JP6185284B2 - Pump equipment - Google Patents

Description

  The present invention relates to a pump facility.

  A pump used in a pump facility that discharges river water or the like is controlled to operate at a water level (LWL) or higher at which no air suction vortex is generated and to stop when the water level drops below LWL.

  In the case of such a pump, there is a risk of inundation damage due to a delay in the start of the pump, particularly when there is a start failure in response to a sudden rise in water level such as guerrilla heavy rain. In order to solve this problem, there is a preceding standby type pump that can start the pump regardless of the suction water level.

  The preceding standby pump employs an operation method in which the aerial operation and the drain operation are switched according to the suction water level. In a pump facility where multiple standby standby pumps of the same specification are installed, all pumps simultaneously perform drainage when the water level rises to a certain level, and all units simultaneously operate in air when the water level falls below a certain level. Do. For this reason, there exists a possibility of causing the hunting which a suction water level repeats a rapid fall and rise. In addition, sudden load fluctuations caused by the simultaneous drainage operation of all units may cause abnormalities in the private power generation facilities.

  On the other hand, it is known that a plurality of preceding standby type pumps are arranged with different positions in the height direction of the impeller (FIG. 4 of Patent Document 1). According to this, when the water level rises, each preceding standby type pump performs the drainage operation in order from the pump with the lower arrangement position of the impeller. As a result, it is possible to suppress the occurrence of water level hunting due to the simultaneous operation of the drainage operation and the air operation of all the standby standby pumps.

JP-A-2-78791

  However, the above prior art does not take any consideration into smoothing the cumulative operation time of a plurality of pumps.

  That is, since the impellers and bellmouths of a plurality of pumps are arranged at different positions in the height direction, when the water level rises, the drainage operation is performed in order from the pump with the lower impeller position, And when a water level falls, a pump with a low arrangement position of an impeller will perform drainage operation to the last. Accordingly, the cumulative operation time of each of the plurality of pumps becomes longer as the impeller has a lower arrangement position, and as a result, the accumulated operation time of the pumps may be biased.

  Therefore, the present invention has an object to suppress occurrence of liquid level hunting in a pump facility that discharges liquid using a plurality of pumps, and to smooth the cumulative operation time of the plurality of pumps. And

  One aspect of the pump facility according to the present invention has been made in view of the above problems, and includes a plurality of pumps for discharging liquid, each of the plurality of pumps including the liquid suction port (bell mouth) and the suction pump. An impeller for pumping the liquid from the mouth, and the impellers of the plurality of pumps are arranged at different positions in the height direction, and the suction ports of the plurality of pumps are each at the same height It is arranged at a position in the direction.

  In addition, an intake device that sucks gas in at least one of the plurality of pumps can be provided.

  In addition, a pressure device that pressurizes gas into at least one of the plurality of pumps can be provided.

  The plurality of pumps are divided into a first system having a lower arrangement position of the impeller and a second system having a higher arrangement position of the impeller, and belongs to the first system. And a first pipe for connecting the pressure device, and a second pipe for connecting the pump belonging to the second system and the intake device, wherein the pressure device includes the first pipe. Thus, the gas can be injected into the pump belonging to the first system through the second intake pipe, and the intake device can suck the gas in the pump of the pump belonging to the second system through the second pipe.

  Moreover, the communication piping which connects the said 1st piping and the said 2nd piping, and the switching valve which opens and closes the said communication piping can be provided.

  Further, a switching valve for opening and closing piping between a plurality of pumps belonging to the first system in the first piping, and a plurality of pumps belonging to the second system in the second piping. And a switching valve for opening and closing each of the pipes.

  The plurality of pumps may be connected to the pressure device and the intake device through separate pipes.

  And a controller that switches between the operation of starting the plurality of pumps in order from the side where the impellers are arranged in order, and the smoothing operation for smoothing the cumulative operation time of the plurality of pumps. In the smoothing operation, the control device is operated in order from a pump having a short cumulative operation time among the plurality of pumps, or is operated in an order set via an input interface. In addition, it is possible to control the pressure air by the pressure air device or the air intake by the air suction device.

A discharge valve for opening and closing a discharge pipe for discharging the liquid; an air inflow valve for opening and closing an air inflow pipe for allowing air to flow into the liquid suction port; An open / close valve that opens and closes a pipe connecting the apparatus and the pump, an air valve that opens and closes a communication pipe communicating the inside of the pump and the atmosphere, and the plurality of pumps from the side where the position of the impeller is low A control device that switches between an operation that starts in order and a smoothing operation that smoothes the cumulative operation time of the plurality of pumps, and the control device includes a plurality of the plurality of pumps in the smoothing operation. By closing the discharge valve, the air inflow valve, the on-off valve, and the air valve corresponding to at least one of the pumps, the inside of the pump can be used without using a pressure device. Suppress the rise of the position, it is possible.

