JP2009138633A - Water supply system generator set - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a water supply system generator set capable of quickly stopping a hydraulic turbine without setting limitation in the operation of a water supply system. <P>SOLUTION: A hydraulic turbine bypass conduit 17 including a bypass valve 18 is provided in parallel with a hydraulic turbine water supply conduit 13. A valve open and close operation device 19 closes a hydraulic turbine start valve 15 of the hydraulic turbine water supply conduit 13 and opens the bypass valve 18 to make a water quantity flowing in the hydraulic turbine water supply conduit 13 bypass the hydraulic turbine bypass conduit 17 according to the close operation of the hydraulic turbine start valve 15 when a stop signal of the hydraulic turbine 14 is inputted. After the hydraulic turbine start valve 15 is fully closed, the device opens a flow rate adjusting valve 12 to make the water quantity flowing through the bypass valve 18 flow to the flow rate adjusting valve 12 of the water supply conduit 11, and closes the bypass valve 18 according to the open operation of the flow rate adjusting valve 12. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a water supply system power generation facility in a water supply system.

  There is a water supply system power generation facility in which a small water wheel is installed in the middle of a water supply system such as a water supply water pipe or an agricultural and industrial water pipe, and power is generated by excess pressure in the water supply pipe (see, for example, Patent Document 1). ). This water transmission system power generation facility uses water that is originally used for purposes other than power generation for power generation, and therefore allows water to flow with priority on the original purpose of use.

  For example, when power generation is performed using water in a water supply pipeline, priority is given to water supply operation of the water supply, and the water turbine is operated depending on the water supply operation of the water supply. Sudden changes in water supply volume in a short period of time cause deterioration of water quality (dirt) and pressure fluctuations, and cause damage to pipelines depending on the degree of pressure fluctuations. There is a restriction that it must not be. Accordingly, the operation of the water wheel installed in the water supply facility is controlled so that the amount of change in the flow rate per short time is reduced.

  FIG. 5 is a system diagram showing an example of a water transmission system power generation facility. A water turbine water supply line 13 is provided in parallel with the flow rate adjustment valve 12 of the existing water supply line 11, and a water wheel 14 and a water wheel start valve 15 are arranged in series in the water wheel water supply line 13. Are connected. Thus, a part or all of the water branched from the water supply pipe 11 and flowing into the water supply pipe 11 is passed through the water turbine water supply pipe 13 and used for power generation.

  The water flowing through the water supply pipe 11 fluctuates according to the demands of water users, and when the flow fluctuation is all adjusted by the water wheel 14, the water wheel 14 performs phase control and fine adjustment to the flow adjustment valve of the water supply pipe 11. 12 may be performed.

  In the water supply pipeline, adjustment of the water supply flow rate takes time. This is to prevent damage to facilities such as water pipes due to ensuring water quality and increasing pressure. Therefore, it is necessary to adjust the flow rate flowing through the water wheel 14 over time as well.

Here, when the water turbine 14 is stopped and the power generation is stopped, the water flow to the water turbine 14 is stopped, so that the water flowing through the water turbine water supply line 13 is switched to the water supply line 11. become. In this case, the water turbine start valve 15 is gradually closed in accordance with the response of the flow rate adjustment valve 12 installed in the water supply pipe 11, and the water flow of the water turbine 14 is stopped. For example, the water turbine start valve 15 is closed over 5 to 10 minutes, and the water that has been passed through the water turbine 14 is switched to the water supply pipe 11 side. The water turbine start valve 15 operates so as to automatically close at a predetermined time when a stop signal of the water turbine 14 is inputted. The closing time is determined by the maximum water flow rate of the turbine, and is constant regardless of the water flow rate.
JP 2002-257026 A

  However, in the case of a water transmission system power generation facility, the priority is given to the original purpose of use of the water transmission system, so even when the water turbine 14 needs to be stopped urgently, the response of the flow rate adjustment valve 12 of the water supply pipeline 11 You must stop at the speed. The response of the flow rate adjustment valve 12 in the water supply pipe 11 is slow, and the turbine 14 is stopped in accordance with the slow response, so the stop time of the turbine 14 becomes long.

