JP5063264B2 - Power system control device and control method - Google Patents

Description

  The present invention relates to a control device and a control method for an electric power system, and more particularly to a technique for preventing an electric power facility from being overloaded without causing a supply failure when an accident occurs.

  In a power system having a power path with a loop structure, power facilities such as power transmission lines and transformers constituting the power system may be overloaded when an accident such as a route break occurs. For example, in the power system 1 illustrated in FIG. 4A, there are two transformers 71 and 72 on the path connecting the generator 2, the load 31, and the load 32, but the power path connecting the node bc is disconnected. As shown in FIG. 4B, the transformer 72 may be overloaded.

Here, in order to prevent the overload, there is a method of installing a system stabilizing device (SSC: System Stabilizing Controller) (see, for example, Patent Document 1). (For example, refer to Patent Document 2).
JP 9-182319 A JP-A-7-107656

  When the above system stabilizing device is used, since it is necessary to capture a tidal current in a power facility such as a transmission line or a transformer, the facility becomes large-scale, and installation costs and operation costs increase. Further, in the conventional method using the system stabilizing device, the power path leading to the load and the generator is interrupted when an accident occurs, which causes a supply trouble.

The present invention, such has been made in view of the background, and an object thereof is to provide a control apparatus and a control method capable power system to prevent feed troubles during accidents such as a route disconnection.

One aspect of the present invention is
A node a to which power is supplied from the first generator;
Node b and node e to which power is supplied from the node a;
A node c to which power is supplied from the node b and the second generator;
A node d to which power is supplied from the node c;
Node f to which power is supplied from the node e,
Power supplied from the node f, node g,
A first transformer provided in a path connecting the node c and the node d;
A second transformer provided in a path connecting the node f and the node g;
A first load to which power is supplied from the node d;
A second load to which power is supplied from the node g;
A first circuit breaker which is provided in a path connecting the node b and the node c and is normally turned on; and
A second circuit breaker provided in a path connecting the node c and the node f and normally open;
A control device for controlling the first circuit breaker and the second circuit breaker, comprising:
When an accident current generated in a path connecting the node b and the node c is detected, the first circuit breaker is opened and the second circuit breaker is turned on.

Another aspect of the present invention is the above control device,
A control device for the power system,
Providing a ratio operation relay, a judgment circuit, and a relay circuit,
When the ratio actuated relay detects an accident current that has occurred in a path connecting the node b and the node c, it opens the first circuit breaker and outputs a trip signal to the determination circuit;
The determination circuit outputs an accident notification signal to the relay circuit when the trip signal is input,
When the accident notification signal is input, the relay circuit turns on the second circuit breaker,
The determination circuit outputs the accident notification signal to the relay circuit at the same time when the trip signal is output from the ratio operation relay.
The time from when the first circuit breaker is opened by the ratio actuated relay to when the second circuit breaker is turned on by the relay circuit is, for example, 100 ms or less.

Another one of the present invention is
A node a to which power is supplied from the first generator;
Node b and node e to which power is supplied from the node a;
A node c to which power is supplied from the node b and the second generator;
A node d to which power is supplied from the node c;
Node f to which power is supplied from the node e,
Power supplied from the node f, node g,
A first transformer provided in a path connecting the node c and the node d;
A second transformer provided in a path connecting the node f and the node g;
A first load to which power is supplied from the node d;
A second load to which power is supplied from the node g;
A first circuit breaker which is provided in a path connecting the node b and the node c and is normally turned on;
A second circuit breaker provided in a path connecting the node c and the node f and normally open; and
A power system control method including a control device for controlling the first circuit breaker and the second circuit breaker,
When the control device detects an accident current generated in a path connecting the node b and the node c, the control circuit opens the first circuit breaker and turns on the second circuit breaker.

Another aspect of the present invention is the above control method,
The control device includes a ratio operation relay, a determination circuit, and a relay circuit,
When the ratio actuated relay detects an accident current that has occurred in the path connecting the node b and the node c, it opens the first circuit breaker and outputs a trip signal to the determination circuit;
The determination circuit outputs an accident notification signal to the relay circuit when the trip signal is input,
The relay circuit turns on the second circuit breaker when the accident notification signal is input,
The determination circuit outputs the accident notification signal to the relay circuit at the same time when the trip signal is output from the ratio operation relay.
The time from when the first circuit breaker is opened by the ratio actuated relay to when the second circuit breaker is turned on by the relay circuit is, for example, 100 ms or less.

According to the present invention, it is possible to prevent the supply trouble in the event of an accident such as a route disconnection.