According to the present invention, in a pump facility that discharges liquid using a plurality of pumps, the occurrence of liquid level hunting is suppressed, and the cumulative operation time of the plurality of pumps is smoothed. Can do. This stabilizes the operation of the pump equipment and can prevent a specific pump from being loaded.

Drawing 1 is an explanatory view showing the schematic structure of the flood control installation in which the pump installation of this embodiment is installed. FIG. 2 is a diagram illustrating an overall schematic configuration of the pump equipment of the first embodiment and the second embodiment. FIG. 3 is a diagram showing an outline of a vertical-axis spiral mixed flow pump. FIG. 4 is a diagram showing a detailed configuration of the pump. FIG. 5 is a diagram illustrating a flow of operation processing in the pump facility of the second embodiment. Drawing 6 is a figure showing an example of the operation processing in the pump equipment of a 2nd embodiment. Drawing 7 is a figure showing an example of the operation processing in the pump equipment of a 2nd embodiment. FIG. 8 is a diagram illustrating a flow of operation processing in the smooth operation mode. FIG. 9 is a diagram for explaining the cumulative operation time and operation sequence of a plurality of pumps. FIG. 10 is a diagram illustrating an example of an input interface for setting the operation order of a plurality of pumps. FIG. 11 is a diagram illustrating a schematic configuration of the entire pump facility according to the third embodiment. FIG. 12 is a diagram illustrating an overall schematic configuration of the pump facility according to the fourth embodiment.

  Hereinafter, a pump facility according to an embodiment of the present invention will be described with reference to the drawings. Drawing 1 is an explanatory view showing the schematic structure of the flood control installation in which the pump installation of this embodiment is installed. Hereinafter, an example in which the pump facility is provided in the flood control facility will be described. However, the present invention is not limited to this.

  The flood control facility 100 is a facility of a drainage station that forcibly discharges the internal water in the levee land to the outer land according to the situation. The flood control facility 100 may be operated and managed unattended, or an operation manager may be arranged. As shown in the figure, in the present embodiment, the flood control facility 100 is provided at a place where the branch river 20 joins the main river 50. The tributary 20 branches off on the way. The tributaries after branching are called tributaries 30 and 40.

  The flood control facility 100 includes a suction water tank 120, a discharge water tank 130, a drainage lock gate (gate) 140, a natural flow down lock gate (gate) 150, a communication device 170, and a pump facility 300. The pump facility 300 includes a pump 200a to a pump 200d (hereinafter simply referred to as the pump 200), a control device 160, and the like. In the example of FIG. 1, the pump 200 is configured with four series for convenience, but the number of series can be set to an arbitrary number. Details of the pump facility 300 will be described with reference to FIG.

  The suction water tank 120 is installed in the basement of the site 70 where the pump 200, the control device 160, and the communication device 170 are installed. The site 70 can be entered from the road 60. The pump 200, the control device 160, and the communication device 170 are accommodated in the building.

  Water (inner water) flows from the tributary 30 into the suction tank 120. The water stored in the suction water tank 120 is pumped up by the pump 200 and discharged to the discharge water tank 130.

  The drainage gate 140 is provided on a dike constructed between the discharge water tank 130 and the main river 50. By opening the drain gate 140, the water in the discharge water tank 130 is discharged to the main river 50. The natural flow gate 150 is provided at the boundary between the branch river 40 and the main river 50. By opening the natural flow gate 150, the water of the tributary 40 flows into the main river 50 by natural flow. In the present embodiment, the drain gate 140 and the natural flow gate 150 are both configured by a plurality of gates. In the present embodiment, the drain gate 140 and the natural flow gate 150 are opened and closed using an electric motor as a power source.

  The control device 160 controls the overall operation of the flood control facility 100 and the pump facility 300. For example, the control device 160 measures instrumentation data of equipment in the flood control facility 100 and records it in a storage medium. A communication device 170 is connected to the control device 160. In the present embodiment, the communication device 170 performs wireless communication and receives a disaster alarm from a predetermined server.

  The communication device 170 performs wireless communication with a management office (not shown). The management office is a facility that manages a plurality of drainage stations, and an administrator is assigned.

  On the other hand, when the water level of the main river 50 becomes a predetermined value or more, that is, when there is a possibility that outside water may flow backward from the main river 50 to the branch river 20, the natural flow gate 150 is closed. Then, the pump facility 300 is operated and the drain gate 140 is opened. As a result, the internal water of the tributary 30 is forcibly drained into the main river 50, so that it is possible to suppress the occurrence of inundation damage or the like due to the retention of the internal water in the embankment.

(First embodiment)
Next, the overall schematic configuration of the pump facility 300 according to the first embodiment will be described. FIG. 2 is a diagram illustrating a schematic configuration of the entire pump facility according to the first embodiment. FIG. 3 is a diagram showing an outline of a vertical-axis spiral mixed flow pump. FIG. 4 is a diagram showing a detailed configuration of the pump. FIG. 4 is a diagram representatively showing one of the plurality of pumps in FIG.