  If the generator 16 is disconnected from the electric power system in the process of stopping the water turbine 14, the energy that has been converted to electricity so far acts as energy for rotating and raising the water turbine 14. Therefore, if the stop time of the water turbine 14 becomes longer, the time during which the water wheel 14 is operated at high speed becomes longer, causing bearing wear of the generator 16 and greatly affecting the life of the equipment.

  On the other hand, if the response of the flow rate adjustment valve 12 of the water supply pipeline 11 can be accelerated, the stop time of the water wheel 14 can be shortened. However, since this will limit the operation prioritizing the original purpose of use of the water supply system, The response of the flow regulating valve 12 cannot be accelerated.

  An object of the present invention is to provide a water transmission system power generation facility that can quickly stop a water turbine without restricting the operation of the water transmission system.

  The water transmission system power generation facility according to the invention of claim 1 is a water transmission system power generation facility in which a water turbine is provided in the middle of a water supply pipeline of the water supply system, and the turbine is driven by surplus pressure of the water supply pipeline to generate power. A flow rate adjusting valve that is installed in the water pipeline and adjusts the amount of water delivered to the water supply pipeline, and a water turbine start valve that is installed in parallel to the water supply pipeline provided with the flow rate adjustment valve and starts and stops the water turbine and the water turbine. A water turbine water supply pipe provided in series, a water turbine bypass pipe installed in parallel to the water turbine water supply pipe and having a bypass valve, a valve for opening and closing the flow rate adjusting valve, the water turbine start valve, and the bypass valve An opening / closing operation device, and the valve opening / closing operation device closes the water turbine start valve when a stop signal of the water wheel is input, and the water turbine water supply line corresponds to the operation of closing the water turbine start valve. The amount of water flowing in The bypass valve is opened so as to be bypassed to the vehicle bypass pipe, and after the water turbine start valve is fully closed, the bypass valve is set so that the amount of water flowing through the bypass valve is passed through the flow regulating valve. The flow control valve is opened gradually in response to the closing operation of the bypass valve.

  A water transmission system power generation facility according to a second aspect of the present invention is the water transmission system power generation facility in which a water turbine is provided in the middle of the water supply pipeline of the water supply system, and the turbine is driven by the residual pressure of the water supply pipeline to generate power. A flow rate adjusting valve that is installed in the water pipeline and adjusts the amount of water delivered to the water supply pipeline, and a water turbine start valve that is installed in parallel to the water supply pipeline provided with the flow rate adjustment valve and starts and stops the water turbine and the water turbine. A water turbine water supply pipe provided in series, a water turbine bypass pipe installed in parallel to the water turbine water supply pipe and having a bypass valve and a standby valve in series, the flow rate adjusting valve, the water wheel start valve, and the bypass valve And a valve opening / closing operation device for opening / closing the standby valve, wherein the valve opening / closing operation device fully closes the standby valve during operation of the water turbine, and sets the opening of the bypass valve to the water turbine water pipe. Equivalent to the amount of water flowing in the road When the turbine stop signal is input, the standby valve is opened and the turbine start valve is closed, and the turbine start valve is closed in response to the closing operation of the turbine start valve. The water amount flowing through the water turbine water supply conduit is bypassed to the water turbine bypass conduit, and the water amount flowing through the bypass valve is passed through the flow rate adjusting valve after the water turbine start valve is fully closed. The standby valve is closed, and the flow rate adjusting valve is opened in response to the standby valve closing operation.

  According to the present invention, when the stop signal of the water turbine is input, the water turbine start valve is closed, the bypass valve is opened in response to the water turbine start valve closing operation, and the water turbine water supply pipe is flowing. Since the amount of water is bypassed to the water turbine bypass pipe, the water flow through the water turbine water pipe can be quickly shut off. Thereby, a water turbine can be stopped quickly. In addition, after the turbine start valve is fully closed, the bypass valve is closed and the flow rate adjustment valve is opened in response to the bypass valve closing operation. According to the flow rate control valve.

  Accordingly, since the water turbine does not continue to rotate for a long time, the life of the bearings of the generator can be extended, and damage to the water transmission system power generation equipment and deterioration of water quality can be prevented. In addition, since the stop of the water turbine can be controlled independently, the operation of the existing water transmission system is not limited and can be applied regardless of the type of water turbine used and the operating conditions of the installation destination.

