JP2829049B2 - Operating method of internal pump device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an operation method of an internal pump device, particularly to an operation method suitable for starting and stopping operation.

[Prior Art] Reactor coolant recirculation system (1) promotes heat transfer from fuel to coolant by forcibly circulating coolant in the core, (2) core and coolant flow rate It is installed for the purpose of controlling the power of the nuclear reactor by changing it, and when this recirculation is performed by an internal pump, there are a plurality of such internal pumps. The operation of the pump is generally performed by a variable speed control. On the other hand, in Japanese Patent Application Laid-Open No. 61-28892, "Internal pump system", a plurality of internal pumps are driven by a variable speed frequency power supply or a pole number conversion motor, and a speed controllable internal pump group and a constant frequency power supply are used. An internal pump group that is driven to perform operation-stop control is divided, and a control operation method combining the two is disclosed. Thus, the flow rate can be smoothly changed as a whole.

[Problem to be Solved by the Invention] Japanese Patent Application Laid-Open No. 61-28892 discloses that, among a plurality of internal pumps, a constant frequency power supply drive pump is used for some of the internal pumps and a variable speed pump is used for the remaining pumps. At the time of change, a method of combining the former number control and the latter rotational speed control is adopted.

However, when pumps with different rotation speeds are operated in parallel,
The problem is how to take measures against the overflow operation of the pump and the shutoff operation of the pump that occur when the plant is started / stopped. That is, when the difference between the rotation speed of the pump operated by the variable speed control and the rotation speed of the pump performing the constant speed operation is large, the high rotation speed pump becomes an extreme overflow operation, and the failure of the high rotation pump drive motor. Cause. In addition, the low-speed pump operates in a shut-off mode in which the discharge amount becomes zero, the internal temperature of the pump increases, and the pump may be burned.

Further, the core power control of the nuclear reactor includes a method by pulling / inserting a control rod and a method by a recirculation flow rate.
The output is controlled by the control rod at the time of start-up or the like, but the output is controlled by the recirculation flow rate during the normal operation. In the future, it is considered that the recirculation flow control will be actively used for the load following operation in the nuclear power plant.

In this recirculation flow rate control, an internal pump is used. To widen the recirculation flow rate control range, at least a majority of the internal pumps must be operated at a variable speed. In a pump system including a constant-speed pump and a variable-speed pump, if a small number of constant-speed pumps are activated first, there is a possibility that an overflow operation will occur.

An object of the present invention is to prevent an overflow operation exceeding a specification range of a drive motor of the pump when a pump performing a constant speed operation is started or stopped, and to prevent a pump operated by a variable speed control from being a cutoff operation. It is intended to provide an operation method of the internal pump device described above.

[Means for Solving the Problems] The present invention relates to a pump operating under variable speed control before starting a pump operating at constant speed, which corresponds to a pump head at the maximum flow rate of the pump operating at constant speed. The pump is accelerated to an operating point, and a pump that performs a constant speed operation after the acceleration is started.

Further, according to the present invention, the pump operated by the variable speed control is decelerated to an operation point corresponding to the pump head at the maximum flow rate of the pump performing the constant speed operation, and thereafter, the constant speed operation is performed. The pump is stopped.

[Operation] According to the present invention, the pump of the variable speed operation is started, and after the start, the pump is accelerated to an operation point corresponding to the pump head at the maximum flow rate of the constant speed operation pump. Since the high-speed pump is started, the plant can be started smoothly, and when both the fixed speed pump and the variable speed pump are operating, the variable speed pump is first switched to the pump at the maximum flow rate of the fixed speed pump. The plant is decelerated to the operating point corresponding to the head, and after reaching this operating point, the fixed speed pump is stopped and then the variable speed pump is stopped, so that the plant can be stopped smoothly.

FIG. 1 is an embodiment of a recirculation system using an internal pump and a control circuit thereof. A reactor core 11 is provided in the pressure vessel 10, and a recirculation flow rate flows into the reactor core 11 via the internal pumps 1 and 2.

FIG. 2 shows an example of the arrangement of the internal pump. Core 11
A plurality of internal pumps 1 and 2 are installed concentrically around. The figure shows an example of ten internal pumps. Among the internal pumps, the pump 2 indicated by a black mark is used for constant speed operation, and the pump 1 indicated by a white mark is used for variable speed operation.