  As shown in FIG. 2, the pump facility 300 according to the first embodiment includes a plurality of pumps 200 (six in this embodiment) for discharging liquid (river water). Hereinafter, the plurality of pumps are also referred to as pump 200-a to pump 200-f or pump a machine to pump f machine. The number of pumps 200 in the pump facility 300 is arbitrary, but may be, for example, 6 to 8. In the present embodiment, a stand-by standby type vertical shaft pump will be described as an example, but the present invention is not limited thereto. The present invention is also effective as a countermeasure for a pump facility having a horizontal suction pipe such as a vertical-shaft spiral mixed flow pump in which it is difficult to change the bellmouth position. That is, as shown in FIG. 3, when the inflow water channel 610 for flowing water into the suction water tank 650 is an underground water discharge channel and includes a horizontal suction pipe 620 such as a vertical spiral swirl pump 600, LWL (during drainage operation) Since a plurality of pumps (for example, 6 to 8 pumps) drain according to the increase in the water level at which no air suction vortex is generated and the water level in the underground discharge channel, the water level control width is narrowed. In order to perform a preliminary standby operation with such a pump facility, the impeller positions of a plurality of pumps are changed for the above-mentioned reasons. However, if the bell mouth position is changed, the LWL changes and the water level control width becomes narrower. The present invention that can align the mouse position at the same height is effective.

  As shown in FIG. 2, the pumps 200-a to 200-f are installed in the suction water tank 120. Although the depth of the suction water tank 120 is arbitrary, it can be set as the depth of 10m-15m, for example.

Further, as shown in FIG. 2, the pumps 200-a to 200-f are respectively a casing 210-a to a casing having a bell mouth 212-a to a bell mouth 212-f serving as a river water (liquid) suction port. 210-f, and an impeller (impeller) 202-a that pumps river water from the bell mouth 212-a to the bell mouth 212-f.

  Here, the pump equipment 300 will be described using the pump 200-a as a representative. As shown in FIG. 4, the pump 200-a is suspended in the suction water tank 120 by a suspension pipe 220-a. Further, the impeller 202-a is rotatable via a drive shaft 330-a by a drive machine 320-a installed on the drive machine base 310-a. The drive shaft 330-a includes a shaft seal device 332-a that prevents leakage of liquid pumped from the shaft penetrating portion. In addition, a discharge pipe 230-a for discharging river water to the discharge water tank 130 is connected to the suspension pipe 220-a.

  The pump facility 300 includes a discharge valve 340-a provided in the discharge pipe 230-a. The discharge valve 340-a opens and closes the discharge pipe 230-a based on an open / close signal transmitted from the control device 160. In addition, the pump facility 300 includes an air inflow valve 350-a provided in an air inflow pipe 352-a that allows air to flow into a river water inlet (bell mouth 212-a). The air inflow valve 350-a opens and closes the air inflow pipe 352-a based on an open / close signal transmitted from the control device 160.

  In addition, the pump facility 300 includes an on-off valve 360-a provided in a first piping 362 that connects the pressure device 380 that pressurizes gas (air) into the pump 200-a and the pump 200-a. The on-off valve 360-a opens and closes the first pipe 362 based on an open / close signal transmitted from the control device 160. In addition, about the pump 200-d-the pump 200-f, the 2nd piping 364 which connects the intake device 390 which suck | inhales the internal air of the pump 200-d-the pump 200-f, and the pump 200-d-the pump 200-f. Are provided with on-off valves 360-d to 360-f. The on-off valve 360-d to the on-off valve 360-f open and close the second pipe 364 based on the open / close signal transmitted from the control device 160.

  The pump facility 300 includes an air valve 370-a provided in a communication pipe 372-a that communicates the inside of the pump 200-a with the atmosphere. The air valve 370-a opens and closes the communication pipe 372-a based on an open / close signal transmitted from the control device 160. In the present embodiment, the discharge valve 340, the air inflow valve 350, the on-off valve 360, and the air valve 370 are shown as motorized valves. However, the present invention is not limited to this and may be electromagnetic valves.

  In addition, the pump facility 300 includes a water level gauge 322-a that measures the water level of the river water in the suction water tank 120 and a pressure gauge 324-a that measures the pressure in the discharge pipe 230-a. The water level measured by the water level gauge 322-a and the pressure measured by the pressure gauge 324-a are transmitted to the control device 160. Based on the water level measured by the water level gauge 322-a, the pressure measured by the pressure gauge 324-a, and the like, the control device 160 has a discharge valve 340-a, an air inflow valve 350-a, and an on-off valve 360-a. The opening and closing of the air valve 370-a is controlled. Details of this point will be described later.