  FIG. 1 is a configuration diagram showing an example of a water transmission system power generation facility according to an embodiment of the present invention. In contrast to the conventional example shown in FIG. 5, a water turbine bypass pipe 17 is additionally provided in parallel with the water turbine water supply pipe 13, and a bypass valve 18 is provided in the water turbine bypass pipe 17. Then, the valve opening / closing operation device 19 opens / closes the flow rate adjusting valve 12, the water wheel start valve 15, and the bypass valve 18. The same elements as those in FIG. 1 are denoted by the same reference numerals, and redundant description is omitted.

  The flow rate adjusting valve 12 installed in the water supply line 11 adjusts the amount of water sent to the water supply line 11, and gradually the water supply line 11 so that the water supply amount of the water supply line 11 does not change suddenly in a short time. Adjust the amount of water delivered to the tank. As a result, deterioration of water quality (dirt) and pressure fluctuation are prevented. A water turbine water supply line 13 is provided in parallel with the water supply line 11, and a water wheel 14 for generating power by the residual pressure of the water supply line 11 is installed in the water wheel water supply line 13, and the water wheel 14 is connected in series with the water wheel. A water turbine start valve 15 is provided for adjusting the amount of water flowing through the water.

  Further, a turbine bypass pipe 17 having a bypass valve 18 is provided in parallel with the turbine feed pipe 13. The water turbine bypass pipe 17 is provided to absorb a sudden change in the amount of water flowing through the water turbine water supply pipe 13. A stop signal of the water turbine 14 is input, and a fluctuation in the amount of water generated when the water turbine 14 is quickly stopped. To absorb. That is, when the water turbine 14 is quickly stopped, the opening degree of the bypass valve 18 is adjusted so as to absorb the fluctuation of the amount of water flowing through the water turbine water supply conduit 13, and before the turbine stops, during the turbine stop, after the turbine stop. The flow rate fluctuation of the amount of water flowing in the water supply pipe 11 of the water supply system is prevented.

  When the turbine stop signal is input, the valve opening / closing operation device 19 closes the turbine start valve 15 and opens the bypass valve 18, and the turbine feed water line 13 corresponds to the closing operation of the turbine start valve 15. The amount of water that has been flowing through the turbine is bypassed to the turbine bypass conduit 17. Then, after the turbine start valve 15 is fully closed, the amount of water flowing through the bypass valve 18 is gradually passed through the flow rate adjustment valve 12. That is, the bypass valve 18 is closed and the flow rate adjustment valve 12 is opened in response to the bypass valve 18 closing operation. Thereby, while being able to stop the water turbine 14 quickly, the operation | movement according to the original water supply operation | movement of a water supply system can be performed, without producing a pressure fluctuation in a water supply system.

  FIG. 2 is an explanatory diagram of the movements of the flow rate adjusting valve 12, the turbine start valve 15 and the bypass valve 18 from before the turbine stop to the completion of the turbine stop. FIG. 2 (a) shows the operation of the turbine and FIG. FIG. 2 (c) shows the movement of the flow rate adjusting valve 12, the water wheel start valve 15 and the bypass valve 18 when the water turbine stop control is completed. In addition, regarding the notation of each valve, black fill indicates fully closed, white indicates fully open, hatched indicates an intermediate opening degree from fully closed to fully open, and left one hatched indicates a state in which the closing operation is started. In FIG. 2, the generator 16 and the valve opening / closing operation device 19 are not shown.

  As shown in FIG. 2A, during the water turbine operation, the water turbine start valve 15 is fully opened, and the flow rate adjustment valve 12 and the bypass valve 18 are fully closed. In the sharing of the water supply amount, during the normal water turbine operation, the water supply start valve 15 bears the entire amount of water supply, and the flow rate adjustment valve 12 and the bypass valve 18 both bear zero.

  Next, when a turbine stop signal is input, turbine stop control is started. As shown in FIG. 2B, in the turbine stop control, the flow rate adjustment valve 12 remains fully closed, the operation of the turbine start valve 15 starts from the fully open state to the fully closed state, and the bypass valve 18 operates as the turbine wheel. The opening operation is started from the fully closed state in accordance with the operation of the water turbine start valve 15 until the opening according to the water flow amount. The share of the water supply amount is zero for the flow rate control valve 12, gradually decreases for the water turbine start valve 15, and increases for the bypass valve 18 as the water flow rate decreases. Then, when the turbine start valve 15 is fully closed, the turbine stops. In this state, the share of the water supply amount is zero for the flow rate control valve 12 and the turbine start valve 15, and the bypass valve 18 is the amount of water flow through the turbine start valve 15 during the turbine operation.

