JPH05268798A - Power generating facility - Google Patents

Abstract

PURPOSE:To protect a prime mover against short circuit fault. CONSTITUTION:The power generating facility comprises a circuit breaker 4 for disconnecting output cables 3a, 3b of a generator 2, a regulator 12 for regulating input amount to a prime mover 1, a current relay 7 being set at a level for protecting the generator 2, and a short circuit relay 8 for operating the circuit breaker 4 upon detection of short circuit current flowing through the output cables 3a, 3b and operating the regulator 12 to reduce input amount to the prime mover 1.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power generation facility having a prime mover and a generator driven by the prime mover.

[0002]

2. Description of the Related Art As a conventional technique, in a power transmission system of a prime mover and a generator, a mechanical fuse is provided for disconnecting the prime mover within the proof stress of the prime mover in order to protect the prime mover from excessive torque due to a short circuit accident. In the mechanical fuse in this case, a shear pin is generally provided at the shaft coupling portion.

Some relays are provided to electrically protect the generator. This relay will be briefly described with reference to FIG. In the figure, the horizontal axis represents time, the vertical axis represents output (100% of rated output), the solid line represents the protection cooperation curve G of the generator, and the dashed line represents the characteristic curve R of this relay.

As a relay for electrically protecting the generator, for example, in order to protect the generator from an inrush current generated at the time of starting the generator, a relay works at a point a on the characteristic curve R, that is, , When the output of about 2000% continues for about 0.02 seconds, the operating time on the characteristic curve R is set to protect the generator from what the relay is set to operate and continuous overcurrent. Some are set so that the relay works in a long time. In addition, the shear pin S described above is about 170 to 20 as shown in FIG.
It is set to disconnect when a 0% load is applied.

[0005]

However, in such a conventional technique, if an excessive torque is generated due to a short-circuit accident and the shear pin is cut off, the power generation equipment must be stopped for a long time to restore the shear pin. Therefore, in the case of a power generation facility installed in a factory as a regular machine such as a cogeneration system, a long power outage causes a large amount of damage to the customer.

Further, as shown in FIG. 3, during the period from the occurrence of the short-circuit accident t ₀ to the disconnection of the shear pin t ₁ , the rotational speed S of the prime mover decreases while the sudden short-circuit torque T increases. When viewed from the side of the prime mover, the load has increased, so a large amount of fuel F is injected in an attempt to increase the output of the prime mover. Therefore, there is a problem that a state in which a large amount of fuel F is injected while the rotation speed S of the prime mover is slow may temporarily occur, and the prime mover may be damaged.

Further, in general, when the power generation equipment and the commercial power supply are operated in parallel, the reactive power flows between them, so in order to adjust this, the voltage of the power generation equipment is monitored while monitoring the voltage of the commercial power supply. An automatic voltage regulator (AVR) for adjusting is provided. By the way, the synchronous generator has a property of adjusting its voltage so as to match the voltage of the commercial power source by flowing a reactive current. Therefore, if this automatic voltage regulator fails, the phase of the reactive current may advance to the commercial power source side, and excessive power may be supplied to the commercial power source side. If the other party is a power company, the power supply from the power generation system side may be prohibited and subject to fines. In addition, the power generation equipment on the supply side changes the current for voltage adjustment, so there is no problem in terms of voltage, but the power factor is excessively delayed or advanced, and overload occurs and the generator burns out. There is a problem that can lead to.

The present invention has been made in view of such conventional problems, and an object thereof is to provide a power generation facility capable of preventing a damage accident.

[0009]

Means for Solving the Problems A power generation facility for achieving the above object is a circuit breaker that disconnects a power path of a generator, and a value that can protect the power generator. When the value exceeds the value, a current relay for operating the circuit breaker, and a separate short circuit relay for detecting the short circuit current flowing through the power path, separately from the current relay, and operating the circuit breaker when the short circuit current is detected, It is characterized by having.

