JP7000227B2 - Power system - Google Patents

Description

The present invention relates to a power system capable of connecting a power supply facility to a consumer premises.

Consumers receive electricity (commercial power) from electric power companies and use electricity in load equipment (general electric facilities) on the premises. Further, it is also possible to install a power generation facility such as a solar power generation facility on the premises to operate the load facility (for example, Patent Document 1) and sell the surplus electric power to the electric power company.

Japanese Unexamined Patent Publication No. 2013-247737

As a power generation facility such as a photovoltaic power generation facility or a power supply facility using a battery, a single-phase three-wire system 100V / 200V (hereinafter, simply referred to as a single-phase three-wire system) is used. In addition, a small output power supply facility may be installed on one of the voltage lines and the neutral line of the single-phase three-wire system.

When a very large load facility is connected, the current is limited by the earth leakage breaker on the primary side of the internal wiring to prevent the current exceeding the allowable current (overcurrent withstand) of the internal wiring from flowing from the power system. ing. However, when the above-mentioned power supply equipment is connected to the premises, the power is interchanged only in the premises, and the power to the load equipment is partially supplied, the overcurrent limited based on the rated breaking current of the earth leakage breaker is used. A current exceeding the withstand capacity may flow to the internal wiring, causing heat generation and deterioration of durability.

In view of such a problem, the present invention can prevent a current exceeding the overcurrent capacity from flowing through the existing internal wiring even if the power supply equipment is connected to the internal wiring on the leakage breaker side of the load equipment. The purpose is to provide a possible power system.

In order to solve the above problems, the power system of the present invention that supplies the power of the power system to the load equipment through the leakage breaker and the single-phase three-wire internal wiring connected to the secondary side of the leakage breaker is the internal wiring. Power supply equipment connected to the leakage breaker side from the load equipment on the voltage line and neutral line, equipment current meter that measures the equipment current flowing through the power supply equipment, and power supply equipment at the power receiving point on the primary side of the leakage breaker. Power so that the sum of the installed current and the receiving point current of the receiving point current meter that measures the receiving point current flowing through the connected voltage line is less than or equal to the rated breaking current of the leakage breaker or the overcurrent withstand of the internal wiring. It is characterized by including a control unit that limits the output of the supply equipment.

In order to solve the above problems, the other power system of the present invention that supplies the power of the power system to the load facility through the leakage breaker and the single-phase three-wire internal wiring connected to the secondary side of the leakage breaker is used. The power supply equipment connected to the leakage breaker side from the load equipment in the two voltage lines of the internal wiring, the equipment current meter that measures the equipment current flowing through the power supply equipment, and the voltage at one of the receiving points on the primary side of the leakage breaker. A first receiving point current meter that measures the first receiving point current flowing through the line, a second receiving point current meter that measures the second receiving point current flowing through the other voltage line at the receiving point, and equipment current and the first receiving point current. Limit the output of the power supply equipment so that both the sum of the point current and the sum of the equipment current and the second receiving point current are equal to or less than the rated breaking current of the leakage breaker or the overcurrent withstand capacity of the internal wiring. It is characterized by including a control unit.

The control unit limits the output of the power supply equipment so that it follows the rated breaking current of the earth leakage breaker or the overcurrent withstand of the internal wiring, or the predetermined current less than the rated breaking current of the earth leakage breaker or the overcurrent withstand of the internal wiring. You may do so.

According to the present invention, even if the power supply equipment is connected to the internal wiring on the leakage breaker side of the load equipment, it is possible to prevent a current exceeding the overcurrent withstand from flowing through the existing internal wiring.

It is explanatory drawing which showed the basic connection mode of the electric power system. It is explanatory drawing for demonstrating connection mode of power supply equipment as a comparative example. It is explanatory drawing for demonstrating connection mode of power supply equipment. It is explanatory drawing for demonstrating connection mode of power supply equipment as a comparative example. It is explanatory drawing for demonstrating connection mode of power supply equipment. It is explanatory drawing which showed the basic connection mode of the electric power system. It is explanatory drawing for demonstrating connection mode of power supply equipment as a comparative example. It is explanatory drawing for demonstrating connection mode of power supply equipment. It is explanatory drawing for demonstrating connection mode of power supply equipment. It is explanatory drawing which showed the basic connection mode of the electric power system. It is explanatory drawing for demonstrating connection mode of power supply equipment as a comparative example. It is explanatory drawing for demonstrating connection mode of power supply equipment. It is explanatory drawing for demonstrating connection mode of power supply equipment.

Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The dimensions, materials, other specific numerical values, etc. shown in the embodiment are merely examples for facilitating the understanding of the invention, and do not limit the present invention unless otherwise specified. In the present specification and the drawings, elements having substantially the same function and configuration are designated by the same reference numerals to omit duplicate explanations, and elements not directly related to the present invention are not shown. do.

(First Embodiment)
FIG. 1 is an explanatory diagram showing a basic connection mode of the power system 100. The electric power system 100 receives electricity (commercial electric power) from the electric power system 14 through the drop line 12. The power system 100 is configured for each consumer of low-voltage power reception, and its scope is not limited to houses and the like as long as it is a general electric facility, such as hospitals, factories, hotels, leisure facilities, commercial facilities, and condominiums. It may be a building unit or a part of a building.

Further, the power system 100 includes a power meter 112, a distribution board 114, and a premises wiring 116.

The watt-hour meter 112 is connected to the power system 14 via a lead-in wire 12 and measures the current value of the current flowing (consumed and sold) between the lead-in wire 12 and the electric power system 100.

The distribution board 114 is connected to the power meter 112 and indicates the contracted capacity. The leakage breaker 114a, the leakage breaker 114b that cuts off the supply of electricity in response to the detection of leakage, and the internal wiring (main bar) 114c. It has a wiring (safety) breaker 114d that is connected to the breaker 114b and cuts off the supply of electricity when the current flowing through the premises wiring 116 exceeds the rated breaking current. Here, the earth-leakage breaker 114b includes both the concept of an earth-leakage circuit breaker with an earth-leakage circuit breaker and an earth-leakage circuit breaker having only an earth-leakage circuit breaker (hereinafter, for convenience of explanation, the earth-leakage breaker 114b will be simply referred to as an earth-leakage circuit breaker 114b. ).

The consumer connects one or more load facilities 16 to each of the premises wiring 116, and receives power through the service breaker 114a, the leakage breaker 114b, the internal wiring 114c, the wiring breaker 114d, and the premises wiring 116. In such a configuration, the relationship is that the rated breaking current of the earth leakage breaker 114b ≧ the overcurrent withstand capacity of the internal wiring 114c> the rated breaking current of the wiring breaker 114d.

Here, it is considered to further connect the power supply equipment 120 to the power system 100. In this case, the power system 100 includes the power meter 112, the distribution board 114, the premises wiring 116, and the power supply facility 120. The power supply facility 120 can supply power to the load facility 16 in preference to the power system 14. Examples of the power supply facility 120 include renewable energy power generation facilities such as solar power generators, wind power generators, hydroelectric power generators, geothermal power generators, solar heat generators, and atmospheric heat generators, fuel cells, and internal combustion power generation. , Storage batteries and the like can be used.

FIG. 2 is an explanatory diagram for explaining a connection mode of the power supply equipment 120 as a comparative example. In the single-phase three-wire distribution system shown in FIG. 2, between the first voltage line (R phase) and the neutral line (N phase) of one of the two voltage lines, and the second voltage of the other. The voltage between the wire (T phase) and the neutral wire (N phase) is 100V, and the voltage between the first voltage line and the second voltage line is 200V. In the following description, the first voltage line is the R phase and the second voltage line is the T phase, but it goes without saying that the first voltage line can be replaced with the T phase and the second voltage line can be replaced with the R phase.

When the power supply facility 120 having a 100V output is connected to the power system 100, the power supply facility 120 is, for example, a second voltage line (or a first voltage line) immediately after the secondary side of the earth leakage breaker 114b in the internal wiring 114c. And the neutral wire are connected via a separate individual breaker 114e. Therefore, the power supply facility 120 is on the primary side of the load facilities 16a, 16b, 16c when viewed from the leakage breaker 114b in the second voltage line and the neutral line of the internal wiring 114c (the leakage breaker 114b side of the load facilities 16a, 16b, 16c). Will be connected to. Here, based on the power supply direction from the power system, the power system side of the equipment is defined as the primary side, and the opposite side is defined as the secondary side.

The power supply facility 120 includes a power generation unit 120a, an equipment ammeter 120b, and a control unit 120c. The power generation unit 120a is composed of, for example, a fuel cell or the like, and converts other energy into electric energy to generate electricity. The equipment ammeter 120b is composed of, for example, a current transformer (CT) and a rectifier, and measures a current output from the power generation unit 120a (hereinafter referred to as equipment current). The control unit 120c is composed of a semiconductor integrated circuit including a central processing unit (CPU), a ROM in which a program or the like is stored, a RAM as a work area, and the like, and controls the output (current) of the power generation unit 120a based on the installed current. do. By connecting such a power supply facility 120 to the internal wiring 114c, the power supply facility 120 can supply the power to the load facility 16 which is insufficient only by the power system.

