 6d are round columns, it can be said that they can be attached to the left and right column members 6a, 6b, etc. via a fixture or the like.
Further, if the upper beam member 6c and the lower beam member 6d are in the shape of a bar having a substantially U-shaped cross section, the open portion may be located below (lower opening) in a substantially U-shaped cross-sectional view. It may be located above (or open upward).

Hereinafter, the upper beam member 6c and the lower beam member 6d will be described mainly as a bar having a substantially U-shaped cross section with a downward opening.
In this case, in the substantially U-shaped cross section of the upper beam member 6c and the lower beam member 6d, the portion (plate material) located at the rear is fixed to the front surface of the left and right column members 6a and 6b, and the portion (plate material) located at the front. Is fixed to the rear surface of the power conditioner housing of the power conditioner 2 to support the power conditioner 2 from the rear side.

<Roofing material 6e>
As shown in FIGS. 1 to 4, in the roofing material 6e, the lower surface side of the roofing material 6e is attached to the upper surface or the like at the upper ends of the left and right pillar materials 6a and 6b described above.
The shape and configuration of the roofing material 6e are not particularly limited, but for example, if the size is such that rainwater or the like in rainy weather can be suppressed from being applied to the power conditioner 2 or the transformer 3, the plan view shape is omitted. It may have a rectangular plate shape, or may have a plate shape such as a substantially elliptical shape, a substantially square shape, or a substantially circular shape in a plan view.

Hereinafter, the roofing material 6e will be described mainly as a plate having a substantially rectangular shape in a plan view.
The left and right ends of the lower surface of the roofing material 6e may be directly attached to the upper surfaces of the left and right pillars 6a and 6b, but the roofing material 6e is attached to the left and right pillars 6a and 6b via a rod body. It may have been done.
Further, between the roof material 6e and the left and right pillar materials 6a and 6b, a substantially trapezoidal vertical plate material is substantially along the longitudinal direction in the front-rear direction and the thickness direction of the plate material is approximately left and right. It may be provided alongside the above-mentioned rod body (with the board standing vertically).

The roofing material 6e may be inclined forward or backward, or may be substantially horizontal.
On the upper surface of the roofing material 6e, a plurality of grooves (for example, a tile-like groove) are formed in a direction substantially orthogonal to the inclination direction so that moisture can easily flow in rainy weather, or the roofing material 6e is inclined. A gutter member may be provided on the lower side.

<Cabinet support material 6f>
As shown in FIGS. 1 to 4, the cabinet support member 6f is, for example, substantially flush with the left and right outer side (right side) of the right pillar material 6b among the left and right pillar materials 6a and 6b described above. The left side of the cabinet support member 6f is attached to the right side of the transformer cylinder 3a of a certain transformer 3.
The shape and configuration of the cabinet support member 6f is not particularly limited, but for example, it is a member mainly composed of one or a plurality of plate members having a substantially L-shape in a plan view, and other members having a substantially L-shape in a plan view. It may be a pair of rods or pillars.

Hereinafter, the cabinet support member 6f will be described as a member mainly composed of one or a plurality of plate members having a substantially L-shape in a plan view.
The cabinet support member 6f has one or a plurality of plate members having a substantially L-shape in a plan view, and a horizontal plate material having a substantially right-angled triangular shape in a plan view. It is in contact with one plate part, and the other side sandwiching the right angle is in contact with the other plate part of approximately L shape (with the plate stretched sideways), approximately L shape. It may be attached to the plate material of.

In the cabinet support member 6f, the left surface of one plate material portion having a substantially L shape is fixed to the right surface of the right pillar material 6b and the right surface of the transformer cylinder 3a of the transformer 3, and the other plate material portion having a substantially L shape is formed. The front surface is fixed to the rear surface of the cabinet 5 to support the cabinet 5 from the rear side.
The cabinet support member 6f (and cabinet 5) may be attached to the power distribution system 1 (transformer 3 or the like) upside down.

<Opening of the power conditioner 2 and transformer 3 on the three-way side, etc.>
As shown in FIGS. 1 to 4, the power conditioner 2 and the transformer 3 whose rear side is supported by the distribution frame frame 6 described so far are the power conditioner 2 and the transformer in a plan view. At least three directions of 3 are open to the outside of the system.
Here, "open to the outside of the system" in the present invention means, for example, whether the rear side is open to the outside of the system means that more than half of the power conditioner 2 and the transformer 3 are exposed from the rear side. For example (if the user or the like can see more than half of the power conditioner 2 or the transformer 3 or the like when the user or the like looks at the power conditioner 2 or the transformer 3 or the like from the rear side), the power conditioner or the like. It can be said that the rear side of 2 and the transformer 3 is open to the outside of the system.

Similarly, if more than half of the power conditioner 2 and the transformer 3 are exposed in the front side, the left side, and the right side in the front side view, the left side view, and the right side view, the power conditioner 2 and the transformer 3 and the like are ". The front side, left side, and right side are open to the outside of the system. "
Therefore, on the four-direction side of the power conditioner 2, the transformer 3, etc., a part of them is hidden by other members (the distribution frame frame 6 or the transformer 3 and the cabinet 5 are hidden from each other. Even if it is hidden by, etc.), if there are fewer hidden parts, it can be said that there is no problem in cooling the power conditioner 2 and transformer 3, and "it is open to the outside of the system."".

In the power distribution system 1 illustrated in FIGS. 1 to 4, it can be said that the power conditioner 2 is open to the outside of the system in all four directions, and the transformer 3 is the front side, the left side, and the rear side of the four directions. It can be said that the side is open to the outside of the system.
If the cabinet 5 is also mentioned, it can be said that the front side and the right side of the cabinet 5 are open to the outside of the system in the four directions, but the equipment in the cabinet 5 is more than the power conditioner 2 or the transformer 3. It can be said that there is no problem because the amount of heat generated is small.

If the power conditioner 2 and the transformer 3 are arranged upside down, it can be said that the front side, the left side, and the rear side of the power conditioner 2 are open to the outside of the system in the four directions. In 3, it can be said that all four directions are open to the outside of the system.
Further, if the cabinet 5 is not provided or the cabinet 5 is arranged above the power conditioner 2 and the transformer 3, the power conditioner 2, the transformer 3 and the cabinet 5 are all on the four-direction side. Can be said to be open to the outside of the system.

<Approximately parallel to the power conditioner 2 and cabinet 5 in the longitudinal direction>
As shown in FIGS. 1 to 4, the longitudinal direction L and the like of the cabinet 5 described above may be substantially parallel to the longitudinal direction L'and the like of the power conditioner 2.
Here, "a certain longitudinal direction is substantially parallel to another longitudinal direction" in the present invention means whether or not it is substantially parallel in a three-dimensional space, for example, the longitudinal direction L of the cabinet 5 and the power. When the longitudinal direction L'of the conditioner 2 is considered to be "left-right direction", the two longitudinal directions L and L in the front view (front view) or the rear view (rear view) of the cabinet 5 and the power conditioner 2 'Is substantially parallel (appears to be approximately parallel depending on the user or the like), and the two longitudinal directions L and L'in the top view (plan view) or bottom view (bottom view) of the cabinet 5 and the power conditioner 2. If is substantially parallel (it looks substantially parallel depending on the user or the like), the longitudinal direction L of the cabinet 5 and the longitudinal direction L'of the power conditioner 2 are in the "left-right direction" even in the three-dimensional space. It can be said that they are almost parallel.

Similarly, if the longitudinal directions L and L'of the cabinet 5 and the power conditioner 2 are both considered to be "front-rear direction", there are two in the left side view or the right side view in the cabinet 5 and the power conditioner 2. If the longitudinal directions L and L'are substantially parallel and the two longitudinal directions L and L'are substantially parallel in the top view or the bottom view of the cabinet 5 and the power conditioner 2, the power condition is substantially parallel to the cabinet 5. It can be said that the longitudinal directions L and L'of the na 2 are substantially parallel in the "front-back direction" even in the three-dimensional space.
If the longitudinal directions L and L'of the cabinet 5 and the power conditioner 2 are both considered to be "vertical", the cabinet 5 and the power conditioner 2 have two longitudinal directions in the left side view or the right side view. If the directions L and L'are substantially parallel and the two longitudinal directions L and L'are approximately parallel in the front view or the rear view of the cabinet 5 and the power conditioner 2, the cabinet 5 and the power conditioner 2 are substantially parallel. It can be said that the longitudinal directions L and L'of 2 are substantially parallel in the "vertical direction" even in the three-dimensional space.

In the power distribution system 1 illustrated in FIGS. 1 to 4, all three of the cabinet 5, the power conditioner 2, and the transformer 3 in the longitudinal directions L, L', and L "are in the" horizontal direction "even in the three-dimensional space. It can be said that they are almost parallel.
Further, if at least two of the three cabinets 5, the power conditioner 2 and the transformer 3 in the longitudinal direction L, L', L "are substantially parallel to each other, the distribution system 1 as a whole contributes to thinning. It can be said that it is doing.

<Upper and lower arrangement of power conditioner 2 and transformer 3 etc.>
As shown in FIGS. 1 to 4, the above-mentioned power conditioner 2 and transformer 3 and the like may be arranged side by side in the vertical direction.
Here, "arranged side by side in the vertical direction" in the present invention means whether or not there is an overlapping portion of at least a part of the power conditioner 2 and the transformer 3 in a plan view.

Even if at least a part of the power conditioner 2 and the transformer 3 overlap in at least one of the front view, the left and right side view, and the rear view, the power conditioner 2 and the power conditioner 2 are used in a plan view. If at least a part of the transformer 3 or the like overlaps with each other, the power conditioner 2 and the transformer 3 or the like are arranged side by side in the vertical direction in the overlapping part in the plan view, and the other parts overlap in the vertical direction. Even if there are parts that are not arranged side by side, at least the heights of the power conditioner 2 and the transformer 3 (for example, the height of the center of gravity of each) are different, so they overlap in a directional view other than the plan view. Even if there are parts, it can be said that it can be determined whether or not they are "arranged side by side in the vertical direction" only by whether or not there are at least some overlapping parts in a plan view.
In the power distribution system 1 illustrated in FIGS. 1 to 4, the power conditioner 2 and the transformer 3 are arranged side by side in the vertical direction, and the power conditioner 2 and the cabinet 5 also have a portion that overlaps in a plan view. Therefore, it can be said that they are arranged side by side in the vertical direction.

On the other hand, it can be said that the transformer 3 and the cabinet 5 are not arranged side by side in the vertical direction because there is no overlapping portion in the plan view.
In addition, in the power distribution system 1, the power conditioner 2 and the transformer 3 may be arranged upside down, or the cabinet 5, the transformer 3, and the power conditioner 2 may be arranged vertically. , The vertical order of each may be any.
Whether the three or more members are "arranged side by side in the vertical direction" means that in the plan view, a portion in which all the three or more members overlap in common exists even in at least a part of the plan view. It can be said that it is done or not.

<Power distribution system 1 of the second embodiment>
9 to 15 show the power distribution system 1 according to the second embodiment of the present invention.
The most different points of the second embodiment from the first embodiment are a transformer output circuit breaker W capable of cutting off a transformer output circuit V (a circuit that outputs an alternating current transformed by the transformer 3) and an iron core of the transformer 3. The points 3X and the coil 3Y are arranged inside the same cover body 3Q.
It can be said that the transformer output electric circuit V is one of the electric circuits conducting with the iron core 3X and the coil 3Y of the transformer 3, and the transformer output circuit breaker W is conducting with the iron core 3X and the coil 3Y of the transformer 3. It can be said that it is a circuit breaker that can cut off the electric circuit.

Further, in the second embodiment, the transformer output circuit breaker W and the iron core 3X and the coil 3Y of the transformer 3 are arranged inside the same cover body 3Q, and at the same time, the transformer output circuit breaker W (for example, inside the cabinet 5). , The above-mentioned molded case circuit breaker 25', control unit circuit breaker 35, etc.) are not provided, which is also different from the first embodiment.
In the second embodiment, the transformer output circuit breaker W and the iron core 3X and the coil 3Y of the transformer 3 are arranged inside the same cover body 3Q, and at the same time, the transformer output circuit breaker W is 1 inside the cabinet 5. Only one (for example, only the above-mentioned circuit breaker 35 for the control unit) may be provided.
The transformer 3, the cabinet 5, and the like in the power distribution system 1 of the second embodiment will be described below.

<Transformer 3 according to the present invention (Transformer 3 of Example 2)>
As shown in FIGS. 9 to 13, the transformer 3 according to the present invention is used in the power distribution system 1 of the second embodiment, and the alternating current from one or more of the above-mentioned power conditioners 2 and the like. It is a device that transforms.
It can be said that the transformer 3 according to the present invention is the transformer 3 of the second embodiment, and the transformer 3 transforms (steps down) an alternating current from the power conditioner 2 to a lower alternating current. Or, conversely, the alternating current from the power conditioner 2 may be transformed (boosted) into a higher alternating current.