  Here, returning to FIG. 2, the description of the pump facility 300 will be continued. As shown in FIG. 2, in the pump equipment 300 of this embodiment, the impellers 202-a to 202-f of the pumps 200-a to 200-f are arranged at different positions in the height direction. Yes. Specifically, the arrangement position increases from the impeller 202-a toward the impeller 202-f. The arrangement height of the impeller 202-f from the impeller 202-f is arbitrary. For example, the arrangement position is 0.5 m to 1.m from the impeller 202-a toward the impeller 202-f. It can be increased by 0 m.

On the other hand, in the pump facility 300 of the present embodiment, the bell mouth 212-a to the bell mouth 212-f serving as the river water suction ports of the pump 200-a to the pump 200-f are respectively positioned at the same height. Has been placed.

  According to the present embodiment, it is possible to suppress the occurrence of water level hunting and to smooth the operation time of the pumps 200-a to 200-f. That is, since the pump 200-a to the pump 200-f are arranged at different positions in the height direction, the impeller 202-a to the impeller 202-f are pumps having a low arrangement position when the water level rises. The drainage operation is performed in order from 200-a. Therefore, it is possible to suppress the occurrence of water level hunting caused by the simultaneous operation of the drainage of all the pumps 200-a to 200-f. Moreover, it is possible to suppress the occurrence of an abnormality in the private power generation facility due to the load fluctuation.

  In addition, the pumps 200-a to 200-f are arranged at positions where the bell mouths 212-a to 212-f are aligned in the height direction (substantially the same position in the height direction). . Therefore, for example, even if the pump (for example, pumps 200-d, e, f) in which the impeller 202 is disposed at a relatively high position, once the drainage operation is started, the air inlet valve 350 is closed. ", The drainage operation can be continued even if the water level drops to some extent. For example, a pump (for example, pump 200-d, e, f) in which the impeller 202 is disposed at a relatively high position is a pump (for example, pump 200-a, pump in which the impeller 202 is disposed in a relatively low position. The drainage operation can be continued until the water level becomes lower than the position of the bell mouth 212 similar to b, c). As a result, for example, when the accumulated operation time of the pumps 200-a, b, and c is long after the pumps 200-a to 200-f sequentially start the drainage operation as the water level rises, the pump 200- By stopping the operation of a, b, and c and continuing the drain operation only with the pumps 200-d, e, and f, the cumulative operation time of the pumps 200-a to 200-f can be smoothed. . In the following description of the embodiments, the intake device 390, the pressure device 380, and the like will be described. However, even if these are not used, the occurrence of water level hunting is suppressed, and the pumps 200-a to 200 are used. Smoothing of the operation time of -f can be achieved.

(Second Embodiment)
As shown in FIG. 2, the pump facility 300 according to the present embodiment further includes an intake device 390 for sucking pump internal air (gas in the pump) and a pressurized air device 380 for pressurizing gas into the pump. .

In the pump facility 300 of the present embodiment, for convenience, in the plurality of pumps 200-a to 200-f, the first system A on the side where the position of the impeller 202 is low and the position of the impeller 202 are high. It is divided into the second system B on the side. Pump 200-a to pump 200-c belong to the first system A, and pump 200-d to pump 200-f belong to the second system B. In addition, the way of classification of the first system A and the second system B of the present embodiment is an example, and can be arbitrarily divided from the viewpoint of the side where the impeller 202 is arranged on the high side and the side where it is low.

  The pumps 200-a to 200-c belonging to the first system A are connected to the pressure device 380 via the first pipe 362. The pressure device 380 pressurizes gas into the pumps 200-a to 200-c belonging to the first system A via the first pipe 362. The pumps 200-d to 200-f belonging to the second system B are connected to the intake device 390 via the second pipe 364. The intake device 390 sucks the pump internal air of the pumps 200-d to 200-f belonging to the second system B via the second pipe 364. For this reason, it is necessary to maintain airtightness in the pump, and it is preferable to inject water into the shaft seal device 332-a shown in FIG.

  Next, the operation process in the pump facility 300 of the second embodiment will be described. FIG. 5 is a diagram illustrating a flow of operation processing in the pump facility of the second embodiment.

  First, the control device 160 determines whether the operation mode of the pump facility 300 is the automatic mode or the manual mode (step S101).

  When the operation mode of the pump facility 300 is the manual mode, the control device 160 performs an operation such as opening / closing of a valve in accordance with a manual operation performed by an operation manager or the like (step S102).

  On the other hand, when the operation mode of the pump facility 300 is the automatic mode, the control device 160 determines whether the operation mode of the pump facility 300 is the normal operation mode or the smooth operation mode (step S103). . The normal operation mode is an operation mode in which a plurality of pumps 200-a to 200-f are started in order from the lower arrangement position of the impellers 202-a to 202-f. The smoothing operation mode is a mode in which a smoothing operation is performed to smooth the cumulative operation time of the plurality of pumps 200-a to 200-f.