In FIG. 1, the internal pumps 1 and 2 for variable speed operation and constant speed operation are driven by drive motors 1A and 1B, respectively. The drive motor 1A is controlled at a variable speed by the speed control device 3, but the drive motor 1B is driven at a constant speed by direct drive from a power source because of the constant speed operation.

The speed control device 3 includes a switch 30, an input transformer 31, a converter 32, a smoothing circuit 33, an inverter 34, and an output transformer 35. The switch 30 is a turn-on switch, and power is turned on by turning on the switch. The converter 32 performs rectification, and the inverter 34 obtains an AC signal of a predetermined frequency, thereby driving the drive motor 1A. The speed control is performed by the inverter 34.

FIG. 3 shows an embodiment diagram of a control system for all internal pumps. A, C, E, G, and I of the internal pump groups 1 and 2 are defined as one group, and F, B, D, H, and J are defined as one group. This division is performed in such a manner that one group is provided for every other internal pump, and separate power supplies (transformers) 6A and 6B are applied to each group.

Power was applied from the power supply 6A to the internal pump A via the circuit breaker 22, and to the internal pumps C, E, G, I via the circuit breaker 23 and the control device group 4A.

Similarly, power was applied from the power supply 6B to the internal pump F via the circuit breaker 24, and to the internal pumps B, D, H, J via the circuit breaker 25 and the control device group 4B. Here, the control device groups 4A and 4B include the control device 3.

Thus, internal pump 2 (A, F) is powered by 6A, 6B
Therefore, this operation is a constant speed operation. Since the internal pump 1 (C, E, G, I, B, D, H, J) is driven by the control device 3 of the control device group 4A, 4B,
It becomes variable speed operation.

Now, a pump starting method will be described. Figures for this purpose are FIGS. 4 and 5. FIG.

FIG. 4 shows a reactor power control curve, in which the horizontal axis shows the core flow rate and the vertical axis shows the reactor power. The curve shown by the dotted line is the coolant recirculation pump minimum speed curve, which is a curve drawn in consideration of the thermal margin of the core. As the core flow rate is increased according to the present invention, the reactor power also increases. This is shown by the characteristic curve 30-31.

FIG. 5 shows a pump performance curve, in which the horizontal axis indicates the flow rate and the vertical axis indicates the pump stroke. A characteristic curve 32 is a characteristic of the constant speed pump 2 (A, F) in parallel operation, and a characteristic curve 38 is a variable speed pump 1 (C, E, G, I, B, D, H, J) 8 identical rotation speeds (N ₁ r
pm) under parallel operation. The parallel operation characteristics of a total of 10 units of this constant speed pump 2 and variable speed pump 1
This is a combination of 32 and 38, and the characteristic 33 is the combined characteristic in the figure.

The characteristic curve 35 is a system pressure loss curve.楊程H ₁ is,
This is the length of the intersection 40 between the characteristic curve 32 and the characteristic curve 33, and is the cutoff length of the variable speed pump 1.

The characteristic 39 is a characteristic curve when the speed of the variable speed pump 1 is increased to N ₂ rpm. The combined characteristic of the eight-speed operation and the constant-speed two operation is a characteristic 34. In other words, before the speed increase, the characteristic 38 is obtained in the operation with eight variable speeds, and becomes the characteristic 39 when the speed is increased. The composite characteristic also changes from the characteristic 33 to the characteristic.

The runout limit point 37 is a point showing the maximum flow rate of the pump determined from the performance of the drive motor of the constant speed pump 2 (A, F),楊程H ₃ is a discharge pressure at that time.

The operating point 42 is an intersection between the system pressure loss curve 35 and the synthetic characteristic 33, the time of the rotational speed N ₁ rpm variable speed pump is operating point at the time of ten pumps operated in parallel. The operating point 36 is the intersection of the system pressure loss curve 35 and the combined characteristic 34, and is the operating point of the 10-unit pump parallel operation after the speed of the variable speed pump is increased to N ₂ rpm.

By the way, when starting up, eight variable pumps 8 are started first, and then two constant speed pumps are started. After starting the constant speed pump, two constant speed pumps 2 and variable speed pump 1 are started. 10 units in parallel operation with 8 units. The operating point at this time is the operating point 42. Operating point 42 is the runout limit point 37
The pump head is lower than the pump head (pressure). For this reason, the two drive motors of the constant speed pump 2 are operated beyond their own performance.