The most different feature of the transformer 3 of the second embodiment from the transformer 3 of the first embodiment is that the electric path conducting the iron core 3X and the coil 3Y of the transformer 3 (for example, the transformer output in the distribution system 1 of the second embodiment described above). A breaker (for example, the second embodiment described above) that can cut off the electric circuit V (the electric circuit that outputs the AC current transformed by the transformer 3) or conversely, the electric circuit that causes the transformer 3 to input the AC current). The transformer output breaker W in the power distribution system 1 or, conversely, a breaker that can cut off the electric path for inputting AC current to the transformer 3) and the iron core 3X and coil 3Y of the transformer 3 are the same. It is a point that is arranged inside the cover body 3Q of.
Hereinafter, the electric circuit conducting with the iron core 3X and the coil 3Y of the transformer 3 is mainly a transformer output electric circuit V, and the circuit breaker capable of cutting off the electric circuit conducting with the iron core 3X and the coil 3Y of the transformer 3 is mainly referred to as a circuit breaker. It is mainly described as a transformer output circuit breaker W.
Here, the cover body 3Q in the transformer 3 of the second embodiment includes the transformer cylinder body 3a and the upper lid 3c described in the transformer 3 of the first embodiment, and may also include the base 3f described later. good.

Further, in the transformer 3 of the second embodiment, an intermediate plate-like member is formed between the circuit breaker such as the transformer output circuit breaker W and the iron core 3X and the coil 3Y of the transformer 3 inside the cover body 3Q. It can be said that P is different from the transformer 3 of the first embodiment in that a heat shield plate 3g and a mounting plate 3h, which will be described later, are arranged as P.
In addition, also in the transformer 3 of the second embodiment, like the transformer 3 of the first embodiment described above, the transformer output circuit breaker W (in the second embodiment, the transformer output circuit breaker W provided inside the cover body 3Q). It can be said that the transformer has a circuit breaker-iron core / coil distance α which is a distance between the transformer 3 and the iron core 3X and the coil 3Y and the like.
Next, the base 3f, the heat shield plate 3g, the mounting plate 3h, the circuit breaker-iron core / coil distance α, and the like in the transformer 3 of the second embodiment will be described below.

<Base 3f>
As shown in FIGS. 10 to 13, the base 3f is a member that supports (supports) the above-mentioned iron core 3X, coil 3Y, terminals, etc. in the transformer 3 (transformer 3 of the second embodiment) according to the present invention. Is.
The base 3f may have any configuration as long as it supports the iron core 3X, the coil 3Y, and the like. For example, the base 3f is made of a steel material (H steel, etc.) having a substantially well-shaped portion, a substantially rectangular portion, or a substantially rectangular portion. Is further divided into a substantially rectangular shape (so-called abbreviated "eye" -shaped part of the Chinese character), or a combination of these abbreviated well-shaped or substantially rectangular parts. In addition, a solid foundation made of concrete or the like having a uniform thickness or a geta foundation having a dent or the like so as to form a space below the transformer 3 may be used.

The base 3f may support (or support) the above-mentioned transformer cylinder 3a in addition to the iron core 3X, the coil 3Y, and the like.
Hereinafter, it will be described that the transformer 3 of the second embodiment mainly uses the base 3f in which a substantially well-shaped or substantially rectangular portion is combined.

<Aperture ratio in cover body 3Q>
In the example shown in FIGS. 11A to 11C, the aperture ratio in the cover body 3Q is assembled into a substantially rectangular shape of the base 3f if the opening state of the lower portion (base 3f described above) of the cover body 3Q is mentioned. The aperture ratio in the portion may be, for example, greater than 0% and 95% or less, preferably 10% or more and 85% or less, and more preferably 20% or more and 80% or less (70% or the like).
Further, the aperture ratio in the substantially rectangular portion of the base 3f further divided into substantially rectangular shapes is, for example, greater than 0% and 80% or less, preferably 10% or more and 70% or less, and further preferably 20% or more and 60. It may be less than% (30%, etc.).

Further, referring to the opening state of the upper portion (upper lid 3c described above) of the cover body 3Q, the opening ratio between the four side plates of the upper lid 3c and the transformer cylinder body 3a is, for example, greater than 0% and 80% or less. It may be preferably 10% or more and 70% or less, and more preferably 20% or more and 60% or less (30% or the like).
The aperture ratio that communicates the space between the four side plates of the upper lid 3c and the transformer cylinder 3a and the inside of the transformer cylinder 3a itself is, for example, greater than 0% and 100% or less, preferably 25% or more and 95%. Hereinafter, it may be more preferably 50% or more and 90% or less (100% or the like).
The arrows in FIGS. 11 (b) and 11 (c) indicate the air flow in the simulations shown in FIGS. 10 (c), (d), 12 and 13.

<Heat shield 3g, etc.>
As shown in FIGS. 10 to 13, the heat shield plate 3g is the above-mentioned transformer output circuit breaker W (the above-mentioned molded case circuit breaker 25) in the transformer 3 (transformer 3 of the second embodiment) according to the present invention. 'And at least one of the circuit breaker 35 for the control unit) and the intermediate plate-shaped member P arranged between the iron core 3X and the coil 3Y of the transformer 3.
The heat shield plate 3g has a heat shield property, and it can be said that the heat generated from the iron core 3X, the coil 3Y, etc., which is the main body of the transformer 3, is suppressed (shielded) from reaching the transformer output circuit breaker W.

The heat shield plate 3g is arranged between the transformer output circuit breaker W and the iron core 3X, the coil 3Y, etc., and may have any configuration as long as it shields heat from the iron core 3X, the coil 3Y, etc., but for example, the iron core. It is a plate-shaped member with heat-shielding coating on the side of 3X and coil 3Y, a plate-shaped member made of synthetic resin or iron with aluminum vapor deposition, and other plate-shaped members made of aluminum. It doesn't matter.
The shape of the heat shield plate 3g is not particularly limited, but for example, a substantially rectangular plate-shaped member (see FIG. 13) or a substantially rectangular plate-shaped member is bent at the end to form a substantially U-shape in a plan view. (See FIGS. 10 and 11), or other substantially square plate-shaped members, and the size of the heat shield plate 3g is not particularly limited, but the transformer 3 In front view, the transformer output circuit breaker W may be larger (wider) than the transformer output circuit breaker W, and even if the transformer output circuit breaker W is two or more such as a molded case circuit breaker 25'and a control unit circuit breaker 35 or the like. It can be said that it is large enough to block heat.

The heat shield plate 3g is erected from the front surface of the iron core 3X, the coil 3Y, etc., and is attached via a heat shield arrangement member (heat shield support member) 3z1 extending in the forward direction by a predetermined heat shield arrangement distance β. You may.
The heat shield arrangement member 3z1 is a rod-shaped material having a predetermined number (two (a pair of left and right), three or more, etc.) and is substantially linear, and the cross-sectional shape thereof is not particularly limited, but for example, It may have a substantially square shape, a substantially rectangular shape, or any other shape such as a substantially circular shape, a substantially elliptical shape, or a substantially triangular shape.
On the other hand, if the heat shield plate 3g is formed by bending both ends of a substantially rectangular plate-shaped member into a substantially U shape in a plan view, it can be said that both ends are members for arranging the heat shield plate 3g. Separately, it is not necessary to have the heat shield arrangement member 3z1.

Further, the above-mentioned heat shield arrangement distance β may be any value, and for example, in the side view of the transformer 3, it may be 20 cm (200 mm) or less, or 1 cm or more and 20 cm or less (10 mm or more and 200 mm). Below), preferably 2 cm or more and 16 cm or less (20 mm or more and 160 mm or less), more preferably 4 cm or more and 12 cm or less (40 mm or more and 120 mm or less), and more specifically, 5 cm or 10 cm or the like. It can be said that it doesn't matter.
It can be said that the following mounting plate 3h is attached to the iron core 3X, the coil 3Y, and the like via such a heat shield arranging member 3z1 and the heat shield plate 3g.

<Mounting plate 3h, etc.>
As shown in FIGS. 10 to 13, the mounting plate 3h also has the above-mentioned transformer output circuit breaker W (the above-mentioned molded case circuit breaker 25'in the transformer 3 (transformer 3 of the second embodiment) according to the present invention. And at least one of the circuit breaker 35 for the control unit), and the intermediate plate-shaped member P arranged between the iron core 3X and the coil 3Y of the transformer 3.
It can be said that the transformer output circuit breaker W is attached (supported) to the above-mentioned iron core 3X, coil 3Y, etc., or the heat shield plate 3g via the attachment plate 3h.

The mounting plate 3h is arranged between the transformer output circuit breaker W and the iron core 3X, the coil 3Y, and the like, and any configuration may be used as long as the transformer output circuit breaker W is mounted. , A substantially rectangular plate-shaped member (see FIG. 13), a substantially rectangular plate-shaped member whose end is bent to form a substantially U-shape in a plan view, and a substantially square plate-shaped member. It may be a member, and the size of the mounting plate 3h may be larger (wider) than the transformer output circuit breaker W or smaller than the above-mentioned heat shield plate 3g in the front view of the transformer 3 (). It does not matter (even if it is narrow), and even if the transformer output circuit breaker W is two or more, such as a circuit breaker 25'for wiring and a circuit breaker 35 for a control unit, the size is such that heat can be blocked. I can say.
The mounting plate 3h is also a plate-shaped member having a heat-shielding coating on the side of the iron core 3X and the coil 3Y, a plate-shaped member made of synthetic resin or iron on which aluminum is vapor-deposited, and other aluminum. It may be a plate-shaped member of the above, or may be made of a heat insulating material, but conversely, even if it is not provided with such a structure and is simply made of a synthetic resin or iron. I do not care.

The mounting plate 3h may be erected from the front surface of the heat shield plate 3g and mounted via a mounting arrangement member (mounting support member) 3z2 extending in the forward direction by a predetermined mounting arrangement distance γ.
The mounting arrangement member 3z2 is also a rod-shaped material having a predetermined number (two (a pair of left and right), three or more, etc.) and is substantially linear, and the cross-sectional shape thereof is not particularly limited, but is, for example, omitted. It may have any shape such as a square shape, a substantially rectangular shape, a substantially circular shape, a substantially elliptical shape, and a substantially triangular shape.
On the other hand, if the mounting plate 3h is a substantially rectangular plate-shaped member in which both ends are bent to form a substantially U-shape in a plan view, it can be said that both ends are members for arranging the mounting plate 3h. , It is not necessary to have the mounting arrangement member 3z2.
Further, the mounting plate 3h may be also used as the above-mentioned heat shield plate 3g (that is, the mounting plate 3h and the heat shield plate 3g may be shared by one plate-shaped member), and the heat shield arrangement member may be used. 3z1 and the mounting arrangement member 3z2 may be the same member.

Further, the mounting arrangement distance γ described above may be any value, but for example, in the side view of the transformer 3, it may be 10 cm (100 mm) or less, or 1 cm or more and 10 cm or less (10 mm or more and 100 mm or less). ), Preferably 2 cm or more and 7 cm or less (20 mm or more and 70 mm or less), more preferably 3 cm or more and 4 cm or less (30 mm or more and 40 mm or less), and more specifically, 3.5 cm or more. It can be said that.
It can be said that the transformer output circuit breaker W is attached to the iron core 3X, the coil 3Y, and the like via the mounting arrangement member 3z2 and the mounting plate 3h described so far, the heat shield arrangement member 3z1 and the heat shield plate 3g, and the like.

Further, the mounting plate 3h is fixed by directly contacting the back surface of the transformer output circuit breaker W with a fixing means such as a screw (see FIGS. 13A and 13B), or a predetermined offset arrangement distance. It may be fixed by a fixing means such as a screw via a substantially tubular spacer 3z3 having a length of δ (the length is an offset arrangement distance δ) (see FIG. 13C).
When such a spacer 3z3 is provided, the offset arrangement distance δ described above may be any value, but for example, in the side view of the transformer 3, it may be 5 cm (50 mm) or less, or , 5 cm or less (greater than 0 mm and 50 mm or less), preferably larger than 0 cm and 4 cm or less (greater than 0 mm and 40 mm or less), and more preferably 0.5 cm or more and 3 cm or less (5 mm or more and 30 mm or less). More specifically, it can be said that it may be 1 cm or the like.

<Circuit breaker-iron core / coil distance α>
As shown in FIG. 13, the circuit breaker-iron core / coil distance α is the transformer provided inside the cover body 3Q described above in the transformer 3 (transformer 3 of the second embodiment) according to the present invention. This is the distance between the output circuit breaker W and the iron core 3X and coil 3Y of the transformer 3.
Here, since the transformer output circuit breaker W, the iron core 3X of the transformer 3, the coil 3Y, and the like are arranged inside the same cover body 3Q, naturally, the circuit breaker-iron core / coil distance α must be set. It becomes less than or equal to a predetermined value (so to speak, they exist in the vicinity of each other).

That is, if the transformer output circuit breaker W and the iron core 3X and the coil 3Y of the transformer 3 are present in the vicinity of each other, the circuit breaker-iron core / coil distance α is naturally equal to or less than a predetermined value. The circuit breaker-iron core / coil distance α is 30 cm (300 mm) or less, or 1 cm or more and 30 cm or less (10 mm or more and 300 mm or less), preferably 3 cm or more and 24 cm or less (30 mm or more and 240 mm) when viewed from the side of the transformer 3. Below), more preferably 6 cm or more and 18 cm or less (60 mm or more and 180 mm or less), and more specifically, 8.5 cm, 13.5 cm, 14.5 cm or the like.
Further, it can be said that the breaker-iron core / coil distance α is also the total of the distances β, γ, etc. described so far, and when the spacer 3z3 described above is provided (see FIG. 13C), the breaker -The iron core / coil distance α can be said to be substantially equal to the sum of the heat shield arrangement distance β, the attachment arrangement distance γ, and the offset arrangement distance δ, and does not have the spacer 3z3 described above (FIG. 13 (a)). , (B)), it can be said that the breaker-iron core / coil distance α is substantially equal to the sum of the heat shield arrangement distance β and the attachment arrangement distance γ. Strictly speaking, the circuit breaker-iron core / coil distance α is a value obtained by adding the sum of the distances β, γ, etc. described above to the sum of the thicknesses of the heat shield plate 3g and the mounting plate 3h. It can be said that.