  Hereinafter, embodiments of the present invention will be described in detail. FIG. 1A shows a schematic configuration of a power system 1 described as an embodiment of the present invention. As shown in the figure, the power system 1 is composed of a generator 2 that is a power supply source and power equipment such as a transmission line, and a power path 4 that guides the power supplied from the generator 2 to loads 31 and 32. And a transformer 71 provided on a path connecting the nodes cd and a transformer 72 provided on a path connecting the nodes fg. In addition, power is supplied from the generator 7 to the node c.

  As shown in the figure, the electric power system 1 includes a loop structure. For example, the path connecting the generator 2 and the load 31 includes two paths: a path passing through the node abcd (first power path) and a path passing through the node aefghid (second power path). In the path connecting 2 and the load 32, there are two paths: a path passing through the node abcdihg and a path passing through the node aefg.

  Of the paths constituting the power path, a path connecting the nodes bc (hereinafter, this path is referred to as A line 41) is provided with a first circuit breaker 51. A second circuit breaker 52 is provided on a path connecting the nodes cjkf (hereinafter, this path is referred to as a B line 42 (third power path)). The B line 42 is an auxiliary route that is temporarily used during work or test operation. For this reason, the 2nd circuit breaker 52 is normally open | released (break | disconnection), and the B line 42 is not energized. If the A line 41 and the B line 42 are energized at the same time, the short-circuit capacity increases and exceeds the rated breaking capacity, and the induction voltage to the communication line under the line may exceed the allowable value due to the increase in the one-line ground fault current. There is.

  Opening / closing control (breaking / closing) of the first circuit breaker 51 and the second circuit breaker 52 is performed by the control unit 6 (control device) that is communicably connected thereto. FIG. 2 shows the configuration of the control unit 6. As shown in the figure, the control unit 6 includes an A-line relay panel 61, an A-line route break determination panel 62, and a B-line relay panel 63. The A-line relay panel 61 includes a ratio differential relay 611 (87 relay) that controls opening and closing of the first circuit breaker 51. The A-line route break determination panel 62 relays a signal (hereinafter referred to as an accident notification signal) indicating whether or not an accident has occurred in the A-line 41 in accordance with the trip signal input from the ratio differential relay 611. The determination circuit 621 is input to the circuit 631. The B-line relay panel 63 has a relay circuit 631 that turns on the second circuit breaker 52 when an accident notification signal indicating that an accident has occurred in the A-line 41 is input from the determination circuit 621.

  Next, specific control of the first circuit breaker 51 and the second circuit breaker 52 performed by the control unit 6 when an accident such as a route break occurs in the A line 41 will be described together with the timing chart shown in FIG. To do.

  First, when an accident such as a route interruption occurs in the A line 41 and a large accident current flows (t1), the ratio differential relay 611 is turned on (t2), and a trip signal is output from the ratio differential relay 611 (t3). ). Subsequently, the first circuit breaker 51 is opened (t4) (cutoff state), and the power supply path (A line 41) connecting the nodes bc is cut off. When a trip signal is input from the ratio differential relay 611, the determination circuit 621 outputs an accident notification signal indicating that an accident has occurred in the relay circuit 631 (t3). When receiving the accident notification signal from the determination circuit 621, the relay circuit 631 turns on (closes) the second circuit breaker 52 (t5).

  Here, if the time (t4 → t5) from when the first circuit breaker 51 is opened to when the second circuit breaker 52 is turned on is long, the phase angle (phase difference angle) at both ends of the second circuit breaker 52 is increased. When the second circuit breaker 52 is turned on, a large torque may be applied to the shaft of the generator 7 that supplies power to the node c when the second circuit breaker 52 is turned on, causing the generator 7 to break. For this reason, the time (t4 → t5) from when the first circuit breaker 51 is opened until the second circuit breaker 52 is turned on is the time (t4 → t5) until the phase difference angle has an adverse effect on the generator 7 ( Hereinafter, it is preferably referred to as a predetermined time.

  Therefore, in the present embodiment, as shown in FIG. 3, the accident notification signal is input from the determination circuit 621 to the relay circuit 631 at the same time when the trip signal is output from the ratio differential relay 611 (t3), thereby The circuit breaker 52 is turned on as soon as possible (t5) to suppress the influence on the generator 7. Specifically, the predetermined time, that is, the time (t4 → t5) from when the first circuit breaker 51 is opened until the second circuit breaker 52 is turned on is set to 100 ms or less.

  FIG. 1B shows a state of power supply in the power system 1 after the second circuit breaker 52 is inserted. During the period from t4 to t5, the load 32 is supplied with electric power from the generator 2 through the node aefg, and the load 31 is supplied from the generator 2 through the node aefghi. For this reason, supply trouble does not arise in the load 31 during the period from t4 to t5 when both the first circuit breaker 51 and the second circuit breaker 52 are open.