Therefore, in this embodiment, the speed-up operation is performed after starting eight variable-speed pumps so that the characteristic 34 is obtained. After the completion of the speed increase, the two constant speed pumps 2 (A, F) are started.
At this time, the operating point under the parallel operation of 10 pumps is operating point 36
Becomes The operating point 36 operates within the performance range of the drive motor of the constant speed pump 2 because the operating point 36 has a pressure higher than the pump head at the run-out limit point.

Note that the rotation speed of the variable speed pump 1 that results in the characteristic curve 39 is referred to as a constant speed pump activation permission setting rotation speed.

The above operation method will be described with reference to FIG. First, the control device groups 4A and 4B are operated, and the inverter 34 enters the variable speed operation of the pump 1 and at the same time, performs the speed-up operation to make the rotation speed of the constant-speed pump start permitted. After confirming that the permissible rotation speed has been reached, the constant speed pump 2 (A, F) is started. After this startup, the constant speed pump 2 enters the rated speed operation.
The pump 1 can be started by turning on the switch 30.
Although not shown, the pump 2 is started by a start switch. These may be performed by the circuit breakers 22 to 25.

When the control rod is pulled out to a preset pattern while the constant speed pump is in operation under the rated speed, the reactor power increases along the curve 30 shown in FIG. I do. From here, when the inverter is controlled to gradually increase the speed of the variable speed pump 1, the output increases along a curve 31 shown in FIG. When the specified output is reached, the start-up of the nuclear power plant ends.

After the start, the normal operation is started. In the normal operation, the output control is performed by controlling the rotation speeds of the eight pumps 1.

On the other hand, when the nuclear power plant is stopped, the control opposite to the start is performed. That is, the variable speed pump 1 is decelerated to the constant speed pump start rotation speed, and the control rod is inserted at the time when the rotation speed is reached. The constant speed pump 2 in which the control rod has been inserted is stopped, and then the variable speed pump 1 is stopped.

FIG. 6 is a diagram showing another embodiment of the present invention. In this embodiment, even when the rotation speed of the constant-speed pump is higher than the set rotation speed, when the operation at a rotation speed lower than the set rotation speed occurs in one variable-speed pump, the constant-speed pump is immediately started. 2 is an embodiment in which the number 2 is stopped.

A contact 47 is provided in series with the circuit breaker 22, and this contact is
The start / stop control circuit 44 turns ON or OFF.
The circuit breaker 22 has a role of a closing switch, and when all the variable speed pumps 1 reach the constant speed pump activation permission set rotation speed,
The operator is convinced and turns the operation switch 48 “ON”.

On the other hand, the control circuit 44 has a comparator, inputs the rotation speed from all the variable speed pumps, and compares the rotation speed with a preset rotation speed of the constant speed pump activation permission set. As a result of this comparison, if the rotation speed has reached the set speed in all the variable speed pumps 1, the contact 47 is turned ON. If at least one has not reached the set number of revolutions, that is, all the variable speed pumps 1 have reached the set number of revolutions, and the contact 47 is turned on. This means that, for example, even if the operator erroneously turns on the operation switch 48 even though all the variable speed pumps 1 have not reached the set number of revolutions, the contact 47 remains OFF. This also has the advantage that erroneous operation can be prevented.

Another embodiment will be described with reference to FIGS. 5 and 7. FIG. Seventh
The figure shows only the curve 39 in the pump performance curve shown in FIG. The curve 39 is a pump performance curve at the time of parallel operation of eight variable speed pumps capable of starting a constant speed pump, as described in the previous embodiment. A curve 35 in FIG. 7 is a system pressure loss curve at the time of parallel operation of eight variable speed pumps. The intersection of this curve and the curve 39 is an operating point at the time of parallel operation of eight variable speed pumps.

In the pump operation method described in the previous embodiment, the seventh set value for starting / stopping the constant speed pump 2
Discharge pump shown in Fig shall choose pressure H _4. That is,
After starting the variable speed pump 1 to the plant startup minimum speed, the pressure discharge further pump becomes H ₄ continue to speed-up, start the constant-speed pump 2 when the pump discharge pressure becomes the H ₄ I do. During plant shutdown, will slow down the variable speed pump 1, when the pump discharge pressure is less than H _4, stops the control rod insertion and constant speed pump 2.