<Iron core / coil-circuit breaker cable V'>
In addition, it can be said that the transformer 3 of the second embodiment has an iron core / coil-circuit breaker cable V'.
As shown in FIG. 13, the iron core / coil-circuit breaker cable V'is the transformer output circuit breaker W provided inside the cover body 3Q described above and the transformer 3 in the transformer 3 of the second embodiment. It can be said that it is a cable (electric circuit) for conducting the coil 3Y, terminals, etc.

The iron core / coil-circuit breaker cable V'may have any configuration as long as it conducts the transformer output circuit breaker W and the coil 3Y or the like. It may be a rod-shaped material such as a shape, or a rod-shaped material having a substantially straight shape, and the cross-sectional shape thereof is not particularly limited. It may have any shape such as a shape, a substantially elliptical shape, and a substantially triangular shape.
Since the iron core / coil-circuit breaker cable V'is also the "electric circuit" in the present invention, the material thereof is the same as described later, but for example, nichrome or the like may be used.

The AC current transformed by the transformer 3 is transferred from the iron core 3X, the coil 3Y, etc. via the iron core / coil-circuit breaker cable V'to the transformer output circuit breaker W (circuit breaker 25'for wiring and the control unit. After passing through the circuit breaker 35, etc.), it is output to the outside of the transformer 3 through the transformer output electric circuit V (transformer output electric circuit 3e, branch electric circuit 25, etc.).
Further, Joule heat generation generated when an AC current transformed by the transformer 3 flows through this iron core / coil-circuit breaker cable V'is reflected in the temperature distribution and wind speed distribution inside the cover body 3Q of the transformer 3. Can be said to have no effect.
Hereinafter, the temperature distribution and the wind speed distribution inside the cover body 3Q of the transformer 3 will be described.

<Temperature distribution / wind speed distribution in the cover body 3Q>
In the simulations shown in FIGS. 10 (c) and 10 (d), among the simulation conditions, the ambient temperature is 40 ° C., the amount of heat generated by the transformer 3 (at the time of maximum heat generation) is 1340 W (watt), and the presence or absence of solar radiation is present. Yes, if the solar radiation conditions are an azimuth of 268.9 °, a solar altitude of 47.8 °, and a solar radiation intensity of 1000 W (watt) / m ² , the iron core 3X and coil 3Y of the transformer 3 etc. The surface temperature of itself was about 170 ° C., and the ambient temperature of the iron core 3X and the coil 3Y of the transformer 3 was about 50 ° C.
The simulation shown in FIG. 12 (a) shows the temperature distribution of the entire power distribution system 1 when the simulation conditions and the solar radiation conditions are the same as those in FIGS. 10 (c) and 10 (d). It can be said that there is no effect on the power conditioner 2 and the like above.

In the simulations shown in FIGS. 12 (b) and 12 (c), the wind speed vector distribution inside the cover body 3Q of the transformer 3 when the simulation conditions and the solar radiation conditions are the same as those in FIGS. 10 (c) and 10 (d). It can be said that the wind is hard to come out on the side surface side in the left-right direction of the circumference of the iron core 3X and the coil 3Y of the transformer 3. Inside the cover body 3Q of the transformer 3, heated air flows upward around the iron core 3X, the coil 3Y, etc., whose surface tends to be hot, and the opening between the transformer cylinder body 3a and the upper lid 3c ( Air comes out of the cover body 3Q from (between the outer surface of the transformer cylinder 3a and the eaves portion of the upper lid 3c), and the amount of air that goes out of the cover body 3Q is in the lower part of the transformer cylinder 3a. Through the gap between the notch 3b and the base 3f, the cover body 3Q enters from the outside to the inside (the wind flow shown by the wind velocity vectors in FIGS. 12 (b) and 12 (c) is generated). It can be said that the transformer output circuit breaker W is also cooled.
In the three simulations shown in FIGS. 13 (a) to 13 (c), among the common simulation conditions, the calorific value of the transformer 3 is a predetermined value (for example, the iron core 3X of the transformer 3 and the coil 3Y itself or the like). When the surface temperature of the transformer 3 is 25 ° C, the calorific value of the transformer 3 is 240 W (watt) for the iron core 3X and 730 W (watt) for the coil 3Y, for a total of 970 W (watt). At the time of heat generation, the amount of heat generated by the transformer 3 in this case is 240 W (watt) for the iron core 3X and 1100 W (watt) for the coil 3Y, for a total of 1340 W (watt). The directions are the same (shown only in FIG. 13A), and the width of the side surface of the cover body 3Q on the solar radiation direction side is 900 mm × 600 mm.

In the simulation shown in FIG. 13A, in addition to the above common simulation conditions, the upper surface (top surface) of the upper lid 3c of the cover body 3Q is heat-shielded, and the circuit breaker-iron core / coil distance α is 8. .5 cm (85 mm), breaker placement distance β is 5 cm (50 mm), mounting placement distance γ is 3.5 cm (35 mm) (Note that there is no iron core / coil-circuit breaker cable V', simulation results The surface temperature of the transformer output circuit breaker W is 63.8 ° C., the surface temperature of the mounting plate 3h on the transformer output circuit breaker W side is 65.3 ° C., and the upper lid 3c of the cover body 3Q. The surface temperature at the center of the upper surface is 69.8 ° C, the surface temperature on the end side of the upper lid 3c of the cover body 3Q is 72.8 ° C, which is the maximum, and the surface temperature on the solar radiation direction side of the cover body 3Q is 80.4. It shows that the temperature is ℃, and it can be said that by applying the heat-shielding coating on the upper surface of the upper lid 3c, the surface temperature of each surface is lower than that in the case where it is not applied.
In the simulation shown in FIG. 13 (b), in addition to the common simulation conditions and the heat shield coating on the upper surface of the upper lid 3c, an iron core / coil-circuit breaker cable V'that can conduct an AC current of 60 A (amper) is used. The iron core 3X and coil 3Y and the like were made conductive, and the cutoff arrangement distance β was increased by 5 cm (50 mm) from the case of FIG. 13 (a) (in other words, the iron core / coil-circuit breaker cable). The heat generated by V'was simulated at 0.48 W (watt), and the circuit breaker-iron core / coil distance α was also increased by 5 cm (50 mm) (the mounting arrangement distance γ is the same value as in FIG. 13 (a)). In the case of)), the surface temperature of the transformer output circuit breaker W is lowered to 63.1 ° C., the surface temperature of the mounting plate 3h on the transformer output circuit breaker W side is lowered to 63.9 ° C. The surface temperature at the center of the upper surface and the surface temperature on the solar radiation direction side of the cover body 3Q are the same as in the case of FIG. 13 (a), and the iron core around the end of the iron core / coil-circuit breaker cable V'on the iron core 3X side. Although the surface temperature of 3X and the coil 3Y is 140 ° C., the surface temperature at the end of the cable V'on the iron core 3X etc. side is 81.1 ° C., and the end of the cable V'on the transformer output circuit breaker W side. It shows that the surface temperature in the part is 84.8 ° C. Even if the iron core / coil-circuit breaker cable V'is provided, there is almost no influence of the Joule heat generation, and the circuit breaker arrangement distance β (circuit breaker-). It can be said that the surface temperature of the transformer output circuit breaker W and the surface temperature of the mounting plate 3h on the transformer output circuit breaker W side are lowered by increasing the iron core / coil distance α).

The simulation shown in FIG. 13 (c) is not in the case of FIG. 13 (b) in addition to the above common simulation conditions, the heat shield coating on the upper surface of the upper lid 3c, and the conduction by the iron core / coil-circuit breaker cable V'. When the offset arrangement distance δ is 1 cm (10 mm), the surface temperature of the transformer output circuit breaker W becomes 63.0 ° C., and the surface temperature of the mounting plate 3h on the transformer output circuit breaker W side further increases to 62.6 ° C. The temperature of the space between the transformer output circuit breaker W and the mounting plate 3h is 59.2 ° C, and the temperature of the space of the transformer output circuit breaker W opposite to the mounting plate 3h is 58.8 ° C. By arranging the transformer output circuit breaker W at an offset with respect to the mounting plate 3h (providing an offset arrangement distance δ), the temperature of the space around the transformer output circuit breaker W can be set to 60 ° C. or less. It can be said that. The temperature of the transformer output circuit breaker W itself was about 60 ° C.
Other configurations, effects, and usage modes of the transformer 3 and the like are the same as those of the transformer 3 of the first embodiment.

<Cabinet 5 according to the present invention (Cabinet 5 of Example 2)>
As shown in FIGS. 14 and 15, the cabinet 5 according to the present invention is a box body used in the power distribution system 1 of the second embodiment and provided with the above-mentioned control unit 4 and electrical equipment 11 inside. ..
It can be said that the cabinet 5 according to the present invention is the cabinet 5 of the second embodiment.

The most different difference between the cabinet 5 of the second embodiment and the cabinet 5 of the first embodiment is that the circuit breaker (transformer output circuit breaker W and the like) is inside the cabinet 5 as in the power distribution system 1 of the second embodiment described above. All circuit breakers) are not provided (built-in) (see FIG. 14), or only one circuit breaker (eg, transformer output circuit breaker W, etc.) is provided (built-in) (FIG. 15). See) Point.
When the transformer output circuit breaker W is not provided inside the cabinet 5 as shown in FIG. 14, naturally, the above-mentioned molded case circuit breaker 25'and the control unit circuit breaker 35 are all included in the cabinet 5. The transformer output circuit breaker W is not provided inside.
On the other hand, as shown in FIG. 15, when only one circuit breaker is provided inside the cabinet 5, any of the circuit breakers such as the circuit breaker 25'for wiring and the circuit breaker 35 for the control unit described above may be used. Although only one is provided, a circuit breaker (for example, a circuit breaker 25'for wiring) in an electric circuit (branch circuit breaker 25 or the like) conducting to the load F or system K is not provided, and a circuit breaker 25'for wiring is not provided. A circuit breaker 35 for a control unit, which is smaller than the above, may be provided.

The cabinet 5 of the second embodiment may have any configuration as long as no circuit breaker is provided inside the cabinet 5 or only one circuit breaker is provided. For example, the cabinet 5 may have any configuration. In addition to the control unit 4, the cabinet 5 of the second embodiment incorporates, for example, a power measurement unit 12 described later, which is an electric device 11, a ground fault overvoltage relay 33 described above, a communication device 36, and an uninterruptible power supply 37. In addition to these, for example, a power adapter 4a for the control unit 4 and a lightning arrester (SPD, Surge Protective Device) 39 for the communication device 36 may be built in (see FIG. 15). I do not care.
The configuration, operation effect, and usage mode of the other cabinet 5 and the like are the same as those of the cabinet 5 of the first embodiment.

<Power distribution system 1 of the third embodiment>
FIG. 16 shows a power distribution system 1 according to a third embodiment of the present invention.
The most different points of the third embodiment from the first and second embodiments are the transformers 3 of the first and second embodiments described above, the cabinet 5 of the first and second embodiments, the power conditioner 2, and the like. The point is that it is a split type that is split.

In other words, it can be said that the distribution frame frame 6 is not provided in the third embodiment, and the divided transformer 3 in the distribution system 1 of the third embodiment is the transformer 3 according to the present invention. The divided cabinet 5 in the power distribution system 1 of the third embodiment may be the cabinet 5 according to the present invention.
Other power distribution system 1, power conditioner 2, transformer 3, control unit 4, cabinet 5, power distribution frame frame 6 and the like are configured, and the effects and usage modes are the power distribution system 1 of the first and second embodiments. It is the same as the transformer 3 of Examples 1 and 2 and the cabinet 5 of Examples 1 and 2.

<Power plant 21 of the first embodiment>
17 and 18 show the power plant 21 according to the first embodiment of the present invention.
The power generation plant 21 is a plant having the distribution system 1 described so far and connection portions 22 connected to the system K and the load F, respectively.
In the power generation plant 21, the power generation unit 26 is connected to the load F via the power distribution system 1.

Further, the power generation plant 21 may have a power generation connection device 24 described later and an electric device 11 described above.
It can be said that the power plant 21 of the first embodiment is a CB power receiving type (a type having a high voltage circuit breaker (VCB) 22a) that receives high voltage power having a capacity exceeding 300 kVA.

The power plant 21 may have a power generation device 23 described later, a control unit 4 for controlling the connection unit 22 and the power conditioner 2 (power generation device 23) described above.
It can be said that the connection unit 22 described above is connected to the power conditioner 2, the system K, and the load F, respectively. Here, the system K will be described below.

<System K>
As shown in FIGS. 17 and 18, system K is also called a commercial power system, and is a system that integrates power generation, substation, power transmission, and distribution for supplying electric power to a consumer's power receiving equipment.
The system K is a three-phase three-wire system (3φ3W) and supplies electric power of 6600V, 22000V, etc., 60Hz, 50Hz, etc. from a substation of an electric power company. After the pole transformer K'in the third embodiment of the power plant 21 described later, electric power such as single-phase two-wire (1φ2W) or 1φ3W (single-phase three-wire) may be supplied.
Such a system K is first connected to the connecting portion 22, and then the connecting portion 22 and the like will be described below.