  Next, after the turbine stops, control after stopping the turbine is started to switch the flow of water flowing through the bypass valve 18 to the flow rate adjustment valve 12. As shown in FIG. 2C, the turbine start valve 15 is fully closed, the flow rate control valve 12 is gradually opened from zero, and the bypass valve 18 decreases as the flow rate of the flow rate control valve 12 increases. The share of the water supply amount gradually increases as the flow rate adjustment valve 12 increases, the water wheel start valve 15 becomes zero, and the bypass valve 18 gradually decreases as the flow rate adjustment valve 12 increases. Then, as shown in FIG. 2 (d), when the bypass valve 18 is fully closed, the turbine stop control is completed.

  FIG. 3 is a graph of the opening degree of the flow rate adjustment valve 12, the water wheel start valve 15 and the bypass valve 18 from the time before the water wheel stop to the time when the water wheel stop is completed. Before the time t1 before the turbine stop, the flow rate adjustment valve 12 and the bypass valve 18 are fully closed and the turbine start valve 15 is fully open, and the turbine is operating. When the turbine stop signal is input at time t1, the valve opening / closing operation device 19 keeps the flow rate control valve 12 fully closed, closes the turbine start valve 15 from fully open to fully closed, and bypasses it. The valve 18 is opened from fully closed in accordance with the operation of the water turbine start valve 15. As a result, a part of the water flow amount flowing to the water turbine start valve 15 flows to the bypass valve 18 and the water wheel flow amount decreases. Then, when the generator 16 is disconnected from the power system at the time t1, the synchronization is lost from the power system, and the rotational speed of the water turbine 14 of the water turbine 14 and the generator 16 that have been in a high rotation speed is reduced due to a decrease in the amount of water passing through the turbine.

  When the turbine start valve 15 is fully closed at time t3, the turbine is stopped and the bypass valve 18 is fully opened (set opening). At the time t4 after the elapse of a predetermined waiting time T from the time t3, the control after stopping the water turbine for switching the water flow flowing through the bypass valve 18 to the flow rate adjusting valve 12 is started. The flow rate control valve 12 is gradually opened from time t4, and the bypass valve 18 is closed as the flow rate control valve 12 increases. The opening operation of the flow control valve 12 is performed according to the original operation of the water supply system. When the flow rate adjustment valve 12 reaches an opening degree corresponding to the water passage amount at the time point t5, the bypass valve 18 is fully closed, and the turbine stop control is completed.

  In this way, when the turbine stop signal is input to the valve opening / closing operation device 19, the turbine start valve 15 is operated from fully open to fully closed, the bypass valve 18 is operated from fully closed to open, and the water flow through the turbine is started. The valve 15 is switched to the bypass valve 18. The opening operation speed of the bypass valve 18 is made to follow the opening degree at which the water flow reduced by the change in the opening degree of the water turbine start valve 15 can flow. Therefore, even if the water passage of the water turbine water supply pipe is shut off quickly, the water turbine can be stopped quickly because there is no sudden change or pressure fluctuation in the water delivery amount.

  FIG. 4 is a configuration diagram showing another example of the water transmission system power generation facility according to the embodiment of the present invention. This example is different from the example shown in FIG. 1 in that a standby valve 20 is added in series with the bypass valve 18 to the water turbine bypass pipe 17, and the standby valve 20 is fully closed during the water turbine operation. The standby valve 20 is quickly opened simultaneously with the closing operation of the water turbine start valve 15 while adjusting the opening to the same amount as the amount of water flow through the turbine. The same elements as those in FIG. 1 are denoted by the same reference numerals, and redundant description is omitted.