  When the operation mode of the pump facility 300 is the normal operation mode, the control device 160 controls the discharge valve 340, the air inflow valve 350, and the air valve 370 to “open”, and the on-off valve 360 to “close”. Control (step S104). Subsequently, the control device 160 performs a preliminary standby operation of the pump (step S105). In addition, this advance standby operation performs the same operation as the conventional advance standby operation. Since the pump 200-a to the pump 200-f are arranged at different positions in the height direction of the impeller, drainage is possible sequentially as the water level rises.

  On the other hand, when the operation mode of the pump facility 300 is the smooth operation mode, the control device 160 determines whether the next operation number is the A system or the B system (step S106). That is, the control device 160 determines whether the pump that performs the drainage operation next is a pump belonging to the first system A or a pump belonging to the second system B.

  When the next operation machine is the A system, the control device 160 performs the normal operation for the shortage machine having the shortest cumulative operation time among the A system pumps, and also performs the normal operation for the B system pump, Of the A-type pumps, pumps other than the shortage machine perform a pressurized air sealing operation (air standby operation) (step S107).

  For example, the control device 160 “closes” the discharge valve 340, “closes” the air inflow valve 350, “opens” the on-off valve 360, and “opens” the air valve 370 for the pumps other than the shortage among the A-system pumps. Under the condition that the water level of the suction water tank 120 is equal to or higher than the lower end of the bell mouth, the pressure device 380 is activated, the pump internal pressure is increased, and the on-off valve 360 is closed when the specified internal pressure is reached. The device 380 is stopped. Thereby, even if the water level of the suction water tank 120 rises, it controls so that a drain operation is not carried out. When the water level in the suction water tank 120 reaches a specified value (timing at which the pump may start), the air inlet valve 350, the air valve 370, and the discharge valve 340 are opened, the water level in the pump is returned, Start driving.

  The process of step S107 will be described with reference to FIG. Drawing 6 is a figure showing an example of the operation processing in the pump equipment of a 2nd embodiment. FIG. 6 shows an example of an operation process in the case where there is a machine with a short operation time (for example, the pump 200-c) among the pumps 200-a to 200-c of the A system (for low water level).

In this case, as shown in FIG. 6, the control device 160 opens and closes the on-off valve 360-a and the on-off valve 360-.
b is set to “open” and the on-off valve 360-c is controlled to be “closed”. Here, an unfilled valve in the figure represents “open”, and a painted valve represents “closed”. Accordingly, the control device 160 supplies compressed air from the pressure device 380 to the pumps 200-a and 200-b. Therefore, for the pump 200-a and the pump 200-b, the water level in the pump does not rise even if the water level of the suction water tank 120 rises. As a result, the pump 200-a and the pump 200-b do not perform the drainage operation but perform the air standby operation in which the pump is operated in the absence of water. The control device 160 controls the on-off valve 360-a and the on-off valve 360-b to be “closed” after the compressed air is supplied by the pressure device 380.

  On the other hand, the control device 160 causes the preceding standby operation, which is a normal operation, to be performed for the pump 200-c. As a result, the pump 200-c is controlled to perform a drain operation (load operation) in conjunction with the water level of the suction water tank 120. In addition, the control apparatus 160 continues drainage operation by performing control which closes the air inflow valve 350-c, when the water level of the suction tank 120 falls and it becomes an airlock water level after drainage operation of the pump 200-c. You can also

  Moreover, since the impeller is higher than the pump 200-c in the B-system pumps 200-d to 200-f, the load operation is not performed earlier than the pump 200-c. Therefore, the control device 160 causes the standby standby operation following the water level to be performed as normal operation control for the pumps 200-d to 200-f.

  As described above, this embodiment causes the pump 200-a and the pump 200-b to perform the air standby operation by press-fitting air into the pump 200-a and the pump 200-b. Therefore, according to the present embodiment, the pump 200-c having the shortest accumulated operation time can be drained before the pumps 200-a and 200-b where the impeller is disposed lower. As a result, the cumulative operation time of the pumps 200-a to 200-f can be smoothed. Moreover, according to this embodiment, it can suppress that the hunting of the water level resulting from all the pump 200-a-pump 200-f performing drainage operation simultaneously generate | occur | produces. Moreover, it can also suppress that the sudden load fluctuation | variation by performing drainage operation all at once raise | generates abnormality in a private power generation equipment.

  On the other hand, returning to the description of FIG. 5, when the next operation machine is the B system, the control device 160 performs a pressurized air sealing operation (in-air standby operation) for the A system pump. Of these pumps, normal operation is performed for those other than the shortage machine with the shortest cumulative operation time, and intake operation (load operation with the water level raised to the impeller) is performed for the shortage machine with the shortest cumulative operation time among the B-series pumps. (Step S108).