However, on the other hand, when power is supplied from the power supply facility 120, a current exceeding the overcurrent withstand capacity limited based on the rated breaking current of the leakage breaker 114b may flow to the internal wiring 114c.

With reference to FIG. 2, for example, it is assumed that the load equipment 16a consumes 3A (300W) and the load equipments 16b and 16c consume 35A (3500W) in total. Here, for convenience of explanation, the consumption of the other load equipment 16 is not considered. At this time, it is assumed that the rated breaking current of the earth leakage breaker 114b and the overcurrent withstand capacity of the internal wiring 114c are 30A.

Here, when power equivalent to a current value of 10 A is supplied from the power supply facility 120 to the load facility 16b through the interconnection phase, power corresponding to a maximum of 25 A is supplied from the power system to the load facility 16b. Specifically, 3A flows through the first voltage line, 22A flows through the neutral line, and 25A flows through the second voltage line (the direction of the current does not matter). At this time, the power supply facility 120 is operating within the rating, and the current flowing through each single-phase three-wire system (first voltage line, neutral line, second voltage line) is also the rated breaking current 30A of the earth leakage breaker 114b. There is no problem because it is as follows.

However, in the portion of the internal wiring 114c shown by the thick line in FIG. 2, the maximum current corresponding to the sum of the current of the power supply facility 120 and the receiving point current (current supplied from the power system) (for example, 35A). ) Flows, and the current value may exceed the overcurrent withstand capacity of 30 A of the internal wiring 114c. Then, it may cause heat generation and deterioration of durability of the internal wiring 114c.

Therefore, in the present embodiment, by controlling the output of the power generation unit 120a, it is possible to prevent a current exceeding the overcurrent withstand capacity from flowing through the existing internal wiring 114c.

FIG. 3 is an explanatory diagram for explaining a connection mode of the power supply equipment 120. Here, for example, a first power receiving point current meter 130a for measuring the current of the first voltage line (hereinafter referred to as a first receiving point current) provided in advance on the primary side (power receiving point) of the leakage breaker 114b, and , Of the second receiving point current meter 130b for measuring the current of the second voltage line (hereinafter referred to as the second receiving point current), in the second voltage line to which the power supply facility 120 is connected (which is an interconnection phase). A second receiving point current meter 130b is used. The first receiving point ammeter 130a and the second receiving point ammeter 130b are composed of a current transformer (CT) and a rectifier.

Then, in the control unit 120c of the power supply equipment 120, the sum of the equipment current measured by the equipment ammeter 120b and the second power receiving point current measured by the second power receiving point ammeter 130b is the rating of the earth leakage breaker 114b. The output of the power generation unit 120a is limited so that it is equal to or less than the breaking current.

For example, as shown in FIG. 3, when the second receiving point current is 25A, the control unit 120c determines that the sum of the second receiving point current 25A and the installed current is 30A or less as the rated breaking current of the earth leakage breaker 114b. That is, the power generation unit 120a is controlled so that the installed current is 5 A or less. Then, the current flowing through all the parts of the internal wiring 114c becomes the overcurrent withstand capacity of 30A or less of the internal wiring 114c, so that it is possible to prevent the current exceeding the overcurrent withstand capacity from flowing through the existing internal wiring 114c, and heat generation and durability. It is possible to prevent deterioration.

At this time, the load equipment 16b and 16c can consume only 30A at the maximum in total, but since it is assumed that the internal wiring 114c can only flow a current equal to or less than the overcurrent withstand capacity, no problem occurs. In this case, it is sufficient to adjust the load of the load equipment 16b and 16c.

Further, the control unit 120c follows a predetermined current in which the sum of the installed current and the second power receiving point current is less than the rated breaking current of the earth leakage breaker 114b of 30A or the rated breaking current of the earth leakage breaker 114b, for example, 28A. As such, the output of the power supply facility 120 may be limited. With this configuration, when the receiving point current increases, the equipment current can be reduced (suppressed) by that amount, and conversely, when the receiving point current decreases, the equipment current can be increased by that amount. In this way, while making the best use of the output of the power supply facility 120, it is possible to prevent a current exceeding the overcurrent capacity from flowing through the existing internal wiring 114c.

Here, an example of using a second receiving point ammeter 130b for measuring the current of the second voltage line has been described, but it is sufficient to measure the current of the voltage line to which the power supply facility 120 is connected. For example, when the power supply facility 120 is connected to the first voltage line, the first power receiving point ammeter 130a may be used.