Further, the power generation equipment for achieving the above object is set to a value that can protect the generator and a circuit breaker that cuts off the power path of the generator, and when the current flowing through the power path exceeds the value. A current relay for operating the circuit breaker,
In addition to the regulator that adjusts the input amount to the prime mover that drives the generator and the current relay, the short-circuit current flowing through the power path is detected, and when the short-circuit current is detected, the input amount is reduced. A short circuit current relay to operate the regulator,
It is characterized by having.

Here, the input amount to the prime mover is fuel or combustion air injected into the combustor if the prime mover is a gas turbine, and steam supplied into the turbine if the prime mover is a steam turbine. If it is a watermill, it is water. In the above power generation equipment, 125% to 170% of the rated current of the generator is 0.2 to 0.
It is preferably set to operate when flowing for 5 seconds.

[0012] Further, another power generation equipment for achieving the above-mentioned object is to detect a power breaker for cutting off the power path of the generator and a power factor of the power path, and set the power factor within a predetermined range. If it exceeds, a power factor relay for operating the circuit breaker is provided.

[0013]

When an electrical short circuit occurs in the output circuit of the generator, a sudden short circuit current of 3 to 10 times the rated value instantaneously flows in the generator armature, which causes a short circuit torque on the rotor shaft. It is transmitted. It is conceivable that this sudden short-circuit torque reaches the prime mover, causing mechanical deformation and, in some cases, damage.
Current relays and voltage relays are installed as protective relays in the electric circuit of the power generation equipment.These relays are installed with settings that protect the generator from continuous overcurrent and overvoltage, and the operation time limit is limited. It cannot respond to a long and sudden sudden short circuit current. In addition, there are some that are set for the purpose of protecting the generator from sudden current at startup, but the current relay for this purpose has a too short setting time for detecting short-circuit current, and the set output is also Since it is too high, it alone cannot protect both the prime mover and the generator from sudden currents and short-circuit accidents at startup. Therefore, a short-circuit relay is installed in addition to these relays.

By connecting this short-circuit relay to the trip circuit of the main circuit breaker, the circuit is disconnected before the sudden short-circuit torque is applied to the prime mover, and the prime mover and the joint portion between the prime mover and the generator are protected. Can be planned. The short circuit relay may also be connected to the regulator of the prime mover. As described above, when a short-circuit accident occurs, the sudden short-circuit torque is equivalent to a temporary increase in load when viewed from the prime mover side.Therefore, the prime mover injects a large amount of fuel in order to increase the output. , It becomes overloaded and damages the prime mover. Therefore, when the short-circuit relay detects a short-circuit current, by operating the regulator so that the input amount to the prime mover decreases, it is possible to prevent the prime mover from being overloaded and protect the prime mover from a short-circuit accident. ..

When the power generation equipment and the commercial power supply are operated in parallel, the excessive amount of the advanced power is supplied from the power generation equipment to the commercial power supply side due to the adjustment failure of the reactive power generated by the trouble of the control device of the power generation equipment. There is a possibility that it will end up.
If the power factor is delayed, the generator of the power generation facility may be overloaded and may not operate normally. Therefore, a power factor relay for detecting the power factor is provided in the circuit of the power generation equipment, and this relay is connected to the trip circuit of the circuit breaker to protect the generator from the adjustment failure of the reactive power.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. As shown in FIG. 1, the power generation facility G of this embodiment
Is connected to a commercial power source W, a prime mover 1, a generator 2 connected to the prime mover 1 via a shaft coupling Q,
Output cables 3a, 3b through which electric power from the generator 2 flows
And a controller 14 that mainly controls the outputs of the prime mover 1 and the generator 2.

The control unit 14 includes output cables 3a and 3b.
Main circuit breaker 4 for shutting off the power flowing through the circuit, trip circuit 5 for operating the main circuit breaker 4, voltage relay 6, current relay 7, short circuit relay 8 and power factor relay 9
, The automatic voltage regulator 10 for constantly monitoring the output voltage E from the power generation equipment G to control the generator field 11 and keeping the output voltage E constant, and signals from the relays 6, 7 ,. It also has a control circuit 13 for receiving and operating the trip circuit 5. The prime mover 1 receives the instruction from the control circuit 13 and adjusts the rotation speed of the prime mover 1 to the prime mover 12
Is provided.