<Connection part (system board) 22 etc.>
As shown in FIGS. 17 and 18, the connection unit 22 is a portion having a device to be connected to the system K described above, and the connection unit 22 is a system board 22 such as a power purchase board or an existing installation. It can be said that it is a board. The equipment of such a system board 22 is built in the board support (system board housing) 22'.
The system board 22 may have any configuration as long as it is connected to the system K and the equipment of the system board 22 is built in the system board housing 22'. For example, a vacuum circuit breaker ( Even if it is equipped with a circuit breaker (so-called system circuit breaker) 22a such as VCB), a high-voltage circuit breaker, a lightning arrester (SAR), an instrument transformer (VT, Voltage Transformer, so-called voltage transformer) 22b, etc. good.

The system circuit breaker 22a in the system board 22 may be configured to cut off a signal from the control unit 4 (or the above-mentioned electric device 11) described later via a trip coil or the like.
Since such a system circuit breaker 22a is provided in the system board 22 (system board housing 22'), an electric circuit (in other words, in other words) between the power generation device 23 (power conditioner 2) and the system K, which will be described later, is provided. Then, of the main electric circuit M from the system K to the load F via the system board 22, the electric circuit in the system board 22) is cut off.

As described above, the potential in the main electric circuit M may be the same as the potential in the system K (6600V, 22000V, etc.), and the load F described later has a transformer (step-down transformer) F1. In this case, it can be said that the electric circuit connecting the transformer F1 (high voltage side) and the system board 22 is a part of the main electric circuit M.
A power generation connection device 24 (particularly, a branch electric circuit 25), which will be described later, may be connected to the main electric circuit M.

The instrument transformer 22b in the system board 22 is closer to the system K than the above-mentioned system circuit breaker 22a (system K) between the power generation device 23 (power conditioner 2) and the system K, which will be described later, and in the electric circuit in the system board 22. It is provided in the electric circuit (on the side closer to).
In such an instrument transformer 22b, the high-voltage side thereof is an electric circuit closer to the system K (closer to the system K) than the system circuit breaker 22a, and a branch electric circuit (transformed branch) from the branch point (transformed branch point) 22c in the electric circuit. It is connected via the electric circuit) 22d, and the low voltage side of the instrument transformer 22b is connected to the electric device 11 described above and the power generation meter described later.

The configuration of the instrument transformer 22b in the system board 22 is also not particularly limited, but may be, for example, a configuration in which 6600V, 22000V, or the like is stepped down to 110V or the like.
In the system board 22, a high-voltage current limiting fuse (PF, Power Fuse) may be provided in the electric circuit between the instrument transformer 22b and the transformation branch point 22c.

<Other equipment in system board 22>
As shown in FIGS. 17 and 18, the system board 22 also includes a circuit breaker (so-called retractable circuit breaker, high-voltage switch) 22e and a current transformer for instruments (so-called high-voltage system current transformer) 22f. , Overcurrent relay (so-called power receiving OCR) 22 g, instrument transformer current transformer (so-called high-voltage current transformer, which can be said to form a part of the trading meter 22h') 22h. You may.
Furthermore, the system board 22 is provided with an undervoltage relay, an overvoltage relay, an undervoltage relay (also referred to as a frequency reduction relay), an overfrequency relay, a watt-hour meter, and a pillar-mounted air switch. You may be.

The disconnector (DS, Disconnecting Switch) 22e in the system board 22 is a device that opens and closes the circuit in the power generation plant 21 and the circuit in the power generation plant 21 in a state where no current is flowing. There is no function to cut off the current, and the disconnector is opened and closed after the current is cut off by another circuit breaker (system circuit breaker 22a, power generation circuit breaker 25', etc.).
The disconnector 22e may have any configuration as long as the circuit can be opened and closed while no current is flowing. For example, the disconnector 22e has a branch point (transformation branch point) 22c to the instrument transformer 22b described above. It may be provided in the electric circuit between the system K.

The current transformer (CT) 22f in the system board 22 is located between the power generation device 23 and the system K, which will be described later, and in the electric circuit in the system board 22 (the electric circuit in the system board 22 in the main electric line M). , It is provided in the electric circuit closer to the power generation device 23 (the side closer to the power generation device 23) than the system breaker 22a described above.
The configuration of such an instrument transformer 22f is also not particularly limited, but for example, the sensor unit 15 of the above-mentioned electric device 11 is attached to the output side (secondary side) of the instrument transformer 22f. Alternatively, the electrical device 11 may be directly connected.
An overcurrent relay (OCR, Over Current Relay) 22g is connected to the instrument transformer 22f.

The instrument transformer (VCT, Combined Voltage and Current Transformer) 22h in the system panel 22 is a device that combines an instrument transformer (VT) and an instrument transformer (CT) into one, and is a system. It is a device that measures the current and voltage that flows from K to the system board 22 (or flows out to the system K). It is a device that measures the amount of power flowing into the system 22 (or flowing out from the system board 22 to the system K), and can be said to be a trading meter.
The instrument transformer 22h may have any configuration as long as it can measure the current and voltage flowing from the system K into the system panel 22, but for example, the instrument transformer 22h may have any configuration. It may be provided in the electric circuit between the above-mentioned circuit breaker 22e and the system K.

In addition, when the system board 22 is provided with an undervoltage relay (which may be the electrical equipment 1 described later), this undervoltage relay (UVR, Under Voltage Relay) is a relay that detects the undervoltage U. Any configuration may be used as long as the undervoltage U can be detected, and for example, it may be connected to the low voltage side of the instrument transformer 22b described above.
When the undervoltage U detected by the undervoltage relay or the like becomes equal to or less than a predetermined value (a value obtained by subtracting a predetermined voltage (for example, 100V, 200V, etc.) from 6600V, 22000V, etc.), the control unit 4 described later describes the above. Any circuit breaker (system circuit breaker 22a, power generation circuit breaker 25', etc.) from the power generation device 23 (power conditioner 2) to the system K may be interrupted, but this circuit breaker generates the reverse power described above. It can be said that the priority is lower than that in the case of the state C1.
When the undervoltage relay or the like detects an undervoltage U and the above-mentioned circuit breaker is cut off by hardware (for example, via a trip coil or the like), the undervoltage relay or the like itself will be described later. It can also be said that the control unit 4 is used.

When the system board 22 is provided with an overvoltage relay, the overvoltage relay (OVR) is a relay that detects overvoltage, and may have any configuration as long as it can detect overvoltage. However, for example, it may be connected to the low voltage side of the instrument transformer 22b described above.
When the overvoltage detected by the overvoltage relay exceeds a predetermined value (a value obtained by adding a predetermined voltage (for example, 100V, 200V, etc.) from 6600V, 22000V, etc.), the power generation device 23 described above is used by the control unit 4 described later. Any circuit breaker from (power conditioner 2) to system K may be cut off, but it can be said that this cutoff also has a lower priority than the case where the reverse power generation state C1 described above is reached.
When the overvoltage relay detects an overvoltage and the above-mentioned circuit breaker is cut off in terms of hardware, it can be said that the overvoltage relay itself is the control unit 4 described later.

When the system board 22 is provided with a shortage frequency relay, this shortage frequency relay (UFR, Under Frequency Relay) is a relay that detects the shortage frequency, and any configuration can be used as long as the shortage frequency can be detected. It may be present, but for example, it may be connected to the low pressure side of the instrument transformer 22b described above.
Insufficient frequency When the insufficient frequency detected by the relay becomes less than or equal to a predetermined value (a value obtained by subtracting a predetermined frequency (for example, 1 Hz or more and 10 Hz or less) from 60 Hz, 50 Hz, etc.), the control unit 4 described later describes the problem. Any circuit breaker from the power generation device 23 (power conditioner 2) to the system K may be cut off, but it can be said that this cutoff also has a lower priority than the case where the reverse power generation state C1 described above is reached. ..
When the shortage frequency is detected by the shortage frequency relay and the above-mentioned circuit breaker is cut off by hardware, it can be said that the shortage frequency relay itself is the control unit 4 described later.

When the system board 22 is provided with an overfrequency relay, this overfrequency relay (OFR, Over Frequency Relay) is a relay that detects overfrequency, and any configuration can be used as long as it can detect overfrequency. It may be present, but for example, it may be connected to the low pressure side of the instrument transformer 22b described above.
When the overfrequency detected by the overfrequency relay exceeds a predetermined value (a value obtained by adding a predetermined frequency (for example, 1 Hz or more and 10 Hz or less) from 60 Hz, 50 Hz, etc.), the control unit 4 described later describes the above. Any circuit breaker from the power generation device 23 to the system K may be cut off, but it can be said that this cutoff also has a lower priority than the case where the reverse power generation state C1 described above is reached.
When an overfrequency is detected by the overfrequency relay and the above-mentioned circuit breaker is cut off in terms of hardware, it can be said that the overfrequency relay itself is also the control unit 4 described later.

When the system board 22 is provided with a watt-hour meter, the watt-hour meter may have any configuration as long as it can measure the amount of power when flowing from the system K to the system board 22. For example, the measured values of the current and the voltage connected to the transformer transformer 22h for the instrument and output from the transformer transformer 22h for the instrument are input, and the value obtained by multiplying the current and the voltage (voltage and current). The product) may be integrated to measure the amount of power.
Here, it can be said that the watt-hour meter is for purchasing power when measuring the amount of power flowing from the system board K to the system board 22, and conversely, it is sold when measuring the amount of power flowing out from the system board 22 to the system board K. It can be said that it is electric. It should be noted that this watt-hour meter may be a class B electrical appliance specified by the Electrical Appliance and Material Safety Law.

When the pole air switch is provided on the system board 22, this pole air switch (PAS, Pole Air Switches) is a device used to open / close the demarcation point of responsibility between the power plant 21 and the system K. Is.
The pole-mounted air switch may have any configuration as long as it can open and close the demarcation point of responsibility between the power plant 21 and the system K. For example, the system with the above-mentioned instrument transformer transformer 22h. It may be provided in the electric circuit between K.

<Board support of system board 22 (system board housing) 22'>
As shown in FIGS. 17 and 18, the system board housing 22'which is a system support is a housing in which the equipment of the system board 22 described above is built in, and is one power plant 21 (or a power generation device described later). In 23), it can be said that there is only one (there is only one system board 22) because it is connected to the system K.
The system board housing 22'may have any configuration as long as it incorporates the equipment of the system board 22, but may be formed in a substantially rectangular parallelepiped shape as a whole, for example.

<Load F, Load power D>
As shown in FIGS. 17 and 18, the load F includes the power received J from the system K via the connection portion (system board) 22, the power generation H output from the power generation device 23 (power conditioner 2), and the like. The power consumed by such a load F is referred to as load power (which can also be said to be power consumption) D.
The load F may have any configuration as long as it consumes the received power J and the generated power H. For example, the load F may be a lighting (light load equipment) F in a factory or an industrial motor (IM) in a factory or the like. , Industrial Motor, power load equipment) F, or an illumination distribution board connected to a plurality of the above-mentioned illuminations F.

The load F may be an air conditioner in a building such as a house or a building, a fluorescent lamp, a home appliance, a vehicle such as an electric vehicle or a gasoline vehicle, or an equipment in the vehicle, in addition to the equipment in the factory.
In addition, the load F has a transformer (so-called step-down transformer) F1 that transforms (steps down) the received power J (or the power generated from the power conditioner 2) from the system K via the system board 22. Or have a high-voltage AC load switch (LBS, Load Break Switch) F2 in the electric circuit between the transformer F1 and the system board 22 (or power conditioner 2), or the transformer F1 and the above. A molded case circuit break (MCCB) F3 may be provided in an electric circuit or the like between the industrial motor (or lighting) F and the like.
The circuit breaker F3 for wiring may have a fuse such as a high-voltage current limiting fuse.

The configuration of the transformer F1 in the load F is also not particularly limited, but for example, in the case of an industrial motor (for power), 6600V, 22000V, etc. can be changed to 440V, 210V, 600V, etc. with three-phase three-wire (3φ3W). If it is a configuration for stepping down, or for lighting (for an electric lamp), it may be configured to step down 6600V, 22000V, etc. to 105V or more and 210V or less with a single-phase three-wire (1φ3W).
The load F does not have to be provided with such a transformer F1. In this case, another transformer is provided on the system panel 22 side, or the output from the power generation device 23 (power conditioner 2) is output. , It may be configured to be directly connected to the load F without going through the transformer F1.

<Power consumption (load power) D of load F, its calculation and change>
The power consumed by the entire load F is the load power D, which is consumed not only by the total power consumed by each load F itself, but also by the power loss in the transformer F1 and the lighting distribution board. Power may be included.
The number of loads F may be one or more, but even if the load F is one, if the transformer F1 is also possessed, the power including the power loss is the load. It becomes electric power D.

In this way, it is difficult in terms of hardware to directly measure the power consumption of one or more loads F and calculate the total load power D including the power loss, and the load is accurate. It can be said that it is difficult to measure the power D.
Therefore, by calculating the load power D from the sum of the received power J and the generated power H, it is not necessary to directly measure the load power D, and the measurement of the received power J and the generated power H has a simple hardware structure. It can be said that it is easy to measure and the accuracy is improved.
It is the above-mentioned electric device 11 that measures the received power J (including the reverse power G and the insufficient power U) that is the basis for calculating the load power D, and the power generation that measures the power generation H. Its use for use will be described later.