Thus, according to this embodiment, it is not caused supply trouble in load during accidents such as a route disconnection. Moreover, since the time (t4 → t5) from when the first circuit breaker 51 is opened to when the second circuit breaker 52 is turned on is short, the influence on the generator 7 due to the switching of the path can be suppressed. In addition, since the above mechanism is a simple mechanism in which the control unit 6 controls the first circuit breaker 51 and the second circuit breaker 52, it can be implemented easily and inexpensively.

  The above description of the embodiment is for facilitating the understanding of the present invention, and does not limit the present invention. It goes without saying that the present invention can be changed and improved without departing from the gist thereof, and that the present invention includes equivalents thereof.

It is a structure of the electric power grid | system 1 demonstrated as one Embodiment of this invention, and is a figure which shows a normal operation state. It is a structure of the electric power grid | system 1 demonstrated as one Embodiment of this invention, and is a figure which shows the operation state at the time of accident occurrence. It is a figure which shows the structure of the control part 6 demonstrated as one Embodiment of this invention. It is a timing chart explaining the specific control of the 1st circuit breaker 51 and the 2nd circuit breaker 52 by the control part 6 demonstrated as one Embodiment of this invention. It is an example of the electric power grid | system 1, and is a figure which shows a normal operation state. It is an example of the electric power grid | system 1, and is a figure which shows the operation state at the time of accident occurrence.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Electric power system 2 Generator 31 Load 32 Load 4 Electric power path 41 A line 42 B line 51 1st circuit breaker 52 2nd circuit breaker 6 Control part 61 A line relay panel 611 Ratio differential relay 62 A line route break determination Panel 621 Judgment circuit 63 B-line relay panel 631 Relay circuit 7 Generator

Claims (6)

A node a to which power is supplied from the first generator;
Node b and node e to which power is supplied from the node a;
A node c to which power is supplied from the node b and the second generator;
A node d to which power is supplied from the node c;
Node f to which power is supplied from the node e,
Power supplied from the node f, node g,
A first transformer provided in a path connecting the node c and the node d;
A second transformer provided in a path connecting the node f and the node g;
A first load to which power is supplied from the node d;
A second load to which power is supplied from the node g;
A first circuit breaker which is provided in a path connecting the node b and the node c and is normally turned on; and
A second circuit breaker provided in a path connecting the node c and the node f and normally open;
A control device for controlling the first circuit breaker and the second circuit breaker, comprising:
When an accident current generated in the path connecting the node b and the node c is detected, the first circuit breaker is opened and the second circuit breaker is turned on.
A power system control device. A power system control device according to claim 1,
Providing a ratio operation relay, a judgment circuit, and a relay circuit,
When the ratio actuated relay detects an accident current that has occurred in a path connecting the node b and the node c, it opens the first circuit breaker and outputs a trip signal to the determination circuit;
The determination circuit outputs an accident notification signal to the relay circuit when the trip signal is input,
When the accident notification signal is input, the relay circuit turns on the second circuit breaker,
The determination circuit outputs the accident notification signal to the relay circuit at the same time when the trip signal is output from the ratio operation relay.
A power system control device. A control device for a power system according to claim 2,
The time from when the first circuit breaker is opened by the ratio actuated relay to when the second circuit breaker is turned on by the relay circuit is 100 ms or less.
A power system control device. A node a to which power is supplied from the first generator;
Node b and node e to which power is supplied from the node a;
A node c to which power is supplied from the node b and the second generator;
A node d to which power is supplied from the node c;
Node f to which power is supplied from the node e,
Power supplied from the node f, node g,
A first transformer provided in a path connecting the node c and the node d;
A second transformer provided in a path connecting the node f and the node g;
A first load to which power is supplied from the node d;
A second load to which power is supplied from the node g;
A first circuit breaker which is provided in a path connecting the node b and the node c and is normally turned on;
A second circuit breaker provided in a path connecting the node c and the node f and normally open; and
A power system control method including a control device for controlling the first circuit breaker and the second circuit breaker,
When the control device detects an accident current generated in a path connecting the node b and the node c, the control device opens the first circuit breaker and turns on the second circuit breaker.
A power system control method characterized by the above. It is a control method of the electric power system according to claim 4,
The control device includes a ratio operation relay, a determination circuit, and a relay circuit,
When the ratio actuated relay detects an accident current that has occurred in the path connecting the node b and the node c, it opens the first circuit breaker and outputs a trip signal to the determination circuit;
The determination circuit outputs an accident notification signal to the relay circuit when the trip signal is input,
The relay circuit turns on the second circuit breaker when the accident notification signal is input,
The determination circuit outputs the accident notification signal to the relay circuit at the same time when the trip signal is output from the ratio operated relay.
A power system control method characterized by the above. It is a control method of the electric power system according to claim 5,
The time from when the first circuit breaker is opened by the ratio actuated relay to when the second circuit breaker is turned on by the relay circuit is 100 ms or less.
A power system control method characterized by the above.

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