Next, the operation of this embodiment will be described.
When fuel or electric power P is input to the prime mover 1, the prime mover 1 is driven, and at the same time, the generator 2 connected to the prime mover 1 via the shaft coupling Q is also driven. Electric power is generated by driving the generator 2. This power is output from the output cable 3
a and 3b, and is controlled by the controller 14.

The voltage relay 6 detects the voltage of the output cable 3b, and when this voltage exceeds a specified value, the control circuit 13
Send a signal to. When the control circuit 14 receives this signal,
A signal is output to the trip circuit 5 to operate the main circuit breaker 4. Further, the current relay 7, the short-circuit relay 8 and the power factor relay 9 also detect the current, short-circuit current and power factor of the output cable 3b, respectively, and output a signal when these values exceed the specified values, and the control circuit The main circuit breaker 4 is operated via 13 and the trip circuit 5.

Here, the current relay 7 and the short-circuit relay 8
The operation will be described in detail with reference to FIG. The current relay 7 and the short circuit relay 8 are both output cables 3
It operates by detecting the current of b, but the set values at which they operate are different.

That is, as described above, the current relay 7 protects the generator 2 from the inrush current generated when the generator 2 is started up.
When 000% output continues for about 0.02 seconds (characteristic curve R
The above point a) is set so that the relay works. On the other hand, the short-circuit relay 8 operates at a short-circuit current of about 150% in order to protect the motor from a short-circuit accident.
The relay is set to operate when the output of (2) continues for 0.5 seconds (point b in FIG. 2).

The sudden short circuit torque is generated in 1/2 cycle after the short circuit. Therefore, if the short circuit current is cut off before that, this torque will not be generated. Therefore, it is necessary to set the time until the trip of the main circuit breaker 4 after the short circuit is shorter than 1/2 cycle. Therefore, in order to detect the short-circuit current and meet this need, the set time of the short-circuit relay 8 is set to 0.5 seconds.
The set time is not limited to this, and may be set to 0.2 to 0.5 seconds. Further, since the short-circuit relay 8 operates, the output is to prevent damage to the prime mover 1 between the occurrence of the short-circuit accident and the breakage of the shear pin (however, the shear pin is not provided in this embodiment) described above. , Sharpin S breaks 170%
It is set to 125% to 170%, which is lower than ~ 200%.

The signal from the short circuit relay 8 is sent to the control circuit 13
Sent to the main circuit breaker 4 via the main cable 3a,
When 3b is cut off, it is sent to the prime mover governor 12 and the fuel or power source which is the prime mover input P is narrowed down. When the main cables 3a, 3b are disconnected, the prime mover 1 is not subjected to sudden short-circuit torque, so the prime mover 1 and the shaft coupling Q are protected. The input P is also positively suppressed by the prime mover governor 12, so that the prime mover 1 is protected. By the way, in order to protect the prime mover 1 from a short-circuit accident, one of the prime mover governor 12 and the main circuit breaker 4 may be positively operated by a signal from the short-circuit relay 8. For example, if only the main circuit breaker 4 is operated, it takes time until the narrowing down of the fuel and the like is started due to the control delay, so that the prime mover 1 cannot be sufficiently protected. Therefore, in the present embodiment, the prime mover governor 12 and the main circuit breaker 4 are operated by the signal from the short circuit relay 8.

Moreover, since the prime mover 1 is protected from the short circuit accident by the short circuit relay 8, it is not necessary to provide the shear pin. Therefore, the recovery work for cutting the shear pin can be eliminated. If it is desired to protect the motor with a mechanical fuse, a shear pin may be provided. The set value b of the short-circuit relay 8
2 is lower than the protection coordination curve G of the generator 2 as shown in FIG. 2, so that when a short-circuit accident occurs, the operation of the short-circuit relay 8 also indirectly protects the generator 2. It will be. Further, in this embodiment, a relay for continuously detecting a relatively low overcurrent is not provided, but this is because the short-circuit relay 8 can handle this.