  The control device 160 sets the discharge valve 340 to “open”, the air inflow valve 350 to “close”, the on-off valve 360 to “open”, and the air valve 370 for the under-running machine that has the shortest accumulated operation time among the B system pumps. Is controlled to be “closed”, and on the condition that the water level of the suction water tank 120 is equal to or higher than the lower end of the bell mouth 212, the intake device 390 is started, the pump internal pressure is lowered, and the pump internal water level is raised. When the water level in the pump reaches the position of the impeller, the pump starts the drain operation. The intake device 390 and the on-off valve 360 perform a stop / close operation (control) after confirming with the pressure sensor that the drainage operation of the pump has started. In this embodiment, the actual drainage operation of the pump is detected by the pressure sensor, but it is determined whether the load operation (actual drainage operation) is performed with the current value of the electric motor instead of the pressure sensor. You may do it. Further, it may be determined by a level switch such as a tuning fork type.

The process of step S108 will be described with reference to FIG. Drawing 7 is a figure showing an example of the operation processing in the pump equipment of a 2nd embodiment. FIG. 7 shows an example of operation processing in the case where there is a machine with a short operating time (for example, pump 200-e) in the pumps 200-d to 200-f of the B system (for high water level).

  In this case, as shown in FIG. 7, the control device 160 opens the on-off valves 360-a to 360-c. Accordingly, the control device 160 supplies compressed air from the pressure device 380 to the pumps 200-a to 200-c. Therefore, for the pumps 200-a to 200-c, the water level in the pump does not rise even if the water level of the suction water tank 120 rises. As a result, the pumps 200-a to 200-c perform the air standby operation without performing the drain operation.

  On the other hand, as shown in FIG. 7, the control device 160 controls the on-off valve 360-e to “open” and the on-off valves 360-d and 360-f to “close”. As a result, the pump 200-e is sucked by the suction device 390 (vacuum pump), and after the water level in the pump 200-e is raised, the drainage operation (load operation) is performed. The control device 160 causes the preceding standby operation following the water level to be performed as normal operation control for the other B-system pumps 200-d and 200-f. Further, the control device 160 takes in the air by the intake device 390, raises the water level in the pump to the impeller position, and controls the on-off valve 360-e to “close” when the drainage operation is started.

  As described above, in the present embodiment, air is press-fitted into the pumps 200-a to 200-c to cause the pumps 200-a to 200-c to perform a standby operation in the air, and the inside air of the pump 200-e is discharged. Intake air increases the water level in the pump 200-e. Therefore, according to the present embodiment, the pump 200-e having the shortest cumulative operation time can be drained before the pumps 200-a to 200-d where the impeller is disposed lower. As a result, the cumulative operation time of the pumps 200-a to 200-f can be smoothed. Moreover, according to this embodiment, it can suppress that the hunting of the water level resulting from all the pump 200-a-pump 200-f performing drainage operation simultaneously generate | occur | produces. Moreover, it can also suppress that the sudden load fluctuation | variation by performing drainage operation all at once raise | generates abnormality in a private power generation equipment.

  In addition, according to the present embodiment, when the water level of the suction tank suddenly rises like guerrilla heavy rain, the normal operation mode is set, and when no sudden rise of the tank level like small rain is expected, The operating time can be smoothed using the conversion mode. Therefore, appropriate operation and operation according to the weather are possible, and the facility has good operation and maintenance. The mode may be switched arbitrarily by the operator in view of the weather, or the mode may be switched automatically by entering rainfall amount or water level data upstream of the inflow water channel to the pump station into the control device. . For example, when the amount of rainfall is large or when the rate of increase of the water level on the upstream side is high, automatic switching control such as switching to the normal operation mode can be performed.

  Next, the operation process in the smooth operation mode will be described. FIG. 8 is a diagram illustrating a flow of operation processing in the smooth operation mode.

  As shown in FIG. 8, when the smooth operation mode is started, the control device 160 determines whether the operation order is automatic selection or optional selection (step S201). Here, the automatic selection of the operation order is a mode in which the control device 160 calculates in what order the pumps 200-a to 200-f are operated. The optional selection is a mode in which the pump is operated in the order set by the operation manager via the input interface.

  When the operation order is automatic selection, the control device 160 calculates the operation order according to the accumulated operation time of each pump (step S202). This point will be described with reference to FIG. FIG. 9 is a diagram for explaining the cumulative operation time and operation sequence of a plurality of pumps.

  As shown in FIG. 9, for example, the cumulative operation times of the pumps 200-a to 200-f are “2000”, “1800”, “1850”, “1500”, “1600”, and “1000”, respectively. And In this case, the control device 160 calculates the operation order of each pump so that the operation is performed in the order of short accumulated operation time. In the example of FIG. 9, the operation order is determined so that the pump 200-f, the pump 200-d, the pump 200-e, the pump 200-b, the pump 200-c, and the pump 200-a are operated in this order.

