JPH0568196B2 - - Google Patents

Description

[Detailed Description of the Invention] [Objective of the Invention] (Industrial Application Field) The present invention is an AC variable speed system for a pumped storage power generation plant, in particular, when starting pumping operation, the system starts up and connects synchronously to the grid power source. The present invention relates to a method for controlling the start of pumping storage operation in the process from starting the pumping storage operation to starting the pumping storage load operation.

(Prior Art) Pumped storage power plants in recent years have become increasingly larger in capacity to accommodate nuclear power plants, and also tend to have higher heads due to location conditions and efficiency of pump turbines. Generally, in pumped storage power plants with large head fluctuations, a water level response device is applied that adjusts the guide vane opening to an appropriate degree according to the head (head) in order to achieve efficient operation during pumped load operation. ,
Since the generator-motor is a synchronous machine, the rotational speed is constant, so there is a limit to how much the operating efficiency can be improved. Therefore, recently, an AC variable speed system has been proposed in which an induction machine is used instead of a synchronous machine and a cycloconverter is connected to the rotor side of the induction machine.

FIG. 5 shows an example of the main circuit configuration of an AC variable speed system for this type of pumped storage power generation plant. In FIG. 5, 1 is a pump-turbine, and 2 is a rotor side that is mechanically directly connected to the pump-turbine 1, and a stator side that is connectable to a system power supply 4 via a parallel disconnector 3. It is an induction machine. Further, a starting disconnector 5 is connected to the stator side of the induction machine 2. On the other hand, 6 is a cycloconverter system power supply whose input side is connected to the system power supply 4 via a cycloconverter sheath disconnector 7, and which includes a thyristor or the like for converting the frequency of the system power supply 4 to a required frequency. Its output side is connected to the rotor side of the induction machine 2.

When the AC variable speed system starts pumping load operation, the cycloconverter 6 adjusts and controls the guide vane opening and rotation speed of the pump turbine 1 to appropriate values according to the head difference (head) at that time. It is also possible to adjust and control the guide vane opening degree and rotation speed so as to enable efficient operation and to maintain an allowable input amount especially for continuous capacity (surplus power) at night.

However, in such an AC variable speed system, in the process of controlling the rotation speed from the start of pumping storage operation to the appropriate rotation speed during load operation, the problem is how to control the rotation speed from the time the grid power is connected to the start of pumping storage load operation. Become. Generally, in order to reduce the reaction torque at the start of pumping operation, compressed air is supplied to the draft to increase the speed of the pump turbine 1 while it is idling, and the draft is exhausted after the grid power is connected.
When the priming water pressure is established, the guide burn is opened and pumping load operation is started. However, the pump is in a shut-off state until the priming water pressure is completely established, and the higher the rotation speed at this time, the higher the shut-off pressure than necessary is applied to the pump-turbine 1, causing vibrations and temperature changes. This is an important problem for pumped storage power plants where the number of starts and stops is very large, as it may eventually become a cause of failure of the pump-turbine 1, and may also affect the service life of the pump-turbine 1.

(Problems to be Solved by the Invention) As described above, in the conventional starting method of an AC variable speed system in a pumped storage power generation plant, the pumping storage operation starts, and the The mechanical load placed on the pump-turbine is large, and the pump-turbine is subjected to more than necessary shut-off pressure, which can cause the pump-turbine to malfunction or shorten its lifespan.

Therefore, in the present invention, in an AC variable speed system for a pumped storage power generation plant, positive water operation is started to reduce the mechanical load on the pump turbine between the time when grid power is connected and the start of pumped storage load operation, and the mechanical load on the pump turbine is reduced. It is an object of the present invention to provide a pumping operation start control method for a variable speed induction machine that can ensure mechanical safety and improve its life.

[Structure of the Invention] (Means for Solving the Problems) In order to achieve the above object, in the present invention, the pump-turbine and the rotor side are mechanically directly connected to the pump-turbine, and the stator side is connected to the system. An AC variable speed system for a pumped storage power generation plant that includes an induction machine that is connectable to a power source and a cycloconverter that is connected to the rotor side of the induction machine and converts the grid power frequency to a required frequency. When starting the pumping operation of the pumped storage power generation plant, it is first started on the condition that the draft water level has been lowered, and the cycloconverter supplies power at the required frequency to the induction machine to increase the speed,
Next, when the speed has increased to the minimum rotation speed that establishes the priming water pressure in the pump shut-off state, the cycloconverter applies AC excitation to the induction machine to synchronously connect the induction machine to the grid power supply, and then the draft exhaust is turned off. The invention is characterized in that the constant minimum rotational speed control is continuously performed until the priming water pressure is established.