Next, the operation of the power factor relay 8 will be described in detail. When the power generation facility G and the commercial power source W are operated in parallel, as described above, the reactive power adjustment malfunction caused by the trouble of the automatic voltage regulator 10 or the like causes an excess from the power generation facility G to the commercial power source W side. It is conceivable that the generator 2 may be overloaded as well as the electric power is supplied.

Therefore, provided is a power factor relay 9 which detects and operates the power factor fluctuation of the output of the power generation equipment G. When the power factor fluctuation exceeds a prescribed value, the main circuit breaker 4 is operated to output the output cable. The current flowing through 3a and 3b is cut off.
In addition, the power factor relay 9 has a co
sφ = 0.8, cosφ = for the current delay direction
It is set to 0.6. Therefore, by providing the power factor relay 9, it is possible to prevent excessive power supply to the commercial power source W side and damage to the generator 2 which may occur due to a trouble of the automatic voltage regulator 10 or the like.

[0027]

According to the present invention, a short-circuit relay is provided to prevent a sudden short-circuit torque from being applied to a prime mover when a short-circuit accident occurs. Therefore, the prime mover can be protected from a short-circuit accident. In addition, mechanical fuse (shear pin)
Since it is unnecessary, the downtime of the power generation equipment due to a short circuit accident can be made extremely short because it is only necessary to restore the cause of the short circuit.

Further, since the power factor relay is provided, the power supply from the power generation equipment to the commercial power supply side and the generator being overloaded, which occur when the power generation equipment and the commercial power supply are operated in parallel. Can be prevented.

[Brief description of drawings]

FIG. 1 is a system diagram of a power generation facility according to an embodiment of the present invention.

FIG. 2 is a graph showing a characteristic curve of a relay according to an embodiment of the present invention.

FIG. 3 is a graph showing the operation of the conventional power generation equipment when a short-circuit accident occurs.

[Explanation of symbols]

1 ... motor, 2 ... generator, 3a, 3b ... output cable,
4 ... Main circuit breaker, 5 ... Trip circuit, 6 ... Voltage relay, 7 ... Current relay, 8 ... Short circuit relay, 9 ... Power factor relay, 10 ... Automatic voltage regulator, 11 ... Generator field, 12 ...
Motor governor, 13 ... Control circuit, 14 ... Control device, G ...
Power generation equipment, W ... Commercial power supply.

Front page continuation (72) Inventor Kazuo Iijima 3-2-1, Sachimachi, Hitachi City, Ibaraki Prefecture Hitachi Engineering Co., Ltd.

Claims (6)

[Claims] 1. A power generation facility comprising a prime mover and a generator driven by the prime mover, a circuit breaker for disconnecting a power line of the generator, and a power line set to a value capable of protecting the generator. When the current flowing through exceeds the value, a short circuit current flowing through the power path is detected separately from the current relay that operates the circuit breaker and the current relay, and the circuit breaker is operated when the short circuit current is detected. A power generation facility comprising a short-circuit relay and. 2. A regulator for adjusting an input amount to the prime mover, wherein the short-circuit relay operates the circuit breaker when the short-circuit current is detected, and operates the regulator to reduce the input amount. The power generation equipment according to claim 1, wherein 3. A power generation facility comprising a prime mover and a generator driven by the prime mover, a circuit breaker for disconnecting a power path of the generator, and a value capable of protecting the generator. When the current flowing through exceeds the value, a current relay that operates the circuit breaker, a regulator that adjusts the input amount to the prime mover, and the current relay, separately from the current relay, detects a short-circuit current flowing through the power path. And a short-circuit current relay that operates the regulator so that the input amount decreases when the short-circuit current is detected. 4. The short circuit relay is set to operate when 125% to 170% of the rated current of the generator flows for 0.2 to 0.5 seconds. The power generation facility according to 1, 2, or 3. 5. A power factor relay for activating the circuit breaker when the power factor of the electric power path is detected and when the power factor exceeds a predetermined range. Or the power generation facility described in 3. 6. A circuit breaker for interrupting a power line of a generator, and a power factor relay for detecting the power factor of the power line and operating the circuit breaker when the power factor exceeds a predetermined range. A power generation facility characterized by being equipped with.