Further, in the single-phase three-wire system, if the current of any two of the three wires (first voltage line, neutral wire, second voltage line) can be grasped, the current of the other one wire is derived by calculation. can. Therefore, a first receiving point ammeter 130a and an ammeter for measuring the current flowing through the neutral line are prepared, and the current of the second voltage line is derived from the first receiving point current and the current flowing through the neutral line. May be.

(Second embodiment)
In the first embodiment, the example of connecting the power supply equipment 120 having a 100V output has been described, but the power supply equipment 120 having a 200V output can also be connected.

FIG. 4 is an explanatory diagram for explaining a connection mode of the power supply equipment 120 as a comparative example. When the power supply facility 120 having a 200 V output is connected to the power system 100, the power supply facility 120 is connected to, for example, the first voltage line and the second voltage line immediately after the secondary side of the earth leakage breaker 114b in the internal wiring 114c. , Connected via a separate individual breaker 114e. Therefore, the power supply facility 120 is on the primary side of the load facilities 16a, 16b, 16d (the leakage breaker 114b side of the load facilities 16a, 16b, 16d) when viewed from the leakage breakers 114b in the first voltage line and the second voltage line of the internal wiring 114c. ) Will be connected.

Here, as in FIG. 2, when the electric power is supplied from the electric power supply facility 120, a current exceeding the overcurrent withstand capacity may flow to the internal wiring 114c. With reference to FIG. 4, for example, it is assumed that the load equipment 16a and 16d consume 35A (3500W) in total, and the load equipment 16b consumes 20A (2000W). Again, for convenience of explanation, the consumption of the other load equipment 16 is not considered. At this time, it is assumed that the rated breaking current of the earth leakage breaker 114b and the overcurrent withstand capacity of the internal wiring 114c are 30A.

Here, when the power equivalent to the current value of 10A is supplied from the power supply equipment 120 to the load equipments 16a and 16b and the load equipment 16d, the power system supplies the power equivalent to a maximum of 25A to the load equipments 16a, 16b and 16d. Will be. Specifically, 25A flows through the first voltage line, 15A flows through the neutral line, and 10A flows through the second voltage line. At this time, the power supply facility 120 is operating within the rating, and the current flowing through each single-phase three-wire system (first voltage line, neutral line, second voltage line) is also the rated breaking current 30A of the earth leakage breaker 114b. There is no problem because it is as follows.

However, in the portion of the internal wiring 114c shown by the thick line in FIG. 4, a current (for example, 35A) corresponding to the sum of the current of the power supply equipment 120 and the receiving point current flows at the maximum, and the current value is determined by the current value. The overcurrent withstand capacity of the internal wiring 114c may be 30 A or more. Then, as in FIG. 2, there is a risk of causing heat generation and deterioration of durability. Here, as in the power supply equipment 120 with 100V output, in the power supply equipment 120 with 200V output, by controlling the output of the power generation unit 120a, it is possible to prevent a current exceeding the overcurrent withstand from flowing through the existing internal wiring 114c. do.

FIG. 5 is an explanatory diagram for explaining a connection mode of the power supply equipment 120. Here, for example, both the first receiving point ammeter 130a and the second receiving point ammeter 130b are used.

Then, the control unit 120c of the power supply equipment 120 includes the sum of the equipment current measured by the equipment current meter 120b and the first power receiving point current measured by the first power receiving point current meter 130a, and the equipment current. Make sure that the sum of the sum of the second receiving point current and the second receiving point current measured by the second receiving point current meter is less than or equal to the rated breaking current of the leakage breaker 114b (so that the larger one is less than the rated breaking current). , The output of the power generation unit 120a is limited.

Here, since the first receiving point current and the second receiving point current are calculated by ORing, the receiving point current input to the power supply facility 120 is the first receiving point current and the second receiving point current. Even if it is not specified which of the currents is the receiving point current, the output of the power generation unit 120a can be appropriately limited by adopting whichever is larger.

For example, as shown in FIG. 5, when the first receiving point current is 25A and the second receiving point current is 15A, the sum of the first receiving point current 25A having a large value and the installed current is the leakage breaker 114b. The power generation unit 120a is controlled so that the rated breaking current of the above is 30 A or less, that is, the installed current is 5 A or less. Then, the current flowing through all the parts of the internal wiring 114c becomes the overcurrent withstand capacity of 30A or less of the internal wiring 114c, so that it is possible to prevent the current exceeding the overcurrent withstand capacity from flowing through the existing internal wiring 114c, and heat generation and durability. It is possible to prevent deterioration.