Next, referring to FIG. 8, a description will be given of an interlock corresponding to a malfunction related to the constant speed pump start / stop operation. Interlock operation principle, in the operation principle described in the previous embodiment, as a setting value in the comparator 44, may be stored pressure H ₄ discharge pump discharges the pump as an input signal to the comparator 49 The pressure signal 53 is input. The discharge pressure is obtained by converting the pump inlet / outlet differential pressure into a signal 53 through a differential pressure transmission line 52 and inputting the signal 53 to a comparator 44.

[Effects of the Invention] The present invention has the following effects.

Prior to the constant-speed pump, the variable-speed pump is started, and the variable-speed pump is started after the variable-speed pump shuts down and the variable-speed pump is accelerated to a speed that does not exceed the maximum flow rate of the constant-speed pump. By doing so, a smooth operation can be performed at the time of starting the plant.

When the plant stops, the constant speed pump is stopped when the variable speed pump becomes lower than the specified rotation speed, so that a smooth operation can be performed even when the plant stops.

Also, instead of the above-described set rotation speed for starting / stopping the constant speed pump, the pump discharge pressure or the pump discharge flow rate at the rotation speed is set to a set value for starting / stopping the constant speed pump. Similarly, smooth operation is possible.

Furthermore, by providing a kind of interlock that does not start the constant-speed pump until the variable-speed pump reaches the specified rotation speed or the specified pump discharge pressure, the operation method at the time of starting the plant is not erroneous.

Similarly, by providing a kind of interlock for stopping the constant speed pump when the speed of the variable speed pump becomes lower than the specified rotation speed or the specified pump discharge pressure, the operation method at the time of stopping the plant is not mistaken.

[Brief description of the drawings]

FIG. 1 is an embodiment of the present invention, FIG. 2 is an internal pump arrangement example, FIG. 3 is an embodiment of an operation control system of the present invention,
FIG. 4 is a reactor power characteristic diagram, FIG. 5 is a pump operation characteristic diagram in an embodiment of the present invention, FIG. 6 is an embodiment diagram of an interlock system of the present invention, and FIG. FIG. 8 is an embodiment diagram of another interlock system according to the present invention. 1 ... variable speed operation pump, 2 ... constant speed operation pump,
3 ... speed control device, 34 ... inverter.

Claims (5)

(57) [Claims] 1. An internal pump device used in a reactor coolant recirculation system in which a plurality of internal pumps are installed, a part of the pumps is operated at a constant speed, and the remaining pumps are operated at a variable speed. In the method, the variable speed operation pump is started, and after the start, the speed is increased to an operation point corresponding to the pump head at the maximum flow rate of the constant speed operation pump, and after reaching this operation point, the constant speed operation pump is started. An operation method of the internal pump device which is adapted to be operated. 2. A method for operating an internal pump device according to claim 1, wherein the constant speed pump is started after all pumps for variable speed operation have reached operating points. 3. An operation of an internal pump device used in a reactor coolant recirculation system in which a plurality of internal pumps are installed, a part of the pumps is operated at a constant speed, and the remaining pumps are operated at a variable speed. In the method, both the fixed speed pump and the variable speed pump are operated,
First, the variable speed pump is decelerated to an operating point corresponding to the pump head at the maximum flow rate of the fixed speed pump, and after reaching this operating point, the fixed speed pump is stopped, and then the variable speed pump is stopped. Method of operating the internal pump device. 4. An operation of an internal pump device used for a reactor coolant recirculation system in which a plurality of internal pumps are installed, a part of the pumps is operated at a constant speed, and the remaining pumps are operated at a variable speed. In the method, the pump of the variable speed operation is started, and after this startup, the variable speed pump is operated until the pump head at the maximum flow rate of the constant speed pump reaches the inlet / outlet differential pressure of the pump, and thereafter the fixed speed pump is started. An operation method of the internal pump device which is adapted to be operated. 5. An operation of an internal pump device used in a reactor coolant recirculation system, in which a plurality of internal pumps are installed, a part of the pumps is operated at a constant speed, and the remaining pumps are operated at a variable speed. In the method, both the fixed speed pump and the variable speed pump are operated,
First, the variable speed pump is decelerated to a pump inlet / outlet differential pressure corresponding to the pump head at the maximum flow rate of the fixed speed pump,
A method of operating an internal pump device in which the fixed-speed pump is stopped after the pressure difference is reached, and then the variable-speed pump is stopped.