(Function) In the above-mentioned pumping storage operation start control method, at the time of starting pumping operation, after the induction machine is synchronized with the grid power supply and until the pumping storage load operation is started, appropriate minimum rotation speed control is performed. Therefore, in the pump shut-off state until the priming water pressure is completely established, it is possible to prevent more than necessary shut-off pressure from being applied to the pump-turbine.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 shows a configuration example of an AC variable speed system for a pumped storage power generation plant to which the present invention is applied, and the same parts as in FIG. 5 are denoted by the same reference numerals.

In FIG. 1, 1 is a pump-turbine, 2 is a rotor side that is mechanically directly connected to the above-mentioned pump-turbine 1, and a stator side that is connected in parallel to the system power supply 4 via a disconnector 3 and a main transformer 8. This is an induction machine that can be connected to. Further, a starting disconnector 5 is connected to the stator side of the induction machine 2. Furthermore, the input side of 6 is connected to the above-mentioned grid power supply 4 via a cycloconverter transformer 9 and a cycloconverter shield disconnector 7, and is connected to a thyristor or the like for converting the frequency of the grid power supply 4 to a required frequency. The output side of the cycloconverter system power supply is connected to the rotor side of the induction machine 2. On the other hand, 10
is a control device, 11 is a potential transformer (PT) installed on the grid power supply 4 side of the parallel shield breaker 3, and 12 is an instrument transformer (PT) installed on the induction machine 2 side of the parallel shield breaker 3. A transformer (PT) 13 is a rotation speed detector 1 provided on the rotor side of the induction machine 2 to detect its rotation speed.
4 is an instrument current transformer (CT) for detecting the output current of the cycloconverter 6; 15 is a head detector for detecting head; and 16 is a priming water pressure detector for detecting priming water pressure. In addition,
The solid line arrows in the diagram indicate the respective detectors 11, 12, 13, 1.
4, 15, and 16 to the control device 10, and dotted arrows represent each control command from the control device 10. In addition, IG ₂ is the output current of the cycloconverter 6, VG ₂ is the output voltage of the cycloconverter 6, IG ₁ is the input current of the induction machine 2, VG ₁ is the input voltage of the induction machine 2, fG is the frequency of the induction machine 2, N
represent the rotational speed of the induction machine 2, respectively.

Next, the pumping operation start control method according to this embodiment will be explained with reference to the control block diagram shown in FIG. 2 and the flowchart shown in FIG. 3.

Now, a pumping operation command is given from the plant operation device (not shown), and when the draft water level has been lowered and the cycloconverter disconnector 7 is turned on, the starting disconnector 5 is closed and the stator of the induction machine 2 is closed. short the sides. When the starting disconnector 5 closes, low-frequency power is supplied from the cycloconverter 6 to the rotor of the induction machine 2, and speed-up control of the induction machine 2 is started. During this period, the output voltage VG ₂ of the cycloconverter 6 increases in proportion to the rotation speed, and the output current IG ₂ of the cycloconverter 6 and the input current of the induction machine 2
IG ₁ are each controlled to approximately constant current.

Next, when the speed is increased to the minimum rotation speed that establishes the priming water pressure determined by the head at that time, the output current of the cycloconverter 6 is controlled by synchronization switching control of the cycloconverter 6.
Set IG ₂ to “0”. The minimum rotation speed at this time is determined from the minimum rotation speed characteristics given in Fig. 4 based on the input from the head detector 15 and the rotation speed detector 13, and the minimum rotation speed is approximately proportional to the square root of the head. will be the value. Also, at this time, the output voltage VG ₂ of the cycloconverter 6 and the input current of the induction machine 2
IG ₁ also becomes "0".

Next, when the output current IG ₂ of the cycloconverter 6 becomes "0" (the output from the cycloconverter output current meter current transformer 14 is "0"), the starting disconnector 5 is turned on. open. When the starting disconnector 5 opens, the input voltage VG ₁ and frequency fG of the induction machine 2 are synchronized with the system power supply 4 by controlling the cycloconverter 6 with AC excitation. In this way, the system power supply side voltage transformer 11 and the induction machine side voltage transformer 12
When a grid paralleling condition is detected based on the output from the system, the parallel shield disconnector 3 is turned on, and when the parallel shield disconnector 3 is turned on, draft exhaust control is performed on the plant side (not shown). The minimum rotation speed constant control is continued until the priming water pressure is established based on the output from the priming water pressure detector 16. After the priming water pressure is established, proper rotation speed control is performed by pumping load operation.