Further, in the control unit 120c, both the sum of the installed current and the first receiving point current and the sum of the installed current and the second receiving point current are 30A of the rated breaking current of the earth leakage breaker 114b, or the earth leakage breaker. The output of the power supply facility 120 may be limited to follow a predetermined current less than the rated breaking current of 114b, for example 28A. With this configuration, when the receiving point current increases, the equipment current can be reduced (suppressed) by that amount, and conversely, when the receiving point current decreases, the equipment current can be increased by that amount. In this way, while making the best use of the output of the power supply facility 120, it is possible to prevent a current exceeding the overcurrent capacity from flowing through the existing internal wiring 114c.

Here, an example in which the first receiving point ammeter 130a and the second receiving point ammeter 130b are used has been described. However, in the single-phase three-wire system, if the current of any two of the three wires (first voltage line, neutral wire, second voltage line) can be grasped, the current of the other one wire is derived by calculation. can. Therefore, an ammeter for measuring the current flowing through the neutral wire is prepared, and the first power receiving point ammeter is used by combining the ammeter and the first receiving point ammeter 130a or the current meter and the second receiving point ammeter 130b. A point current or a second receiving point current may be derived.

(Third embodiment)
In the first embodiment and the second embodiment, the power supply equipment 120 will be described with reference to an example of connecting the power supply equipment 120 immediately after the secondary side of the earth leakage breaker 114b in the internal wiring 114c via a separate individual breaker 114e. did. In the third embodiment, an example in which the power supply equipment 120 is arranged at a position corresponding to the downstream side of the earth leakage breaker 114b (the side away from the earth leakage breaker 114b) from the load equipment 16 will be given.

FIG. 6 is an explanatory diagram showing a basic connection mode of the power system 200. Like the power system 100 of FIG. 1, the power system 200 includes a power meter 112, a distribution board 114, a premises wiring 116, and a power supply facility 120. However, here, unlike FIG. 1, the power supply equipment 120 passes through the wiring breaker 114d corresponding to the downstream of the earth leakage breaker 114b from the load equipment 16 to the second voltage line and the neutral line in the internal wiring 114c. Connected (lower interconnection). Therefore, the power supply equipment 120 is located on the secondary side of the load equipment 16 (the side that is not the earth leakage breaker 114b with respect to the load equipment 16) in the second voltage line and the neutral line of the internal wiring 114c when viewed from the earth leakage breaker 114b. You will be connected.

FIG. 7 is an explanatory diagram for explaining a connection mode of the power supply equipment 120 as a comparative example. Here, as in FIGS. 2 and 4, when power is supplied from the power supply equipment 120, a current exceeding the overcurrent withstand capacity may flow to the internal wiring 114c.

With reference to FIG. 7, for example, it is assumed that 25 A (2500 W) is consumed in total in the load equipment 16a and 16d, and 10 A (1000 W) is consumed in the load equipment 16b. From the load facility 16b connected to the second voltage line (interconnected phase) to which the power supply facility 120 is interconnected, to the first voltage line (disconnected phase) to which the power supply facility 120 is not interconnected. The connected load equipment 16a and 16d have a larger load and are closer to the rated breaking current of the earth leakage breaker 114b. Also, here, for convenience of explanation, the consumption of the other load equipment 16 is not considered. At this time, it is assumed that the rated breaking current of the earth leakage breaker 114b and the overcurrent withstand capacity of the internal wiring 114c are 30A.

Here, when power equivalent to a current value of 10A is supplied from the power supply facility 120 to the load facility 16b, 25A flows from the power system to the first voltage line, 25A to the neutral line, and 0A to the second voltage line. (The direction of the current does not matter). At this time, the power supply facility 120 is operating within the rating, and the current flowing through each single-phase three-wire system (first voltage line, neutral line, second voltage line) is also the rated breaking current 30A of the earth leakage breaker 114b. There is no problem because it is as follows.

However, in the portion of the internal wiring 114c that connects the load equipment 16a and the load equipment 16b shown by the thick line in FIG. 7, the maximum current corresponding to the sum of the current of the power supply equipment 120 and the receiving point current ( For example, 35A) may flow, and the current value may be 30A or more withstand overcurrent of the internal wiring 114c. Then, it may cause heat generation and deterioration of durability of the internal wiring 114c. Here, by controlling the output of the power generation unit 120a, it is possible to prevent a current exceeding the overcurrent capacity from flowing through the existing internal wiring 114c.

8 and 9 are explanatory views for explaining the connection mode of the power supply equipment 120. Here, for example, both the first receiving point ammeter 130a and the second receiving point ammeter 130b are used.