The power consumption (load power) D of the load F varies depending on the time zone such as day or night, the number of the lamp load equipment F used, and the type and number of the power load equipment F used in the factory or the like. Since it changes depending on the purpose of the work and the like, the load power D naturally changes such as decreasing or increasing.
The power generation device 23 can generate power H or the like that is as close as possible to the load power D that changes in this way (in other words, the control unit 4 described later makes the limiting coefficient A (t) as close to 100% as possible). For example, it is desirable that the received power (purchased power) J is suppressed as much as possible (costs can be reduced).

On the other hand, when the power generation device 23 is generating power generation H or the like as close as possible to the load power D, when the load power D decreases, the power generation power for controlling the power conditioner 2 to reduce the power generation H is reduced. Even if the target value TH of H is given, the actual power generation H does not decrease immediately (the decrease in the power generation H is delayed). Therefore, the power generation H becomes larger than the load power D by the delay, and the reverse power G (Power that cannot be consumed by the load F flows to the system K) needs to be suppressed.
The power generation connection device 24 for connecting the power generation device 23, which will be described later, to the load F and the system board 22 described so far will be described below.

<Power generation connection device 24 and electrical device 11>
As shown in FIGS. 17 and 18, the power generation connection device 24 is a device that connects the power generation device 23 described later to the connection portion (system board) 22 and the load F described above. Further, the above-mentioned electric device 11 can also be said to be a separate device for connecting the power generation device 23 together with the power generation connection device 24, and thus will be described later.
The power generation connection device 24 may have any configuration as long as the power generation device 23 is connected to the system board 22 and the load F. For example, the power generation connection device 24 may be provided with a branch electric circuit 25, and other power generation. A power meter (not shown), a power generation transformer (not shown), a power generation circuit breaker 25', or the like may be provided.

<Electrical equipment 11>
As shown in FIGS. 17 and 18, the electric device 11 is a device connected to a predetermined electric circuit, and includes a power measuring unit 12 and a relay unit 13, which will be described later. Since such an electric device 1 has both functions of a so-called wattmeter and a relay (relay), it can be said to be a "wattmeter relay".
The electric device 11 may include a sensor unit (so-called current sensor unit) 15 described later.
Here, "connected to a predetermined electric circuit" in the present invention means not only when the electric circuit is directly connected to the electric circuit, but also when the transformer (for example, a current transformer described later) is not directly connected to the electric circuit. It is connected via the low-voltage side of the transformer 22b, the low-voltage side of the pillar transformer K', etc., or is a current transformer (for example, the secondary side of the current transformer 22b described later (current transformer for instruments). The case where the sensor unit 5 is connected (attached) via (output from 22b) and the like), and the case where the sensor unit 5 is connected (attached) to the low voltage side of the pole transformer K'is also included.

The electric device 11 digitizes the measured value by the power measuring unit 12 described later and outputs it to the relay unit 13 described later and the control unit 4 of the power plant 21 described later by wire or wirelessly by a communication cable 11A or the like. It may have an output unit (not shown).
The electric device 11 may have any value for the measurement interval by the power measurement unit 12 and the output interval (communication speed) of the output unit described above, but for example, the measurement interval and the output interval are 0.1 seconds or less. Alternatively, it may be 0.05 seconds or more and 2.00 seconds or less, 0.75 seconds or more and 1.50 seconds or less, 0.10 seconds or more and 1.00 seconds or less (0.1 seconds or the like).

<Power measurement unit 12>
As shown in FIGS. 17 and 18, the power measuring unit 12 is a part that measures the power in the above-mentioned predetermined electric circuit, and it can be said that the electric device 11 has a wattmeter function.
Here, the "electric line" in the present invention is for passing electricity, and includes conductors such as copper, aluminum, silver, gold, and nichrome, cables in which the conductors are covered with an insulating material, and general electric wires. Including.

The predetermined electric circuit for measuring the electric power by the electric power measuring unit 12 is not particularly limited, but for example, the same three-phase three-wire (3φ3W) as the system K described later supplies electric power of 6600V, 22000V, etc., 60Hz or 50Hz. It may be an electric circuit that supplies electric power such as a single-phase two-wire (1φ2W) or a single-phase three-wire (1φ3W).
More specifically, the predetermined electric circuit for which the electric power measuring unit 12 measures the electric power is, for example, an electric circuit from the system K to the load F via the connecting unit 22 in the power plant 21 described later (hereinafter, "main electric circuit"). It may be called "M").

The value of the voltage (voltage of the electric circuit as the measurement target) input to the electric device 11 (particularly, the power measuring unit 12 or the like) is not particularly limited, but for example, the electric circuit is three-phase, three-wire or single-phase. If it is a two-wire system, it may be 110V, 220V, 440V, 600V, etc. of 60Hz or 50Hz that has passed through a transformer (for example, an instrument transformer 22b or a pole transformer K'described later), or a single-phase three-wire system. If there is, it may be 100V or more and 200V or less of 60Hz or 50Hz.
Here, in order to input the voltage of the electric circuit as the measurement target to the power measurement unit 12 and the like, the electric device 11 is naturally connected to the predetermined electric circuit to be the measurement target.

More specifically, for example, if the electric circuit to be measured is a three-phase three-wire or a single-phase two-wire, the electric device 11 is the low-voltage side of the instrument transformer 22b described later (the first power plant 21 described later). If the electric circuit is connected to 1, 2 and 4 (see the first, second and fourth embodiments) and the electric circuit to be measured is a single-phase three-wire, the electric device 11 is the low-voltage side of the pole transformer K'described later (the power plant 21 described later). (See Third Embodiment).
The power supply of the electric device 11 is also not particularly limited, but is shared with the voltage of the electric circuit as the measurement target described above (that is, 110V, 220V, 440V, 600V of 60Hz or 50Hz, or 100V or more and 200V or less). Alternatively, it may be DC 100V or 110V.

The power measured by the power measuring unit 12 may be, for example, reverse power G or insufficient power U in the main electric line M, and flows from the system K to the connection unit 22, the load F, or the like in the main electric line M. It can be said that the received power (purchased power, purchased power) J is also included.
Here, the backflow power G is the power that flows back from the connection portion 22 to the system K in the power plant 21 described later, and can also be said to be the backflow power G.
Further, the insufficient power U is power representing a shortage of the received power J at the connection portion 22 when a short circuit occurs on the system K side described above, and is generated from the power generation device 23 described above. It can be said that when the force H becomes too large, the insufficient power approaches zero.

The power measurement unit 12 is not particularly limited as long as it can measure electric power, but is, for example, an electronic type, a mechanical type, or a three-phase type (a method of measuring two phases out of three phases and three wires). It may be a single-phase type or a single-phase type.
Hereinafter, the power measurement unit 12 will be described as being mainly an electronic type and a three-phase type.
Only one such power measurement unit 12 may exist in one electric device 11, but a plurality of such power measurement units 12 may exist.

<Relay unit 13>
As shown in FIGS. 17 and 18, the relay unit 13 is a portion that performs a relay operation according to the power measured by the power measurement unit 12 described above, and the electric device 11 has a relay function (relay function). It can be said that it has.
Here, "according to the power measured by the power measuring unit 12" in the present invention means that the measured power exceeds a predetermined value (threshold value) (exceeds the threshold value) or a predetermined value. When it becomes less than or equal to the value (threshold value) (when it falls below the threshold value), it means that the next relay operation is performed.

If the measured power is the reverse power G, the predetermined threshold value is, for example, 1% or more of the power flowing from the system K into the connection portion 22 (received power J described later) in the power plant 21 described later. The power may be% or less (preferably 1.5% or more and 5% or less, 5%, 1%, etc.), or the predetermined threshold value may be 0 kW.
More specifically, for example, when the current value in the power of the three-phase three-wire flowing (received) from the system K into the connection portion 22 is 50 A and the voltage value is 6600 V, the received power J is √. 3 × 50 × 6600 = 571576.766 ... W ≈ 571.6 kW, and 5% of the received power J is 571.6 kW × 0.05 ≈ 28.6 kW. Therefore, this 28.6 kW is A predetermined threshold value may be obtained, or 571.6 kW × 0.01 ≈5.72 kW, which is 1% of the received power J, may be a predetermined threshold value.

Furthermore, "according to the power measured by the power measuring unit 12" is not limited to the case where the next relay operation is immediately performed immediately after the measured power reaches a predetermined value (threshold value) or more. , Including the case where the next relay operation is performed after a predetermined time has elapsed.
If the measured power is the reverse power G, the predetermined time is, for example, when a reverse power G larger than 5% (28.6 kW, etc.) of the received power J is generated in the power plant 21 described later. After the reverse power G of this value is generated, 0.1 seconds or more and 15.0 seconds or less, 0.5 seconds or more and 5.0 seconds or less, 1.0 seconds or more or 2.0 seconds or more ( When 2 seconds have passed since the predetermined time (2.0 seconds, etc.) is reached (that is, the reverse power G is 28.6 kW or more, which is the threshold value), the next relay operation is performed. Become).
Here, in the present invention, "the reverse power G becomes larger than a predetermined value (threshold) (so-called" reverse power generation state C1 ")" means that the reverse power G becomes strictly larger than the threshold (naturally). In addition to the meaning that the threshold value is not included), depending on the resolution and settings of the electric device 11, it is permissible to mean that the reverse power G is "greater than or equal to the value that can be regarded as the threshold value". The "value that can be regarded as the threshold value" in the present invention may be set according to the resolution of the electric device 11 or a predetermined value of the insufficient power U. For example, the threshold value and 1 mW, 1 μW, and 1 nW may be set. It may be the sum with such as.

Further, the "relay operation" in the present invention means, for example, in the power generation plant 21 described later, that any one of the electric circuits from the power generation device 23 to the system K is cut off (one of the circuit breakers in the electric circuit is cut off). If the power conditioner 23 has a power conditioner 2 (a power conditioner 2 that converts a direct current or an alternating current into an alternating current), the conversion of the power conditioner 2 is stopped, etc. Means.
The circuit breaker may be configured to cut off a signal from the control unit 4 (or the electric device 11) described later via a trip coil or the like.

The relay unit 13 is not particularly limited as long as it can perform a relay operation according to the power measured by the power measurement unit 12, but for example, a contact type (electromagnetic type) using an electromagnet or a semiconductor element is used. It may be a non-contact type, and if it is an electromagnetic type, for example, a make type (a contact that closes when a current is passed through the electromagnet) or a break type (the contact is closed when a current is passed through the electromagnet). Open, b-contact), transfer type (switching multiple contacts by passing current through the electromagnet, c-contact), ratchet type (switching the opening and closing of contacts each time a current is passed through the electromagnet), and other electromagnets Any configuration such as a polar relay type in which permanent magnets are provided in parallel may be used.

As for such a relay unit 13, only one (one element) may be present in one electric device 11, but a plurality of (plural elements) may be present.
Hereinafter, it is described that the relay unit 13 mainly exists in a plurality (for example, two elements) in one electric device 11.

<Device housing 14>
As shown in FIGS. 17 and 18, the device housing 14 is a housing in which the power measurement unit 12 and the relay unit 13 described above are provided (built-in) inside.
If the device housing 14 incorporates the power measurement unit 12 and the relay unit 13, the shape, size, configuration, etc. of the device housing 14 are not particularly limited, but for example, the shape may be a substantially cubic shape or a substantially rectangular parallelepiped shape. And so on.

<Sensor unit 15>
As shown in FIGS. 17 and 18, the sensor unit 15 is a portion that detects a current in the predetermined electric circuit described above, and can be said to be a current sensor unit 15.
The sensor unit 15 may include a sensor electric circuit 16 described later and an open / close type detector 17.

The sensor unit 15 may have any configuration as long as it can detect the current in a predetermined electric circuit, and may be, for example, a fluxgate type (open loop type, closed loop type, etc.) or a Hall element type (open loop type). , Closed loop type, etc.), CT (Current Transformer) type, Rogowski coil type, etc. may be used.
Further, the current transformer unit 15 has a current transformer ratio between the primary side (predetermined electric circuit side) and the secondary side (output side from the sensor unit 15), which is not particularly limited, but is, for example, 10: 1 or more and 5000: 1. It may be 100: 1 or more and 4000: 1 or less, or (3000: 1 or the like).

That is, if the current transformer ratio between the primary side and the secondary side of the sensor unit 15 is 3000: 1, the current value flowing in the electric circuit to be measured is output from the sensor unit 15 even if it is very large, for example, 150A. The current value is about 0.05A (50mA) or the like.
The detectable range of the sensor unit 15 is also not particularly limited, but may be, for example, 0.01 A or more and 5.00 A or less, or 1 A or more and 200 A or less.

Such a sensor unit 15 may be attached to any position with respect to the electric circuit as long as it can detect the current in a predetermined electric circuit. For example, the current transformer 22a for an instrument described later 2 The next side (see the first and fourth embodiments of the power plant 21 described later) or the main electric circuit M from the system K to the load F via the connection portion 22 (see the second embodiment of the power plant 21 described later). Or it may be attached to the low voltage side of the pillar transformer K'described later (see the third embodiment of the power plant 21 described later).
The sensor unit 15 is attached directly to the main electric line M, or the sensor unit 15 is attached to the secondary side of the instrument diversion device 22a, so that the sensor unit 15 even detects the current value of the main electric line M. If possible, since the voltage value (potential) of the main electric line M is the same potential as the system K (6600 V, 22000 V, etc.), the current value of the main electric line M and the voltage value of the main electric line M detected by the sensor unit 15 Can be said to be the selling power (reverse power G) flowing through the system K measured by the power measuring unit 12 which is the power in the main electric line M, or the buying power (received power J) flowing from the system K.