As described above, in this embodiment, when starting the pumping operation of the pumped storage power generation plant, it is first started on the condition that the draft water level has been lowered, and power at the required frequency is supplied from the cycloconverter 6 to the induction machine 2. Then, when the speed increases to the minimum rotation speed according to the head (head) at that time, which establishes the priming water pressure in the pump shut-off state,
The cycloconverter 6 applies alternating current excitation to the induction machine 2, connects the induction machine 2 synchronously to the grid power supply 4, and then continues the constant minimum rotation speed control until draft exhaustion is performed and priming water pressure is established. Since this is done, an appropriate minimum rotational speed can be maintained from the time when the system power source 4 is synchronously connected to the system power source 4 at the start of the pumping operation until the pumping load operation is started. This ensures the mechanical safety of the pump-turbine 1 in the pump shut-off state, eliminates failures of the pump-turbine 1, and improves its lifespan.Moreover, it improves economic efficiency by shortening the plant start-up time. This makes it possible to improve the situation.

Incidentally, in the above embodiment, a circulating cycloconverter method was applied, but even if a non-circulating cycloconverter method was applied or the cycloconverter 6 was connected to the stator side of the induction machine 2, the same effect as described above would be achieved. It goes without saying that this effect can be obtained.

In addition, the present invention can be modified and implemented in various ways without changing the gist thereof.

[Effects of the Invention] As explained above, according to the present invention, in an AC variable speed system for a pumped storage power generation plant, when starting the pumping operation of the pumped storage power generation plant, the startup is first performed on the condition that the draft water level has been lowered. Then, the cycloconverter supplies power at the required frequency to the induction machine to increase the speed, and then, when the speed has increased to the minimum rotation speed that establishes the priming water pressure in the pump shut-off state, the cycloconverter applies AC excitation to the induction machine. The induction motor was synchronously connected to the grid power supply by giving a , a variable-speed induction machine that reduces the mechanical load on the pump-turbine between the time the grid power is connected and the start of pumped-storage load operation, ensures mechanical safety of the pump-turbine, and extends its service life. A pumping operation start control method can be provided.

[Brief explanation of the drawing]

FIG. 1 is a circuit configuration diagram showing an embodiment of the present invention;
Fig. 2 is a control block diagram for explaining the pumping operation start control method in the same embodiment, Fig. 3 is a time chart for explaining the pumping operation start control method in the same embodiment, and Fig. 4 is a control block diagram for explaining the pumping operation start control method in the same embodiment. FIG. 5, which is a diagram showing the minimum rotation speed characteristics in an example, is a main circuit configuration diagram of an AC variable speed system of a conventional pumped storage power generation plant. 1... Pump water turbine, 2... Induction machine, 3... Parallel cable breaker, 4... System power supply, 5... Starting disconnector, 6... Cyclo converter, 7... Cyclo converter cable Disconnector, 8... Main transformer, 9...
Cycloconverter transformer, 10... Control device, 11... System power supply side instrument transformer, 12...
Induction machine side instrument transformer, 13... rotation speed detector,
14... Instrument current transformer for cycloconverter output current, 15... Head (head) detector, 16... Priming water pressure detector.

Claims (1)

[Scope of Claims] 1. A pump-turbine, an induction machine whose rotor side is mechanically directly connected to the pump-turbine and whose stator side is connectable to a grid power supply, and a rotor side of the induction machine that is connected to the system power supply. In an AC variable speed system for a pumped storage power plant that is configured to include a cycloconverter that is connected to the system and converts the system power frequency to a required frequency, when starting the pumping operation of the pumped storage power plant, first the draft water level is pushed down. Start on condition that the induction machine is completed, supply power at the required frequency from the cycloconverter to the induction machine, increase the speed, and then increase the speed to the minimum rotation speed that establishes the priming water pressure in the pump shut-off state. The cycloconverter applies alternating current excitation to the induction machine to synchronously connect the induction machine to the grid power supply, and then the minimum rotation speed constant control is continued until draft exhaustion is performed and priming water pressure is established. A pumping operation start control method for a variable speed induction machine, characterized in that: 2 The minimum rotation speed is the head (lift) at that time.
A pumping operation start control method for a variable speed induction machine according to claim 1, characterized in that the value is set in accordance with .