Then, the control unit 120c of the power supply equipment 120 has the equipment current measured by the equipment current meter 120b and the first power receiving point ammeter in the first voltage line (disconnected phase) to which the power supply equipment 120 is not connected. The output of the power generation unit 120a is limited so that the sum of the current with the first power receiving point current measured at 130a is equal to or less than the rated breaking current of the leakage breaker 114b.

For example, as shown in FIG. 8, when the first receiving point current is 25A, the control unit 120c has a sum of the first receiving point current 25A and the equipment current of 30A or less as the rated breaking current of the earth leakage breaker 114b. That is, the power generation unit 120a is controlled so that the installed current is 5 A or less. Then, the current flowing through all the parts of the internal wiring 114c becomes the overcurrent withstand capacity of 30A or less of the internal wiring 114c, so that it is possible to prevent the current exceeding the overcurrent withstand capacity from flowing through the existing internal wiring 114c, and heat generation and durability. It is possible to prevent deterioration.

Here, as a condition for limiting the output of the power generation unit 120a, the sum of the equipment current and the first power receiving point current measured by the first power receiving point ammeter 130a in the first voltage line to which the power supply equipment 120 is not connected. The reason for this is as follows.

For example, assuming that the equipment current is X, the current consumed by the load equipment 16a is Y, and the current consumed by the load equipment 16b is Z, the current flowing through each wiring is as shown in FIG. Here, since the current value of X + Y flowing through the portion connecting the load equipment 16a and the load equipment 16b shown by the thick line is the maximum, it is sufficient that X + Y is equal to or less than the overcurrent withstand capacity of the internal wiring 114c. Therefore, the control unit 120c is the first (equal to the current consumption Y of the load equipment 16a) measured by the equipment current X and the first power receiving point ammeter 130a in the first voltage line to which the power supply equipment 120 is not connected. The output of the power generation unit 120a may be limited so that the sum of the current with the receiving point current is equal to or less than the rated breaking current of the leakage breaker 114b.

Further, in the control unit 120c, the sum of the equipment current and the first power receiving point current measured by the first power receiving point current meter 130a in the first voltage line to which the power supply equipment 120 is not connected is the sum of the leakage breaker 114b. The output of the power supply equipment 120 may be limited so as to follow a predetermined current lower than the rated breaking current of 30A or the rated breaking current of the earth leakage breaker 114b, for example, 28A. With this configuration, when the receiving point current increases, the equipment current can be reduced (suppressed) by that amount, and conversely, when the receiving point current decreases, the equipment current can be increased by that amount. In this way, while making the best use of the output of the power supply facility 120, it is possible to prevent a current exceeding the overcurrent capacity from flowing through the existing internal wiring 114c.

Here, an example of using a first receiving point ammeter 130a for measuring the current of the first voltage line has been described, but it is only necessary to measure the current of the voltage line to which the power supply facility 120 is not connected. Sufficiently, for example, when the power supply facility 120 is connected to the first voltage line, the second power receiving point ammeter 130b may be used.

Further, in the single-phase three-wire system, if the current of any two of the three wires (first voltage line, neutral wire, second voltage line) can be grasped, the current of the other one wire is derived by calculation. can. Therefore, a second receiving point ammeter 130b and an ammeter for measuring the current flowing through the neutral line are prepared, and the current of the first voltage line is derived from the second receiving point current and the current flowing through the neutral line. May be.

(Fourth Embodiment)
In the third embodiment, the example of connecting the power supply equipment 120 having a 100V output has been described, but the power supply equipment 120 having a 200V output can also be connected.

FIG. 10 is an explanatory diagram showing a basic connection mode of the power system 300. Like the power system 100 of FIG. 1 and the power system 200 of FIG. 6, the power system 300 includes a power meter 112, a distribution board 114, a premises wiring 116, and a power supply facility 120. However, unlike FIGS. 1 and 6, since the power supply equipment 120 has a 200V output, it cannot be connected to the wiring breaker 114d, and the 200V corresponding to the downstream of the leakage breaker 114b from the load equipment 16 in the internal wiring 114c. It is connected via the interconnection breaker 114f (lower interconnection). Therefore, the power supply equipment 120 is connected to the secondary side of the load equipment 16 when viewed from the leakage breaker 114b in the first voltage line and the second voltage line of the internal wiring 114c.

FIG. 11 is an explanatory diagram for explaining a connection mode of the power supply equipment 120 as a comparative example. When the power supply facility 120 having a 200V output is connected to the power system 300, the power supply facility 120 leaks electricity from the load facilities 16a, 16b, 16d to the first voltage line and the second voltage line in the internal wiring 114c, for example. It is connected via the interconnection breaker 114f corresponding to the downstream of the breaker 114b. Therefore, the power supply facility 120 is connected to the secondary side of the load facilities 16a, 16b, 16d in the first voltage line and the second voltage line of the internal wiring 114c when viewed from the leakage breaker 114b.