  As shown in FIG. 4, a standby valve 20 is provided in series with the bypass valve 18 in the turbine bypass pipe 17. When a turbine stop signal is input, the valve opening / closing operation device 19 opens the standby valve 20 and closes the turbine start valve 15. At that time, since the opening degree of the bypass valve 18 is adjusted to an opening degree corresponding to the amount of water flowing in the water turbine water pipe 13, even if the water turbine start valve 15 is quickly closed, the water turbine water pipe line has been used up to now. The amount of water passing through the water turbine 13 can be quickly passed through the water turbine bypass conduit 17. Therefore, the amount of water that has been flowing through the water turbine water supply conduit 13 can be quickly bypassed to the water turbine bypass conduit 17, so that the water turbine can be stopped quickly.

  According to the embodiment of the present invention, the flow fluctuation generated during the water turbine stop process is absorbed by the water turbine bypass pipe 17 and the flow fluctuation due to the water turbine stop operation can be suppressed, so that the water turbine can be quickly stopped. The life of the generator can be extended. In addition, it is not necessary to pay the cost of remodeling the installation site or change the operation of the water transmission system.

The block diagram which shows an example of the water transmission system power generation equipment concerning embodiment of this invention. Explanatory drawing of the operation | movement of the flow volume adjustment valve before a turbine stop, the turbine start valve, and a bypass valve before the turbine stop in embodiment of this invention. The graph of the opening degree of the flow regulating valve, the turbine start valve, and the bypass valve before the turbine stop in the embodiment of the present invention until the turbine stop is completed. The block diagram which shows another example of the water transmission system power generation equipment concerning embodiment of this invention. The system diagram which shows an example of the conventional water transmission system power generation equipment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 ... Water supply line, 12 ... Flow control valve, 13 ... Water wheel water supply line, 14 ... Water wheel, 15 ... Water wheel start valve, 16 ... Generator, 17 ... Water wheel bypass line, 18 ... Bypass valve, 19 ... Valve opening and closing Operation device, 20 ... standby valve

Claims (2)

  In a water transmission system power generation facility in which a water turbine is installed in the middle of the water supply pipeline of the water supply system and the turbine is driven by surplus pressure of the water supply pipeline to generate power, the amount of water sent to the water supply pipeline installed in the water supply pipeline is A water flow control valve for adjusting, a water turbine water supply line provided in parallel with the water supply conduit provided with the flow control valve, and a turbine start valve for starting and stopping the water turbine and the water turbine, and the water turbine A water turbine bypass pipe installed in parallel with the water supply pipe and having a bypass valve; and a valve opening / closing operation device for opening / closing the flow rate adjusting valve, the water turbine start valve, and the bypass valve; When the stop signal of the turbine is input, the turbine start valve is closed, and the amount of water flowing in the turbine feed pipe in response to the closing operation of the turbine start valve is bypassed to the turbine bypass pipe. Said to let After opening the bypass valve and fully closing the turbine start valve, the bypass valve is gradually closed so that the amount of water flowing through the bypass valve is passed through the flow regulating valve, and the bypass valve A water transmission system power generation facility characterized in that the flow rate adjusting valve is opened in response to the closing operation.   In a water transmission system power generation facility in which a water turbine is installed in the middle of the water supply pipeline of the water supply system and the turbine is driven by surplus pressure of the water supply pipeline to generate power, the amount of water sent to the water supply pipeline installed in the water supply pipeline is A flow rate adjusting valve to be adjusted, a water turbine water supply line installed in parallel to the water supply line provided with the flow rate adjusting valve and a turbine start valve for starting and stopping the water wheel and the water wheel, and the water wheel A water turbine bypass pipe installed in parallel with the water supply pipe and having a bypass valve and a standby valve in series; and a valve opening / closing operation device for opening / closing the flow rate adjusting valve, the water turbine start valve, the bypass valve and the standby valve; The valve opening / closing operation device keeps the standby valve fully closed during the operation of the water turbine, and adjusts the opening of the bypass valve to an opening corresponding to the amount of water flowing in the water turbine water supply conduit. In addition, the stop signal of the water wheel Is input, the standby valve is opened and the turbine start valve is closed, and the amount of water that has flowed into the turbine feed pipe in response to the operation of closing the turbine start valve is reduced to the turbine bypass pipe. The standby valve is closed and the standby valve is closed so that the amount of water flowing through the bypass valve passes through the flow regulating valve after the turbine start valve is fully closed. The water supply system power generation facility is characterized in that the flow rate adjusting valve is operated to open.

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