  On the other hand, returning to the description of FIG. 8, if the operation order is optional, the control device 160 reads out the operation order input via the input interface (step S203). This point will be described with reference to FIG. FIG. 10 is a diagram illustrating an example of an input interface for setting the operation order of a plurality of pumps.

  As shown in FIG. 10, the manager can set the pumps 200-a to 200-f to operate in any order via the input interface. For example, in the example of FIG. 10, the pump 200-a is the first unit in the operation sequence, the pump 200-f is the second unit, the pump 200-c is the third unit, and the pump 200- The pump 200-b can be set for the d, fifth unit, and the pump 200-e can be set for the sixth unit. Note that, on the arbitrary setting screen for the starting order, the operation order can be set on the surface of the control panel or the like by a push button switch (illumination switch) or the like. Also, as shown in FIG. 10, the operation time and the operation start water level of the pump can be displayed on the same screen as data for setting the operation order. It is also possible to arbitrarily set the operation start water level. Moreover, it can also be comprised with a touch panel etc. instead of a pushbutton switch.

  Returning to the description of FIG. 8, the control device 160 determines whether or not the next operation number has reached the operation start water level after step S202 or step S203 (step S204).

  The control device 160 repeats the process of step S204 until the next operation number reaches the operation start water level (No in step S204). On the other hand, when the next operation number reaches the operation start water level (step S204, Yes), the control device 160 determines whether the next operation number is the A system or the B system (step S205).

  When the next operation unit is the A system, the control device 160 performs the normal operation for the shortage machine having the shortest cumulative operation time among the A system pumps, and performs the normal operation for the B system pump. Among the pumps of the system, pumps other than the under-performing machine are subjected to pressurized air sealing operation (air standby operation) (step S206). Since this point is the same as that of FIG.

  In addition, when the next operation machine is the B system, the control device 160 performs a pressurized air sealing operation (aerial standby operation) for the A system pump, and the shortest cumulative operation time is shortest among the B system pumps. Except for the machine, normal operation is performed, and among the B-type pumps, the under-actuated machine having the shortest accumulated operation time is subjected to the intake operation (load operation with the water level raised to the impeller) (step S207). Since this point is the same as that of FIG.

  According to the present embodiment, in the smooth operation mode, the setting function that can arbitrarily set the start order by the control function for determining the operation order so as to start the operation from the one with the shortest accumulated operation time and the selection button provided on the panel surface or the like. Therefore, the manager can select one according to the operation. In addition, according to the present embodiment, since the operation start order can be arbitrarily set, it is possible to set a malfunctioning machine (an old machine with frequent failures) or the like as a subsequent machine, and reliability is improved. High operation can be achieved.

(Third embodiment)
Next, the pump equipment of 3rd Embodiment is demonstrated. FIG. 11 is a diagram illustrating a schematic configuration of the entire pump facility according to the third embodiment.

  Compared with the second embodiment, the pump facility 400 of the third embodiment is provided with a communication pipe 410 that communicates the first pipe 362 and the second pipe 364, and a switching valve 420 is provided in the communication pipe 410. The point is different. The description of the same configuration as that of the second embodiment is omitted.

  As shown in FIG. 11, the first pipe 362 and the second pipe 364 are connected by a communication pipe 410. The communication pipe 410 is provided with a switching valve 420 that opens and closes the communication pipe 410.

  According to the present embodiment, by controlling the switching valve 420 to “open”, the pressure air by the air pressure device 380 and the air intake by the air intake device 390 are performed on any of the pumps 200-a to 200-f. be able to. For example, when there are a large number of pumps installed and there are pumps at intermediate positions with respect to the water level, such as the pumps 200-c and 200-d, the configuration is such that both pressure air (supply air) and intake air can be used. Thus, the operability and operability of the pump facility 300 can be improved.

  Also, in order to ensure that the drainage pump can be started and operated in an emergency, it is necessary to perform a management operation in an actual operation state (actual load state) and confirm that there is no abnormality in the start and operation state. In this regard, according to the present embodiment, since any of the pumps 200-a to 200-f can perform intake air, even when there is little rainfall and the water level of the suction water tank 120 is low (during management operation), It becomes possible to perform load operation, and it is possible to improve the reliability as pump equipment.

(Fourth embodiment)
Next, the pump equipment of 4th Embodiment is demonstrated. FIG. 12 is a diagram illustrating an overall schematic configuration of the pump facility according to the fourth embodiment.

  Compared with the second and third embodiments, the pump facility 500 of the fourth embodiment is a pipe between a plurality of pumps 200-a to 200-c belonging to the first system A in the first pipe 362. Switching valves 510 and 520 for opening and closing the valves, and switching valves 530 and 540 for opening and closing the piping between the plurality of pumps 200-d to 200-f belonging to the second system B in the second piping 364, respectively. Is different. The description of the same configuration as in the second and third embodiments is omitted.

