JPH0646525A - Protection method for inverter distribution system - Google Patents

Abstract

PURPOSE:To provide a downsized economical protective method for inverter distribution system which can enhance reliability in power supply to a sound section while minimizing effect on the sound section upon occurrence of short circuit fault. CONSTITUTION:Output from an inverter 11 is interrupted temporarily when ultrahigh speed overcurrent relays 16A, 16B provided in the inverter 11 detect rising of short circuit current while ultrahigh speed overcurrent relays 20a-20c and the like provided for each switch branching the output from the inverter 11 detect the fault section. A switch located immediately in the upstream of the fault section is then turned OFF to isolate the fault section and the inverter 11 is reclosed to resume power supply to a sound section. Electromagnetic switches 18a-18c or solid state contactors are employed as the switches.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for protecting a load side short circuit in an inverter power distribution system using an inverter device.

[0002]

2. Description of the Related Art Conventionally, an inverter power distribution system for converting power purchased from an electric power company to a high frequency, for example, by an inverter device and distributing the power to a load has a configuration as shown in FIG. After converting the power purchase of the above into a direct current by the rectifier 2 of the inverter device 1,
Then, it is converted into a high-frequency alternating current of 400 or 500 Hz, for example, and output through the electromagnetic switch 4, and this output is branched by each circuit breaker 6 in the distribution board 5 to be distributed to each load.

When power is supplied to many loads,
The alternating current in each branching section provided with each wiring breaker 6 is further branched by a plurality of distribution line breakers, and thereafter finely branched into layers as necessary. When a load-side short-circuit accident occurs in this type of distribution system, the short-circuit protection method is to open the accident section by tripping the wiring breaker, for example, the wiring breaker 6 above the accident point, or the inverter device 1. A method is adopted in which the electromagnetic switch 4, the current transformer 7, and the overcurrent relay 8 are combined to stop the output of the inverter device 1 before the short-circuit current flows.

[0004]

In the case of the conventional method for tripping the circuit breaker 6 for wiring to protect against short circuit, a short-circuit current flows through the inverter 3 until the circuit breaker 6 for wiring trips. It is necessary to give the element etc. overcurrent resistance against short circuit current, which will substantially raise the rating of this switching element etc.
In addition to being uneconomical, there is the problem of increasing the size of the device.

Further, in the case of the conventional method of stopping the output of the inverter device 1 before flowing the short-circuit current, the power distribution is only stopped on the power source side before the load side circuit breaker 6 trips. However, there is no protection coordination, there is a total power failure on the load side, and there is a power outage to a healthy section, which is a problem for the power distribution system. Moreover, it is artificial until the accident section is opened and the healthy section is restored. There is a problem that it is particularly necessary to confirm various accident points and open accident sections.

The present invention has been made in view of the above problems of the prior art, and an object of the present invention is to minimize the influence on the sound section of the accident when a short circuit accident occurs on the load side. It is an object of the present invention to provide an economical and compact protection method for an inverter power distribution system, which can limit the power supply to a healthy section and increase the reliability of power supply to a healthy section.

[0007]

In order to achieve the above object, in a method for protecting an inverter power distribution system of the present invention, an ultra-high-speed overcurrent relay provided in the inverter device detects the rise of a short-circuit current, and The output is temporarily stopped, the output of the inverter device is branched, and the output is distributed to each switch to detect the fault section with an ultra-high-speed overcurrent relay, etc. provided for each switch, and the switch immediately above this fault section is turned off. The accident section is separated, the inverter device is turned on again, and the power supply to the sound section is restarted. And
Each switch is preferably an electromagnetic switch or a solid state contactor.

[0008]

In the case of the protection method of the present invention configured as described above, when a short-circuit accident occurs, the rise of the short-circuit current is detected by the ultra-high-speed overcurrent relay of the inverter device and the ultra-high-speed overcurrent relay of the switch in the fault section. To be done. Then, in the inverter device, since the output is temporarily stopped before the peak value of the short-circuit current flows due to the detection of the overcurrent relay, the necessary overcurrent withstanding capacity of the switching element of the inverter in the device becomes smaller than before, The price and size can be reduced.

Further, the fault section is detected from the state of the ultra-high-speed overcurrent relay for each switch, and the switch immediately above the fault section is turned off by this detection to disconnect the fault section from the inverter device. Then, immediately after this disconnection, the inverter device is re-closed, and the power supply in the healthy section is immediately restarted by this, so that the power failure in the healthy section can be performed only by the required minimum instantaneous power failure (hereinafter referred to as instantaneous voltage drop). The impact of accidents on healthy sections is minimized and the reliability of power supply is improved.

Moreover, it is not necessary to artificially confirm the accident point and open the accident section when the power is restored in the sound section. And
It is practical that each switch in each branch section is an electromagnetic switch.

Further, if each switch is a solid-state contactor which operates at high speed, the accident section can be separated and the sound section can be restored more quickly. Can be separated from.