Here, as in FIG. 7, when the electric power is supplied from the electric power supply facility 120, a current exceeding the overcurrent withstand capacity may flow to the internal wiring 114c. With reference to FIG. 11, for example, it is assumed that the load equipment 16a and 16d consume 35A (3500W) in total, and the load equipment 16b consumes 10A (1000W). Again, for convenience of explanation, the consumption of the other load equipment 16 is not considered. At this time, it is assumed that the rated breaking current of the earth leakage breaker 114b and the overcurrent withstand capacity of the internal wiring 114c are 30A.

Here, when the power equivalent to the current value of 10A is supplied from the power supply equipment 120 to the load equipments 16a and 16b and the load equipment 16d, the power system supplies the power equivalent to a maximum of 25A to the load equipments 16a, 16b and 16d. Will be. Specifically, 25A flows through the first voltage line, 25A flows through the neutral line, and 0A flows through the second voltage line. At this time, the power supply facility 120 is operating within the rating, and the current flowing through each single-phase three-wire system (first voltage line, neutral line, second voltage line) is also the rated breaking current 30A of the earth leakage breaker 114b. There is no problem because it is as follows.

However, in the portion of the internal wiring 114c shown by the thick line in FIG. 11, a current (for example, 35A) corresponding to the sum of the current of the power supply equipment 120 and the receiving point current flows at the maximum, and the current value is increased. The overcurrent withstand capacity of the internal wiring 114c may be 30 A or more. Then, as in FIG. 7, there is a risk of causing heat generation and deterioration of durability. Here, as in the power supply equipment 120 having a 100V output, in the power supply equipment 120 having a 200V output, by controlling the output of the power generation unit 120a, it is possible to prevent a current exceeding the overcurrent capacity from flowing through the existing internal wiring 114c. do.

12 and 13 are explanatory views for explaining the connection mode of the power supply equipment 120. Here, for example, both the first receiving point ammeter 130a and the second receiving point ammeter 130b are used.

Then, the control unit 120c of the power supply equipment 120 receives the first power in the first voltage line to which the equipment current measured by the equipment ammeter 120b and the load equipments 16a and 16d whose connection points are close to the power supply equipment 120 are connected. The output of the power generation unit 120a is limited so that the sum with the first power receiving point current measured by the point ammeter 130a is equal to or less than the rated breaking current of the leakage breaker 114b.

For example, as shown in FIG. 12, if the first receiving point current is 25A, the control unit 120c has a sum of the first receiving point current 25A and the equipment current of 30A or less as the rated breaking current of the earth leakage breaker 114b. That is, the power generation unit 120a is controlled so that the installed current is 5 A or less. Then, the current flowing through all the parts of the internal wiring 114c becomes the overcurrent withstand capacity of 30A or less of the internal wiring 114c, so that it is possible to prevent the current exceeding the overcurrent withstand capacity from flowing through the existing internal wiring 114c, and heat generation and durability. It is possible to prevent deterioration.

Here, as a condition for limiting the output of the power generation unit 120a, the first power receiving point ammeter 130a in the first voltage line to which the equipment current and the load equipment 16 whose connection point is close to the power supply equipment 120 are connected is the first. 1 The sum of the current at the receiving point is for the following reasons.

For example, assuming that the equipment current is X, the current consumed by the load equipment 16a is Y, and the current consumed by the load equipment 16b is Z, the current flowing through each wiring is as shown in FIG. Here, since the current value of Y flowing through the portion indicated by the thick line is the maximum, it is sufficient that Y is equal to or less than the overcurrent withstand capacity of the internal wiring 114c. Therefore, the control unit 120c has the first power receiving point current Y measured by the first power receiving point ammeter 130a in the first voltage line to which the equipment current X and the load equipment 16a whose connection point is close to the power supply equipment 120 are connected. It is sufficient to limit the output of the power generation unit 120a so that Y, which is the sum of −X, is equal to or less than the rated breaking current of the leakage breaker 114b.

Further, the control unit 120c is the first power receiving point current Y-measured by the first power receiving point current meter 130a in the first voltage line to which the equipment current and the load equipment 16a whose connection point is close to the power supply equipment 120 are connected. Even if the output of the power supply facility 120 is limited so that the sum with X follows a predetermined current lower than the rated breaking current of the leakage breaker 114b of 30A or the rated breaking current of the leakage breaker 114b, for example, 28A. good. With this configuration, when the receiving point current increases, the equipment current can be reduced (suppressed) by that amount, and conversely, when the receiving point current decreases, the equipment current can be increased by that amount. In this way, while making the best use of the output of the power supply facility 120, it is possible to prevent a current exceeding the overcurrent capacity from flowing through the existing internal wiring 114c.