This also applies when the sensor unit 15 is connected to the low voltage side of the pillar transformer (step-down transformer) K', and even the current value of the sensor unit 15 on the low voltage side of the pillar transformer K' If it can be detected, the power will be almost the same on the high-voltage side and low-voltage side of the pillar transformer K'(if iron loss, copper loss, etc. are ignored), so the low voltage of the pillar transformer K'by the detection of the sensor unit 15 The product of the current value on the side and the voltage value on the low voltage side of the pillar transformer K'is the power in the system K (the selling power (reverse power G) flowing through the system K measured by the power measuring unit 12 and the system K). It can also be said that it is the purchased power (received power J) that flows in from.
Only one such sensor unit 15 may exist in one electric device 11, but a plurality of such sensor units 15 may also exist.
Hereinafter, it is described that a plurality of sensor units 15 (for example, two) are mainly present in one electric device 11.

<Sensor electric circuit 16>
As shown in FIGS. 17 and 18, the sensor electric circuit 16 is an electric circuit connecting the sensor unit 15 and the power measurement unit 12 described above.
The value of the current flowing through the sensor electric path 16 and being output from the sensor unit 15 may not be particularly limited, but is also related to the flow change ratio between the primary side and the secondary side in the sensor unit 15 described above. For example, it may be 1A or less.

That is, the upper limit of the output current is, for example, 1 A (1000 mA) or less, preferably 500 mA or less, more preferably 100 mA or less, still more preferably 50 mA or less (several mA, 1 mA or more and 20 mA or less, etc.). It may be.
On the other hand, the lower limit of the output current is also not particularly limited, but is, for example, 0.001 mA or more, preferably 0.010 mA or more, more preferably 0.100 mA or more, and even more preferably 0.500 mA or more. Is also good.

The upper limit value and the lower limit value of the output current described so far may be combined with each other, for example, 0.001 mA or more and 1000 mA or less, or 0.001 mA or more and 500 mA or less.
Based on the current value flowing through the sensor electric path 16, the power measuring unit 12 calculates the current value flowing through the predetermined electric path to be measured, and the power measuring unit 12 (electrical device 11) passes through the instrument transformer 22b or the like. It can be said that the power measuring unit 12 measures the electric power in the predetermined electric line by applying the voltage value of the predetermined electric line input to.

<Open / close type detector 17>
As shown in FIGS. 17 and 18, the open / close type detector 17 is a detector that can be attached to the above-mentioned predetermined electric circuit without breaking the predetermined electric circuit.
That is, the open / close type detector 17 can be easily retrofitted by opening and closing itself without opening a predetermined electric circuit to be measured.

At the same time, since the open / close type detector 17 is a detector that detects a current in a predetermined electric circuit, if the sensor unit 15 is a fluxgate type, a Hall element type, or the like described above, the fluxgate or Hall It can be said that it is the part that has the element itself.
The open / close type detector 17 may have any shape and configuration as long as it can be attached without breaking the predetermined electric circuit and detects the current in the predetermined electric circuit. For example, the open / close type detector 17 may be attached. The housing of the above has a substantially rectangular parallelepiped shape, and may have a hole (electric circuit hole) penetrating the middle portion of the substantially rectangular parallelepiped.

In this case, a predetermined electric circuit to be measured enters the electric circuit hole of the housing of the open / close type detector 17, and the other end side opens and closes with one end side of the portion surrounding the electric wire hole as an axis.
That is, after opening the other end side of the housing of the open / close type detector 17 and arranging a predetermined electric circuit to be measured in the electric circuit hole, the other end side of the housing is closed.
Further, the open / close type detector 17 may have a fixing member such as a stopper for fixing a predetermined electric circuit.

<Branch line 25>
As shown in FIGS. 17 and 18, the branch electric wire 25 is an electric wire that enables the power generation device 23 described later to be connected to the system board 22 and the load F described above. For example, the material thereof is a vinyl insulated wire for electric equipment. And so on.
The branch electric circuit 25 (in other words, the power generation connection device 24) may be connected to the load F only via the wiring breaker (MCCB) 25'without passing through the transformer F1 described above. It may be possible to connect to the main electric circuit M (in this case, the potential in the branch electric circuit 25 is the same high voltage as the electric potential in the main electric circuit M and the system K (6600V, 22000V, etc.)).
That is, one end side of the branch electric circuit 25 is directly connected to the load F or is connected to the main electric circuit M (an electric circuit at any position between the system board 22 and the load F), and the other end of the branch electric circuit 25. The side may be connected to the output side of the power generation device 23 (the output side (low voltage side) of the transformer 3). In addition, a plurality of branch electric lines 25 may exist in one power plant 21.

<Electrical equipment 11, reverse power G, received power J>
As shown in FIGS. 17 and 18, the electric device 11 measures the reverse power G, and if the measured reverse power G is larger than a predetermined threshold value, it can be said that the electric device 11 is a device that performs a relay operation.
Here, as described above, the reverse power G is the power that flows back from the connection portion 22 to the system K in the power plant 21, and can also be said to be the backflow power G.
When the reverse power G measured by the electric device 11 becomes larger than a predetermined threshold value (so-called “reverse power generation state C1”), the control unit 4 described later performs a relay operation from the power generation device 23 described later to the system K. Any of the above circuit breakers (power generation circuit breaker 25', system circuit breaker 22a, etc.) may be interrupted, or the conversion of the power conditioner 2 described later may be stopped.
When the reverse power G larger than a predetermined threshold value is measured by the electric device 11, when the above-mentioned circuit breaker is cut off by hardware (for example, via a trip coil or the like), the electric device 11 itself. However, it can be said that it is the control unit 4 described later.

Further, as shown in FIGS. 17 and 18, it can be said that the electric device 11 is a device that measures the received power J as well as the reverse power G.
Here, the received power J is the power received from the system K described above to the system board 22, and can be said to be the received power (purchased power) J.

<Other devices in the power generation connection device 24>
The power generation meter is a power meter that measures the power generation H, and may be provided as a power generation connection device 24.
Here, the generated power H is the power output from the power generation device 23 described later, and can be said to be the generated power H.

The power generation meter may have any configuration as long as it can measure the power generation H. For example, the power generation meter can be connected to the low-voltage side of the instrument transformer 22b built in the system board 22 described above, and , May be connected to the output side of a power generation transformer provided in the branch electric circuit 25, which will be described later.
Such a wattmeter is, for example, an overcurrent relay (OCR, Over Current Relay, so-called power generation OCR) connected to a power transformer described later, or an ammeter (so-called so-called) connected to this overcurrent relay. , Power generation ammeter), a wattmeter connected to the output side of this ammeter and the low-voltage side of the instrument transformer 22b described above (also called a wattmeter in a narrow sense), digitization of the measured values from this wattmeter, etc. The configuration may also include an output unit that outputs the output to the control unit 4.

The output from the power conditioner 2 described later is controlled by the control unit 4 described later based on the value of the power generation H measured by the power generation meter and the received power J measured by the electric device 11 described above. ..
The output side (high voltage side) of the transformer 3 in the power generation device 23 described later is connected to the branch electric circuit 25 described above. In this case, the measured value of the power generation meter which is the output from the transformer 3 is used. , The generated power H output from the power generation device 23 is assumed to be.
When the control unit 4 is provided inside the power distribution system 1 or the like, which will be described later, the value of the power generation H measured by the power generation meter is determined by the control unit 4 by wire or wirelessly by the communication cable 11A or the like. It may be output to.

The power generation circuit breaker 25'is a circuit breaker such as a high-pressure AC load switch (LBS, Load Break Switch) that cuts off the branch electric circuit 25 (that is, between the power generation device 23 and the system K).
The power generation circuit breaker 25'may have any configuration as long as it cuts off the branch electric circuit 25. For example, the power generation circuit breaker 25'may be rotatable in the front-rear direction in order to improve maintainability, which will be described later. The signal from the control unit 4 (or the electric device 11) may be cut off via a capacitor tripping power supply device, which will be described later, a tripping coil, or the like.
By shutting off the power generation circuit breaker 25'and the system circuit breaker 22a described above, it can be said that the power generation H is not output from the power generation device 23 or the current does not flow from the system board 22 to the system K.

In addition, the power generation connection device 24 may be provided with a capacitor tripping power supply device and a cable bracket.
Furthermore, the power generation connection device 24 may be provided with an insufficient power relay.

The capacitor tripping power supply device (CTD, Condenser Trip Device) in the power generation connection device 24 uses the energy generated when the AC input voltage is rectified and discharged to the capacitor to trip the high-voltage AC load switch or vacuum circuit breaker. The branch electric circuit 25 is cut off by the above-mentioned power generation circuit breaker 25'by the capacitor tripping power supply device.
In this case, it can be said that the capacitor stripping power supply device receives the signal from the control unit 4 (or the electric device 11) described later and cuts off the branch electric circuit 25 by the power generation circuit breaker 25'.

<Electrical equipment 11, insufficient power U>
As described above, since the electric device 11 includes two relay units 13, it also measures the shortage power U in the main electric circuit M, and when the measured shortage power U approaches 0, it can also be used as a device that performs a relay operation. Can be used for both purposes.
Here, the insufficient power U is, as described above, the electric power representing the insufficient amount of the received power J in the system board (connection portion) 22 when a short circuit occurs on the system K side. It can be said that when the power generated from the power generation device 23 described above becomes too large, the insufficient power approaches zero.
When the shortage power measured by the electric device 11 approaches 0 (so-called "shortage power substantially zero state C2"), the control unit 4 described later stops the conversion of the power conditioner 2 described above, or stops the conversion of the power conditioner 2 described above. Any circuit breaker (power generation circuit breaker 25', system circuit breaker 22a, etc.) in the electric circuit from the power generation device 23 to the system K described above may be cut off.
When the shortage power measured by the electric device 11 approaches 0 and the above-mentioned circuit breaker is cut off in terms of hardware (for example, via a trip coil or the like), the electric device 11 itself is used. It can also be said that the control unit 4 will be described later.
Here, "the shortage power U approaches 0 (zero)" in the present invention means that the shortage power U is "greater than 0W (watt) (that is, does not include 0W)" and "less than or equal to a value near 0W". The "value near 0W" in the present invention may be a value larger than 0W, and may be set to a predetermined insufficient power value according to the resolution of the electric device 11. It does not matter, and may be, for example, 1 kW (1000 W), 1 W, 1 mW, 1 μW, or the like.

<Power generation device 23>
As shown in FIGS. 17 and 18, the power generation device 23 according to the present invention is a device that generates power, and the output side thereof is the above-mentioned connection portion (the above-mentioned connection portion () via the above-mentioned power generation connection device 24 and the above-mentioned electric device 11. It is a device that can be connected to the system board) 22 and the load F.
The configuration of the power generation device 23 is not particularly limited as long as it generates power. For example, the power generation device 23 is a solar power generation device 23'that generates power with a solar cell 26'described later, or wind power or wave power (tide power). ), A device that generates electricity with a motor (generator) that is rotated by hydraulic power, thermal power, geothermal power, etc. (wind power generation plant, etc.), or if it is a device that can generate electric power, it means only the solar cell 26'. There may be.

The motor in the wind power generation plant or the like may be either an AC motor or a DC motor.
The power generation device 23 may include a power generation unit 26, a power conditioner 2, a transformer 3, and a control unit 4.

Such a power generation device 23 is connected to the system board 22 and the load F described above via the power generation connection device 24 and the electric device 11.
Hereinafter, the power generation device 23 will be described as being mainly a solar power generation device 23'.

<Solar power generator 23'etc.>
As shown in FIGS. 17 and 18, in addition to having the power plant 21 described above, the photovoltaic power generation device 23'is a power distribution system including a power conditioner 2, a transformer 3, a power distribution frame frame 6, and the like, which will be described later. It may have 1.
In the photovoltaic power generation device 23', the above-mentioned power distribution system 1 is connected to the system K having a steel tower, a utility pole, or the like at the end via the above-mentioned power generation connection device 24, the electric device 11, the system board 22, the distribution cable, or the like. Has been done.

The photovoltaic power generation device 23'may have a plurality of solar cells 26', a power distribution system 1, and the like.
Further, when there are a plurality of solar cells 26', the photovoltaic power generation device 23'may have a plurality of junction boxes (with a breaker or the like) that conduct with each predetermined number of the plurality of solar cells 26'. Instead, each power distribution system 1 is electrically connected to these plurality of junction boxes, but the function of this junction box may be built into the power distribution system 1, and in this case, each power distribution system 1 is connected to a plurality of solar cells. It will be directly conductive with every predetermined number of the batteries 26'.

The solar cells 26', the power distribution system 1, etc. are arranged according to the size and shape of the land to be installed. For example, the power generation of one power distribution system 1 (per power conditioner 2) is 100 kW or more. It may be 180 kW or less, 50 kW or more and 120 kW or less, 30 kW or more and 50 kW or less (or less than 50 kW), and may be a photovoltaic power generation device 23'provided with a plurality of power distribution systems 1.
The weight of the power distribution system 1 is also not particularly limited, but may be, for example, 0.1 tons or more and 5.0 tons or less, that is, 100 kg or more and 5000 kg or less, preferably 150 kg or more and 2000 kg or less, more preferably. May be 200 kg or more and 1000 kg or less (350 kg or the like).
Hereinafter, the power generation unit 26 of the power generation device 23 including the solar power generation device 23'will be described as being mainly a solar cell 26'.