[0012]

EXAMPLES Examples will be described with reference to FIGS. (First Embodiment) First, a first embodiment in which the switch in each branch section is an electromagnetic switch will be described with reference to FIGS. FIG. 1 shows a single-line connection configuration of an inverter power distribution system. An inverter device 11 includes a rectifier 12 that converts a power purchase of 50 to 60 Hz into a direct current, and an inverter 13 that converts the direct current into a high frequency alternating current of 400 or 500 Hz.
And an electromagnetic switch 14 for branching the output of the inverter 13 into two
A, 14B, current transformers 15A, 15B for detecting the system current passing through both electromagnetic switches 14A, 14B, and both current transformers 15
Ultra-high-speed overcurrent relay 16A, 1 for detecting the rise of the short-circuit current of the output of the inverter 13 from the output of A, 15B
6B is provided.

The output of the inverter device 11 passing through the electromagnetic switch 14A is distributed to the distribution board 17, and the distribution board 1
In FIG. 7, the output of the inverter device 11 is branched by the electromagnetic switches 18a, 18b, 18c for each branch section and distributed to each load. Furthermore, each electromagnetic switch 18a-1
Current transformers 19a to 1 that detect the current in each branch section every 8c
9c and ultra-high-speed overcurrent relays 20a to 20c that detect the rising of the short-circuit current are provided. The output of the other electromagnetic switch 14B of the inverter device 11 is also branched and distributed by a distribution board similar to the distribution board 17.

FIG. 2 is a flowchart showing the protection operation of FIG. 1 when a short-circuit accident occurs. Next, this protection operation will be described with reference to FIG. 3 showing a current waveform. T in FIG.
_{At 1} o'clock, for example, when a short-circuit accident occurs at point X in FIG. 1, when the current at this accident point X begins to rise to the short-circuit current shown by the alternate long and short dash line in FIG. The current relays 20a and 16A detect the rising of the short-circuit current, that is, the leading edge of the abnormal overcurrent.

In the inverter device 11,
By detecting the abnormal overcurrent of the ultra high speed overcurrent relay 16A,
At t ₂ before reaching the peak value of the short-circuit current, the electromagnetic switch 14A is turned off to temporarily stop the output to the distribution board 17. Immediately after this, each ultra-high-speed overcurrent relay 16A,
16B, 20a ~ 20c from the state of the accident detected,
The load side from the ultra-high speed overcurrent relay 20a on the lower side of the accident point X is determined as the accident section.

Upon detection of the accident section of the ultra-high-speed overcurrent relay 20a, the electromagnetic switch 18a located immediately above the accident section is turned off, thereby disconnecting the accident section from the inverter device 11. Further, at t ₃ immediately after the disconnection, the electromagnetic switch 14A of the inverter device 11 is reclosed to restart the power distribution to the healthy section.

When a short-circuit accident occurs, the output of the inverter device 11 is temporarily stopped before the peak value of the short-circuit current is reached, so that an excessive short-circuit current hardly flows. Therefore, it suffices for the switching elements and the like that form the inverter 13 to satisfy the rated output, and it is also possible to lower the required rating of the series connection devices such as the electromagnetic switches 18a to 18c in the distribution board 17 and the distribution cable. Become.

Further, when the accident section is separated, the electromagnetic switch 14A of the inverter device 11 is immediately turned on again, so that only a momentary drop occurs in the sound section and effective protection cooperation is realized. Further, since the switches and the like in each branch section are electromagnetic switches 18a to 18c, respectively, the inverter device 1
There is an advantage that there is no restriction in terms of switch operation with respect to the output frequency of 1.

The case of inputting power purchase of 50/60 Hz to the inverter device 11 has been described.
As shown by the dotted line, the same can be applied to the case where the DC output of the fuel cell 21 or the like is converted into commercial AC or high frequency AC by the inverter 13 for power distribution. Also, each electromagnetic switch 18a
It is needless to say that each of the branch outputs of .about.18c can be applied to the case where the electromagnetic switches are further branched in a hierarchical manner.

Further, in the above embodiment, the inverter device 1
Although the output of 1 is output in two branches by the electromagnetic switches 14A and 14B, for example, the electromagnetic switch 14B and the like may be omitted, and power may be supplied to the load side without branching. It may be branched and output.

(Second Embodiment) Next, a second embodiment in which the switch in each branch section is a solid state contactor will be described with reference to FIGS. 4, the same reference numerals as those in FIG. 1 indicate the same components, and the only difference is that the output of the inverter device 11 is only the output passing through the electromagnetic switch 14A, and instead of the respective electromagnetic switches 18a to 18c of FIG. This is the point where the contactors 22a to 22c are used.

Then, the solid state contactor 22
The a to 22c are turned on and off by the operation of the semiconductor switch instead of being turned on and off by a mechanical operation like the electromagnetic switches 18a to 18c, so that there is an advantage that the operation is performed at an extremely high speed. Therefore, in this embodiment, the protective operation shown in FIG. 5 keeps the sound section in a so-called uninterrupted state and disconnects the accident section from the inverter device 11.