Here, an example of using a first receiving point current meter 130a for measuring the current of the first voltage line has been described, but the connection point of the voltage line to which the load facility 16 close to the power supply facility 120 is connected has been described. It is sufficient to measure the current. For example, when the voltage line to which the load facility 16 whose connection point is close to the power supply facility 120 is connected is the second voltage line, the second power receiving point current meter 130b may be used. ..

Further, in the single-phase three-wire system, if the current of any two of the three wires (first voltage line, neutral wire, second voltage line) can be grasped, the current of the other one wire is derived by calculation. can. Therefore, a second receiving point ammeter 130b and an ammeter for measuring the current flowing through the neutral line are prepared, and the current of the first voltage line is derived from the second receiving point current and the current flowing through the neutral line. May be.

Although the preferred embodiment of the present invention has been described above with reference to the accompanying drawings, it goes without saying that the present invention is not limited to such an embodiment. It is clear that a person skilled in the art can come up with various modifications or modifications within the scope of the claims, which naturally belong to the technical scope of the present invention. Understood.

For example, in the above-described embodiment, the control unit 120c is provided inside the power supply equipment 120, but the present invention is not limited to this case, and the control unit 120c is separated from the power supply equipment 120. It may be provided. In this case, the information transmission between the control unit 120c, the power supply facility 120, the first receiving point ammeter 130a, and the second receiving point ammeter 130b may be an analog signal (for example, a voltage value) or a digital signal. I do not care.

Further, here, the control unit 120c limits the output of the power supply equipment 120 so as to be equal to or less than the rated breaking current of the earth leakage breaker 114b. Therefore, instead of the rated breaking current of the earth leakage breaker 114b, it may be a condition that the withstand current of the internal wiring 114c or less is equal to or less than the withstand current.

INDUSTRIAL APPLICABILITY The present invention can be used for a power system to which a power supply facility can be connected to a consumer premises.

14 Power system 16 (16a, 16b, 16c, 16d) Load equipment 100, 200, 300 Power system 114b Leakage breaker 114c Internal wiring 114d Wiring breaker 114e Individual breaker 114f Interconnection breaker 120 Power supply equipment 120a Power generation unit 120b Equipment current meter 120c Control unit 130a 1st power receiving point current meter (power receiving point current meter)
130b Second receiving point ammeter (receiving point ammeter)

Claims (3)

A power system that supplies the power of the power system to the load equipment through the earth leakage breaker and the single-phase three-wire internal wiring connected to the secondary side of the earth leakage breaker.
The power supply equipment connected to the earth leakage breaker side from the load equipment in the voltage line and the neutral line of the internal wiring, and
An equipment ammeter that measures the equipment current flowing through the power supply equipment,
A power receiving point ammeter that measures the power receiving point current flowing through the voltage line to which the power supply equipment is connected at the power receiving point on the primary side of the earth leakage breaker.
A control unit that limits the output of the power supply equipment so that the sum of the equipment current and the power receiving point current is equal to or less than the rated breaking current of the earth leakage breaker or the overcurrent withstand capacity of the internal wiring.
A power system characterized by being equipped with. A power system that supplies the power of the power system to the load equipment through the earth leakage breaker and the single-phase three-wire internal wiring connected to the secondary side of the earth leakage breaker.
The power supply equipment connected to the earth leakage breaker side from the load equipment in the two voltage lines of the internal wiring, and
An equipment ammeter that measures the equipment current flowing through the power supply equipment,
A first receiving point ammeter that measures the first receiving point current flowing through one of the voltage lines at the receiving point on the primary side of the earth leakage breaker.
A second receiving point ammeter that measures the second receiving point current flowing through the other voltage line at the receiving point, and
Both the sum of the installed current and the first receiving point current and the sum of the installed current and the second receiving point current are equal to or less than the rated breaking current of the earth leakage breaker or the overcurrent withstand capacity of the internal wiring. A control unit that limits the output of the power supply equipment,
A power system characterized by being equipped with. The control unit follows the rated breaking current of the earth leakage breaker or the overcurrent withstand of the internal wiring, or a predetermined current less than the rated breaking current of the earth leakage breaker or the overcurrent withstand of the internal wiring. The power system according to claim 1 or 2, which limits the output of the supply equipment.

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