<Power generation unit 26>
As shown in FIGS. 17 and 18, the power generation unit 26 is a part that actually generates power, and if the power generation device 23 is the solar power generation device 23', the solar cell 26'is the power generation unit 26. If the power generation device 23 is a wind power generation plant or the like that generates power with a motor rotated by wind power or the like, the motor is the power generation unit 26.

<Solar cell 26'>
As shown in FIGS. 17 and 18, the solar cell 26'may have a panel shape (flat plate shape) or the like, and is between the positive electrode (+ pole) and the negative electrode (-pole) by being irradiated with light. DC power is generated in the tablet, and the average of the generated power is 100 W or more and 400 W or less (for example, 250 W).
Of these, the positive pole of one solar cell 26'is connected to the negative pole of another solar cell 26', and the positive pole of another solar cell 26'is connected to the negative pole of another solar cell 26'. Hereinafter, this is repeated, and a plurality of (for example, 5 to 20) solar cells 26'are connected in series to form one solar cell string.

In this way, the voltage between the positive pole (power output end) and the negative pole (ground end) of the entire solar cell string in which a plurality of solar cells 26'are connected in series is generated in each solar cell 26'. It is the sum of the DC voltages, and varies depending on the weather, time, deterioration of each solar cell 26', failure, deviation of the installation position, etc., but it is 200 V or more and 1500 V or less.
The power output from the power output end of the solar cell string is the sum of the powers of each solar cell 26', and 14 solar cells 26'with an output power of 250 W are connected. In the case, 3500W = 3.5kW).

Here, connecting the solar cells 26'in series means that if any one of the solar cells 26'is defective, the current will be cut off in the solar cell 26'. , It becomes difficult to output the electric power generated by another solar cell 26'.
Therefore, by providing a bypass diode (not shown) for each of the solar cells 26'connected in series, the current is configured to bypass the defective solar cell 26'.

This bypass diode is connected in parallel to the solar cell 26'in the direction in which current flows from the negative pole to the positive pole. Specifically, the cathode of the bypass diode is the + of the solar cell 26'. Connected to the pole, the anode of the bypass diode is connected to the negative pole of the solar cell 26'.
Such a solar cell 26'may be installed on the installation surface via a gantry.

The installation surface of the solar cell 26'(or the gantry) is the installation surface on which the above-mentioned photovoltaic power generation device 23'itself is installed, and any surface as long as the solar cell 26'can be installed. However, for example, it may be a golf course site, a mountainous land, a vacant lot, a fallow land, an agricultural land, or the like, a ground with soil, a roof or roof of a building, a wall, or the like.
The installation surface of the solar cell 26'may be the installation surface of the system board 22 described above, the same installation surface as the load F, or an installation surface different from the system board 22 and the load F.
Further, in order to increase the amount of power generated by the photovoltaic power generation device 23', the gantry may support the solar cell 26'by tilting it in a predetermined direction (for example, it becomes lower toward the south), and the angle is sufficient. Any number of times can be obtained as long as a large amount of power generation can be obtained, but for example, 10 degrees or 5 degrees.

<Control unit 4>
As shown in FIGS. 1 to 8, 17 and 18, the control unit 4 is a part that controls the power conditioner 2 described above and the connection unit (system board) 22 described later. For example, in the case of the power distribution system 1 described above, the control unit 4 may be a smart logger or the like provided in the cabinet 5, or a sequencer or the like.
The control unit 4 generates power by assuming that the sum of the received power J received from the system K described later to the system board 22 and the generated power H output from the power generation device 23 described above is the power consumption D of the load F. It controls the power generation H (which can be said to be the output of the power conditioner 2) output from the device 23.
When the control unit 4 controls the output of the power conditioner 2 (gives the output target value to the power conditioner 2), the control unit 4 causes a power loss such as a transformer loss (also called a step-up loss) in the transformer 3 described above. The output target value is slightly higher than the power generation target value TH, which is the target value of the actual power generation H (power on the high-voltage side (output side) of the transformer 3 provided with the power generation meter 12) in consideration of the minute. May be given to the power conditioner 2.
Further, the time interval (target giving interval) in which the control unit 4 gives the output target value to the power conditioner 2 may be given at predetermined time intervals (even at a predetermined target giving interval), but for example, 0. The target assignment interval may be 0.1 seconds or less, 0.05 seconds or less, such as every 1 second, every 0.25 seconds, every 1 second, every 5 seconds (here, the target assignment interval is , May be longer or the same as the sampling time described below).

Further, when the reverse power G measured by the electric device 11 described above becomes larger than a predetermined threshold value (that is, when the “reverse power generation state C1” is reached), the control unit 4 stops the conversion of the power conditioner 2 described above. Alternatively, any circuit breaker (power generation circuit breaker 25', system circuit breaker 22a, etc.) in the electric circuit from the power conditioner 2 to the system K described above may be interrupted.
In addition, when the shortage power U measured by the electric device 11 described above approaches 0 (that is, when the “shortage power substantially zero state C2” is reached), the control unit 4 stops the conversion of the power conditioner 2 described above. Alternatively, any circuit breaker (power generation circuit breaker 25', system circuit breaker 22a, etc.) in the electric circuit from the power conditioner 2 to the system K described above may be interrupted.

When the conversion of the power conditioner 2 is stopped, it is not necessary to match the output from the power conditioner 2 with the voltage, phase, etc. of the system K when the conversion stop is restarted. Therefore, the power conditioner 2 It is possible to restore the power plant 21 in a shorter time and with less effort than in the case of interrupting any of the electric circuits from to system K (shortening and facilitating system restoration). I can say.
In addition, when the control unit 4 cuts off a circuit breaker such as the power generation circuit breaker 25'in hardware when the reverse power generation state C1 is reached, it can be said that the reverse power relay 10 is included in the control unit 4. .. This is because, as described above, the circuit breaker is cut off in hardware when the undervoltage relay detects an undervoltage, or the circuit breaker is cut off in hardware when an overvoltage is detected in the overvoltage relay. The same applies when the circuit breaker is cut off by hardware when the undervoltage relay detects an undervoltage, or when the circuit breaker is cut off by hardware when an overvoltage is detected by the overvoltage relay. Therefore, it can be said that these undervoltage relays, overvoltage relays, undervoltage relays, and overfrequency relays are included in the control unit 4.

The control unit 4 may use any control method as long as it controls the power conditioner 2 with the sum of the received power J and the generated power H as the power consumption D. For example, the following equation ( The target upper limit value (power generation target upper limit value) THmax of the power generation H may be derived based on 1) or the equation (2).
In the equations (1) and (2), the received power J, the generated power H, the limiting coefficient A (the limiting coefficient A applied to the sum of the received power J corresponding to the load power D and the generated power H), and the fluctuation correspondence Assuming that the constant B changes with time t, the received power is J (t), the generated power is H (t), the limiting coefficient A (t), and the fluctuation response constant is B (t). , The unit of each of the received power J (t), the generated power H (t), and the fluctuation correspondence constant B (t) is kW or the like.

Here, the received power J (t) and the generated power H (t) may be measured at predetermined time intervals (even at a predetermined sampling time) by the above-mentioned electric device 11, a power generation meter, or the like. For example, the sampling time is 0.1 seconds or less, 0.05 seconds or more and 2.00 seconds or less, 0.75, such as every 0.1 seconds, every 0.25 seconds, every 1 second, every 5 seconds. It may be seconds or more and 1.50 seconds or less, and 0.10 seconds or more and 1.00 seconds or less.
The limiting coefficient A (t) is not particularly limited, but is, for example, a value of 0 or more and 1 or less (that is, 0% or more and 100% or less, 90% or 95%, 98%, 99%, 100%, etc., or 80. % Or more and 100% or less, 90% or more and 100% or less, 95% or more and 100% or less, etc.), and the fluctuation correspondence constant B (t) is not particularly limited, but is, for example, 0 kW or more and 20 kW or less. It doesn't matter if there is.
The limiting coefficient A (t) may be 99% or more and 100% or less (for example, 99.0%, 99.5%, 99.8%, 99.9%, etc.), or the limiting coefficient A (t) may be set as much as possible. If it can be approached to 100%, it is desirable that the received power (power to be purchased) J is suppressed as much as possible (cost can be reduced).

The limiting coefficient A (t) and the fluctuation correspondence constant B (t) do not have to be finely changed for each predetermined sampling time. For example, the limiting coefficient A (t) does not have to be finely changed for each predetermined sampling time. More specifically, "from midnight to 9 am" and "from 5 pm to 12 pm" in the day are A (t) = 1.00 (100%). B (t) = 0 kW or the like, and “from 9:00 am to 5:00 pm” may be A (t) = 0.90 (90%), B (t) = 10 kW or the like.
Such a control unit 4 has a maximum power so that the power generation H actually output from the power conditioner 2 becomes the power generation target upper limit value THmax derived by the above equations (1) and (2). Point tracking control (MPPT (Maximum Power Point Tracking) Control) or the like may be performed.

<Target value of power generation H (target value of power generation) TH>
On the other hand, as shown in FIG. 4, the control unit 4 causes the power generation device 23 to generate a power generation H that is as close to the load power D as possible and a power generation H that has the same value as the load power D (limit coefficient A (limitation factor A (). When t) is set to 99% or more and 100% or less, or the limit coefficient A (t) is set as close to 100% as possible), when the power generation H is controlled, the power condition is adjusted when the load power D decreases. Even if the power generation target value TH that controls the power generation 2 and lowers the power generation H is given, the actual power generation H does not decrease immediately (the decrease in the power generation H is delayed), so the power generation H is increased by the delay. It is necessary to suppress that the load power D becomes larger than the load power D and the reverse power G is generated (power that cannot be consumed by the load F flows to the system K).
In addition, it takes time and effort to match the output from the power conditioner 2 with the voltage and phase of the system K when reconnecting after shutting off with the power generation breaker 25'or the like. As a result, the power generation H (the amount of power that can be generated) is reduced as a whole, and the power generation H (power conditioner 2) is generated by the control unit 4 so as not to be cut off by the power generation breaker 25'or the like as much as possible. It is desirable to control.

Therefore, when the power generation H is lowered, the control unit 4 is lower than the value at which the power generation H is set to zero and / or the power consumption (load power) D of the load F when the power generation H is lowered. The value may be once set as the target value (power generation target value) TH of the power generation H.
By controlling by the control unit 4 in this way, the actual decrease in the generated power H is not delayed, and the generated power H is less likely to be larger than the power consumption D of the load F. Therefore, the reverse power G is generated (consumed by the load F). It is possible to suppress the flow of power that cannot be performed to the system K).

More specifically, the control unit 4 sets a value that makes the power generation H zero for the first few seconds (5 seconds, etc.) of the delay of about 15 seconds. , Once the power conditioner 2 etc. is controlled as the power generation target value TH (“zero target value control”), and then (about 10 seconds, etc.), the received power J and the generated power H are measured every second. The power conditioner 2 and the like may be controlled by using the load power D itself calculated from the sum of the above as the power generation target value TH.
Of course, the time for controlling the zero target value is not limited to the first 5 seconds, but is only the first 1 second, or 0.1 seconds or more and 10.0 seconds such as the first 3 seconds or 7 seconds. It may be as follows.

In addition, for example, the control unit 4 sets a value lower than the load power D when lowering the power generation H for the first few seconds (5 seconds, etc.) of the delay of about 15 seconds as the power generation target value TH. After controlling the conditioner 2 and the like (“low target value control”), after that (about 10 seconds, etc.), the load power D itself calculated from the sum of the received power J and the generated power H measured every second is used. , The power conditioner 2 or the like may be controlled as the power generation target value TH.
Of course, the time for controlling the low target value is not limited to the first 5 seconds, but is limited to the first 1 second, or 0.1 seconds or more and 10.0 seconds, such as the first 3 seconds or 7 seconds. It may be as follows.
Further, the “value lower than the load power D when lowering the generated power H”, which is the power generation target value TH, is not particularly limited as long as it is lower than the load power D, but for example, the load power D measured for each sampling time. (Sum of received power J and generated power H) is 1% or more and 99% or less, preferably 5% or more and 95% or less, and more preferably 10% or more and 90% or less (20%, 50%, 70%, etc.). You may.

In addition, the above-mentioned zero target value control and low target value control may be combined. For example, the control unit 4 controls the zero target value only for the first few seconds (5 seconds, etc.) of the delay of about 15 seconds. After that (for about 10 seconds, etc.), low target value control may be performed.
Naturally, the time for controlling the zero target value is not limited to the first 5 seconds, but is only the first 1 second, or 0.1 seconds or more and 10.0 seconds such as the first 3 seconds or 7 seconds. Of course, the time for controlling the low target value after that may be not limited to the last about 10 seconds, but may be the last about 14 seconds, the last about 12 seconds, about 8 seconds, and the like. , It may be about 5 seconds or more and about 14 seconds or less.

Here, at the timing (trigger) of performing zero target control or low target value control, the load power D (sum of the received power J and the generated power H) suddenly becomes 2% or more and 10% or less of the received power J (for example,). When the change (or decrease) (greater than 2%), the zero target value control or the low target value control may be started.
The control unit 4 may be provided in any of the power generation plants 21 as long as it is provided, but for example, the control unit 4 may be provided in the power distribution system 1 described above.