[0023] That is, as shown in the current waveform of FIG. 6 corresponding to FIG. 3, when t ₁ 'at X in FIG. 4' short circuit at point corresponding to the time t ₁ in FIG. 3 occurs, the accident point X ' 6 starts to rise to the short-circuit current shown by the one-dot chain line in FIG. 6, the ultra-high-speed overcurrent relays 20a and 16A located above the fault point X'raise the short-circuit current, that is, the leading edge of the abnormal overcurrent. To detect.

In the inverter device 11,
By detecting the abnormal overcurrent of the ultra high speed overcurrent relay 16A,
At t ₂ 'before the peak value of the short-circuit current is reached, the electromagnetic switch 14A is turned off to temporarily stop the output to the distribution board 17. At the same time, the solid state contactor 22a is immediately turned off by detecting the faulty section by the ultra-high-speed overcurrent relay 20a immediately above the faulty section, and disconnecting the faulty section from the inverter device 11.

Further, at t ₃ 'immediately after the disconnection, the electromagnetic switch 14A of the inverter device 11 is reclosed to restart the power supply to the healthy section. In this case, solid-state contactors 22a is turned off very quickly from the electromagnetic switch 18a in FIG. 1, the time required until the 't ₃ healthy section is re-distribution since' the t ₁ of the accident, the electromagnetic switch 18a
Extremely shorter than the case of ~ 18c, about 10-20m
It becomes the sec instant.

Therefore, the faulty section is separated from the inverter device 11 while keeping the sound section substantially uninterrupted. Since the overcurrent output from the inverter device 11 is prevented, the solid state contactors 22a to 22a are
c can be used without providing a quick-acting fuse immediately before it even if the withstand current is small.

[0027]

Since the present invention is configured as described above, it has the following effects. When a short-circuit accident occurs, the ultra-high-speed overcurrent relays 14A and 14B provided in the inverter device 11 detect the rising of the short-circuit current and stop the output of the inverter device 11 before the peak value is reached and output the short-circuit current. Because of the prevention, the overcurrent withstanding capability required for the switching elements and the like in the inverter device 11 becomes smaller than in the past, and the cost and the size can be reduced.

Further, the faulty section is detected by the ultra-high speed overcurrent relays 20a to 20c provided for each switch in each branch section, and the switch immediately above the section is turned off to disconnect the faulty section from the inverter device 11. After that, since the power supply in the sound section is restarted by re-inputting the inverter device 11, the power failure in the sound section can be suppressed to the necessary minimum, and the reliability of the power supply can be significantly improved. Therefore, when an accident occurs, it is possible to provide an economical and small-scale inverter distribution system protection method that can minimize the influence of the accident on the sound section and improve the reliability of the power supply in the sound section.

When the switches in each branch section are electromagnetic switches 18a to 18c, the output frequency of the inverter device 11 is not restricted by the switch operation, and a practical protection method can be provided. Furthermore, if the switches in each branch section are solid state contactors 22a to 22c,
The accident section can be separated and the sound section can be restored to power more rapidly, and the accident section can be separated from the inverter device 11 while maintaining the sound section in a so-called uninterrupted state, and the reliability of power supply is significantly improved.

[Brief description of drawings]

FIG. 1 is a single line connection diagram of a first embodiment of the present invention.

FIG. 2 is a flowchart for explaining the operation of FIG.

FIG. 3 is a current waveform diagram at the time of a short circuit accident in FIG.

FIG. 4 is a single line connection diagram of a second embodiment of the present invention.

5 is a flowchart for explaining the operation of FIG.

FIG. 6 is a current waveform diagram at the time of a short circuit accident in FIG.

FIG. 7 is a single-line connection diagram of a conventional example.

[Explanation of symbols]

 11 Inverter device 14A, 14B, 18a-18c Electromagnetic switch 16A, 16B, 20a-20c Ultra high-speed overcurrent relay 22a-22c Solid state contactor

Front page continuation (72) Inventor Houji Hoji, 47 Umezu Takaunecho, Ukyo-ku, Kyoto City, Nissin Electric Co., Ltd. Naoyoshi Akashi 47 Umezu Takaune-cho, Ukyo-ku, Kyoto City Nissin Electric Co., Ltd.

Claims (3)

[Claims] 1. A method for protecting an inverter power distribution system in which an output of an inverter device is branched by respective switches to distribute to a load, wherein the inverter is detected by detecting a rising of a short-circuit current by an ultra-high-speed overcurrent relay provided in the inverter device. The output of the device is temporarily stopped, and an accident section is detected by an ultra-high-speed overcurrent relay or the like provided for each of the switches, and the accident section is separated by turning off the switch immediately above the accident section, A method for protecting an inverter power distribution system, characterized in that the inverter device is turned on again to restart power supply in a healthy section. 2. The method for protecting an inverter power distribution system according to claim 1, wherein each switch is an electromagnetic switch. 3. The method for protecting an inverter power distribution system according to claim 1, wherein each switch is a solid state contactor.