<Power plant 21 of the second embodiment>
19 and 20 show the power plant 21 according to the second embodiment of the present invention.
The most different from the first embodiment in this second embodiment is the high voltage AC load switch (LBS) 22a'instead of the LBS power receiving type (instead of the high voltage disconnector (VCB) 22a) that receives high voltage power with a capacity of 300 kVA or less. At the same time, it is a type that does not have a disconnector 22e, an instrument transformer 22f, a high-voltage AC load switch F2, etc.).

Further, in the second embodiment, the sensor unit 15 (open / close type detector 17) in the electric device 11 is not directly on the output side (secondary side) of the instrument transformer 22f in the connection unit (system panel) 22. The point that it is attached to the main electric circuit M from the system K to the load F (particularly, the electric circuit between the instrument transformer 22h and the system K in the system panel 22) is also different from the first embodiment. There is.
Other power plant 21, electrical equipment 11, distribution system 1, power generation device 23, power generation connection device 24, power generation unit 26, power conditioner 2, transformer 3, control unit 4, cabinet 5, etc. The usage mode is the same as that of the first embodiment.

<Power plant 21 of the third embodiment>
21 and 22 show the power plant 21 according to the third embodiment of the present invention.
The most different from the first and second embodiments in this third embodiment is the low voltage power receiving type (high voltage circuit breaker (VCB) 22a, high voltage AC load switch (LBS) 22a', for instruments) having a capacity of less than 50 kW. Instead of the transformer current transformer 22h, it has a circuit breaker for wiring (MCCB) 22a "and a meter for trading 22h', and at the same time, it does not have a zero-phase detector 22z, a ground fault overvoltage relay 33, a step-down transformer F1 and the like. Type).

Further, in the third embodiment, the pole transformer (step-down transformer) K'is provided in the electric circuit between the instrument transformer 22h and the system K, and at the same time, the sensor unit 15 in the electric device 11 is provided. (Open / close type detector 17) is also different from the first and second embodiments in that it is attached to the electric circuit between the instrument transformer current transformer 22h and the wiring breaker (MCCB) 22a ”. ..
Other power plant 21, electrical equipment 11, distribution system 1, power generation device 23, power generation connection device 24, power generation unit 26, power conditioner 2, transformer 3, control unit 4, cabinet 5, etc. The usage mode is the same as that of the first and second embodiments.

<Others>
The present invention is not limited to the above-described embodiments. The structure, shape, dimensions, etc. of each configuration or the entire configuration of the power distribution system 1, the power plant 21, the transformer 3, the cabinet 5, etc. can be appropriately changed according to the gist of the present invention.
The power conditioner 2 and the transformer 3 of the power distribution system 1 are other than the power distribution frame frame 6 described above as long as at least three directions of the power conditioner 2 and the transformer 3 are opened to the outside of the system in a plan view. It may be supported by a supporting member, for example, it may be supported by a power distribution frame plate body, or it may be supported by a substantially rectangular parallelepiped supporting member or the like.
The power distribution system 1 does not have to have the control unit 4, the cabinet 5, the roofing material 6e, and the electrical equipment 11.

Each of the power conditioner 2, the transformer 3, and the cabinet 5 may have a plan view shape (substantially square shape, substantially circular shape, etc.) having no longitudinal direction L, L', L ".
The transformer 3 may transform (boost) the alternating current from the power conditioner 2 to a higher voltage alternating current, and in this case, the transformer 3 can be said to be a so-called step-up transformer.
The transformer 3 (ie, the distribution system 1) may be mounted on a foundation. In this case, the foundation may be made of any material such as concrete or steel (H steel), and its shape may be a solid foundation having a uniform thickness, a dent so as to form a space below the transformer 3, and the like. It may be a geta foundation having.
When the foundation of the transformer 3 is a geta foundation, more air is discharged from the notch 3b of the transformer 3 and the recess of the geta foundation and the lower opening of the transformer cylinder 3a of the transformer 3. Since it flows into the inside of 3a, the cooling property is further improved.

The transformer cylinder 3a of the transformer 3 does not have to have a notch 3b formed in the lower front portion thereof, and the notch 3b is a place other than the lower front portion of the transformer cylinder 3a (for example, the left side surface of the transformer cylinder 3a). It may be formed in the lower part, the lower part of the right side surface, the lower part of the rear surface, etc.).
It is not necessary that a hanging member such as a hook or a ring is provided on the upper surface of the upper lid 3c of the transformer 3.
The transformer cylinder 3a of the transformer 3 does not have to be provided with a cable hole 3d at the lower rear portion or the lower front portion of the side surface (right side surface). In this case, the cable is pulled in from the notch 3b of the transformer 3 or the like. It doesn't matter.
Further, the cable hole 3d may be provided at another location in the transformer cylinder 3a.

The transformer 3 of the first embodiment may have the base 3f of the transformer 3 of the second embodiment.
The transformer 3 of the second embodiment may have at least one of a heat shield plate 3g and a mounting plate 3h.
In the transformer 3 of the first and second embodiments, the cover body 3Q may be composed of all of the above-mentioned transformer cylinder body 3a, upper lid 3c, and base 3f, but these transformer cylinders 3a, upper lid 3c, and base 3f It may be composed of at least one of.
Further, in the cover body 3Q of the transformers 3 of Examples 1 and 2, the transformer cylinder body 3a, the upper lid 3c, and the base 3f may be separated from each other, or conversely, the transformer cylinder body 3a and the upper lid may be separated from each other. The 3c and the base 3f may be integrated.
The cover body 3Q of the transformer 3 of Examples 1 and 2 has another member (for example, for example) that covers the iron core 3X, the coil 3Y, the terminals, and the like, in addition to the members of the transformer cylinder body 3a, the upper lid 3c, and the base 3f described above. It may include a bottom plate, etc.).
The upper surface of the upper lid 3c of the transformer 3 of Examples 1 and 2 may be heat-shielded.

The control unit 4 does not have to be provided in the cabinet 5, and may be provided in, for example, the power conditioner housing of the power conditioner 2 or the transformer cylinder 3a of the transformer 3.
The cabinet 5 does not have to have the opening / closing door 5a on the front surface, and the cabinet 5 may have the opening / closing door 5a on any one surface such as the front surface, the left side surface, the rear surface, and the right side surface of the cabinet 5.
A power generation meter may also be provided inside the cabinet 5.

The electric device 11 does not include the sensor unit 15 described above, and may detect a current in a predetermined electric circuit by a member other than the sensor unit 15 (for example, a member in the device housing 14).
The electric device 11 does not have to have the output unit described above.
The electrical equipment 11 includes a system board 22 such as a power purchase board, an extra-high board (extra-high equipment), a high-voltage board (high-voltage equipment), a low-voltage board (low-voltage equipment), a monitoring board (monitoring equipment), and a control board (control). Equipment), substation (substation equipment), equipment for buildings and apartments, power receiving board (particularly existing power receiving board), lighting distribution board, and these boards are provided by electrical equipment 11. It can be said that it is a board according to the present invention having those board supports (board housing and board frame body).

The power measured by the power measuring unit 12 includes the reverse power G in the main electric line M from the system K to the load F via the connection unit 22, the insufficient power U, and the received power (purchased power) J, as well as the power generation device 232. It may be the power generation H output from (the power generation H in the electric circuit other than the main electric circuit M), and the load power D consumed by the load F (the load electric power D in the electric circuit other than the main electric circuit M). It doesn't matter.
The sensor unit 15 does not necessarily have to include the sensor electric path 16 and the open / close type detector 17 described above, and in particular, the detector may be a detector that does not open / close.
The power plant 21 may have a storage battery, a fuel cell, a generator powered by fuel such as gasoline, or the like.

The power distribution system of the present invention can be used for a self-consumed photovoltaic power generation device or the like regardless of the amount and scale of the power generation. In addition to the self-consumed photovoltaic power generation device, a non-self-consumed photovoltaic power generation device It can also be used in devices that generate electricity using generators (AC motors, etc.) that are rotated by wind power, hydraulic power, wave power, geothermal power, etc., and can be used both outdoors and indoors.
The power generation plant of the present invention can be used for a self-consumed photovoltaic power generation device regardless of the amount and scale of the power generation, and other than the self-consumed photovoltaic power generation device, a non-self-consumed photovoltaic power generation device. It can also be used in devices that generate electricity using generators (AC motors, etc.) that are rotated by wind power, hydraulic power, wave power, geothermal power, etc., and can be used both outdoors and indoors.
The transformer of the present invention can be used for a self-consumed photovoltaic power generation device or the like regardless of the amount and scale of the power generation. In addition to the self-consumed photovoltaic power generation device, a non-self-consumed photovoltaic power generation device It can also be used in devices that generate electricity using generators (AC motors, etc.) that are rotated by wind power, hydraulic power, wave power, geothermal power, etc., and can be used both outdoors and indoors.
The cabinet of the present invention can be used for a self-consumable photovoltaic power generation device regardless of the amount and scale of the power generation, and in addition to the self-consumption type photovoltaic power generation device, a non-self-consumption type photovoltaic power generation device or the like. It can be used in devices that generate electricity with a generator (AC motor, etc.) that is rotated by wind power, hydraulic power, wave power, geothermal power, etc., and can be used both outdoors and indoors.

1 Power distribution system 2 Power conditioner 3 Transformer 3a Transformer cylinder (transformer cover)
3c Transformer top cover (transformer cover)
3e Transformer cabinet electric circuit (transformer output electric circuit)
3f Transformer base (transformer cover)
3g Heat shield plate inside the transformer (intermediate plate-shaped member)
3h Mounting plate inside the transformer (intermediate plate-shaped member)
3Q Transformer cover 3X Transformer core 3Y Transformer coil 4 Control 5 Cabinet (part of the cabinet is an intermediate plate member)
21 Power plant 22 Connection (system board)
25 branch electric circuit (transformer output electric circuit)
25'Molded case circuit breaker (circuit breaker that can cut off the transformer output circuit)
26 Power generation unit 35 Circuit breaker for control unit (circuit breaker that can cut off the transformer output circuit)
K system F Load V Transformer output circuit W Breaker that can cut off the transformer output circuit P Intermediate plate-shaped member α Circuit breaker-iron core / coil distance

Claims (12)

A power distribution system having a power conditioner (2) that converts a direct current or an alternating current from the outside of the system into an alternating current, and a transformer (3) that transforms the alternating current from the power conditioner (2). ,
A power distribution system characterized in that at least three directions of the power conditioner (2) and the transformer (3) are open to the outside of the system in a plan view. It has at least a cabinet (5) with a built-in control unit (4) that controls the power conditioner (2).
In plan view, at least the cabinet (5) and the power conditioner (2) have a longitudinal direction.
The power distribution system according to claim 1, wherein the longitudinal direction of the cabinet (5) is at least substantially parallel to the longitudinal direction of the power conditioner (2). The power distribution system according to claim 1 or 2, wherein the power conditioner (2) and the transformer (3) are arranged side by side in the vertical direction. The invention according to any one of claims 1 to 3, wherein all four directions of the power conditioner (2) and / or the transformer (3) are open to the outside of the system in a plan view. Power distribution system. The distribution system has a transformer output circuit that outputs an alternating current transformed by the transformer (3) and a circuit breaker that can cut off the transformer output circuit.
The power distribution system according to any one of claims 1 to 4, wherein a plate-shaped member is arranged between the circuit breaker and the iron core and the coil of the transformer (3). The distribution system has a transformer output circuit that outputs an alternating current transformed by the transformer (3) and a circuit breaker that can cut off the transformer output circuit.
The power distribution system according to any one of claims 1 to 5, wherein the distance between the circuit breaker and the iron core and the coil of the transformer (3) is 30 cm or less. The distribution system has a transformer output circuit that outputs an alternating current transformed by the transformer (3) and a circuit breaker that can cut off the transformer output circuit.
The power distribution system according to any one of claims 1 to 6, wherein the circuit breaker and the iron core and the coil of the transformer (3) are arranged inside the same cover body. A power distribution system having a power conditioner (2) that converts a direct current or an alternating current from the outside of the system into an alternating current, and a transformer (3) that transforms the alternating current from the power conditioner (2). ,
The distribution system has a transformer output circuit that outputs an alternating current transformed by the transformer (3) and a circuit breaker that can cut off the transformer output circuit.
A power distribution system characterized in that the circuit breaker and the iron core and coil of the transformer (3) are arranged inside the same cover body. The power distribution system according to claim 7 or 8, wherein a heat shield plate is arranged between the circuit breaker and the iron core and the coil of the transformer (3). A power plant having the power distribution system (1) according to any one of claims 1 to 9 and a connection portion (22) connected to a system (K) and a load (F), respectively.
A power plant characterized in that a power generation unit (26) is connected to the load (F) via the power distribution system (1). A transformer that transforms alternating current
The transformer has an electric circuit conducting with the iron core and the coil of the transformer, and a circuit breaker capable of interrupting the electric circuit.
A transformer characterized in that the circuit breaker and the iron core and coil of the transformer are arranged inside the same cover body. A cabinet with a built-in control unit (4) that controls at least an external power conditioner.
The cabinet is characterized in that it does not have a built-in circuit breaker capable of cutting off an electric circuit, or has only one built-in circuit breaker.

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