  As shown in FIG. 12, a switching valve 510 that opens and closes the first pipe 362 is provided between the pump 200-a and the pump 200-b of the first pipe 362. In addition, a switching valve 520 for opening and closing the first pipe 362 is provided between the pump 200-b and the pump 200-c in the first pipe 362.

  Further, a switching valve 530 for opening and closing the second pipe 364 is provided between the pump 200-d and the pump 200-e in the second pipe 364. In addition, a switching valve 540 that opens and closes the second pipe 364 is provided between the pump 200-e and the pump 200-f of the second pipe 364.

According to the present embodiment, by controlling the opening and closing of the switching valves 420, 510, 520, 530, and 540, the pressurized air by the pressure device 380 and the intake air for any of the pumps 200-a to 200-f Inhalation by the device 390 can be performed simultaneously. Also,
Each of the pump 200-a to the pump 200-f may be connected to the pressure device 380 and the intake device 390 by separate pipes. According to the present embodiment, for example, when there are a large number of pumps installed, pressurized air (supply air) and intake air can be simultaneously performed. As a result, the operability and operability of the pump facility 500 can be improved.

  In each of the above-described embodiments, an example in which the pressure device 380 is provided and the pump is forcibly pressurized by using the pressure device 380 to force the pump to perform an air standby operation has been described. However, the present invention is not limited thereto. . For example, in the smoothing operation, the control device 160 closes the discharge valve 340, the air inflow valve 350, the on-off valve 360, and the air valve 370 corresponding to the pump that should be forced to perform the air standby operation. The rise of the water level in the pump can be suppressed. According to this, it is possible to perform control without using the pressure device 380, leading to an improvement in reliability. Also, when the water level of the suction tank 120 under normal conditions is below the bell mouth (the drainage pump station that operates the tank in a dry state, that is, the water remaining in the tank is removed to prevent deterioration of the water quality and the generation of bad odors. In the case of a drainage pump station that is operated in the same manner, it is possible to control the starting order by simply deciding the starting order before inflow and closing each valve of the pump that operates with pressurized air, eliminating the need for a pneumatic device and simplifying the equipment. Can be planned.

160 Control device 200-a to 200-f Pump 202-a to 202-f Impeller 210-a to 210-f Casing 212-a to 212-f Bell mouth 300, 400, 500 Pump equipment 332 Shaft seal device 340 Discharge Valve 350 Air inflow valve 360 On-off valve 362 First piping 364 Second piping 370 Air valve 372 Communication piping 380 Air pressure device 390 Intake device 410 Communication piping 420, 510, 520, 530, 540 Switching valve A First system B Second system

Claims (5)

A pump facility equipped with a plurality of pumps for discharging liquid,
Each of the plurality of pumps includes an inlet for the liquid, and an impeller for pumping the liquid from the inlet.
The impellers of the plurality of pumps are respectively arranged at different positions in the height direction,
The suction ports of the plurality of pumps are each arranged at the same height position ,
An intake device for sucking gas in at least one of the plurality of pumps;
A pressure device for injecting gas into at least one of the plurality of pumps,
The plurality of pumps are divided into a first system having a low arrangement position of the impeller and a second system having a high arrangement position of the impeller,
A first pipe connecting the pump belonging to the first system and the pressure device;
A second pipe connecting the pump belonging to the second system and the intake device,
The pressure device press-fits gas into a pump belonging to the first system via the first pipe,
The intake device sucks the gas in the pump of the pump belonging to the second system via the second pipe,
A communication pipe communicating the first pipe and the second pipe;
A switching valve for opening and closing the communication pipe;
A pump facility characterized by comprising: The pump installation according to claim 1 ,
A switching valve for opening and closing pipes between a plurality of pumps belonging to the first system in the first pipe;
A switching valve for opening and closing pipes between a plurality of pumps belonging to the second system in the second pipe,
A pump facility characterized by comprising: The pump installation according to claim 1 or 2 ,
A control device that switches between the operation of starting the plurality of pumps in order from the side where the impeller is arranged in order from the low side and the smoothing operation for smoothing the cumulative operation time of the plurality of pumps,
In the smoothing operation, the control device is operated in order from a pump having a short cumulative operation time among the plurality of pumps, or is operated in an order set via an input interface. Controlling the pressure by the pressure device or the intake by the intake device;
Pump equipment characterized by that. The pump installation according to claim 1 or 2 ,
A discharge valve for opening and closing a discharge pipe for discharging the liquid, an air inflow valve for opening and closing an air inflow pipe for allowing air to flow into the liquid bell mouth, and the pressure device An on-off valve that opens and closes a pipe connecting the pump, and an air valve that opens and closes a communication pipe that communicates the inside of the pump with the atmosphere;
A control device that switches between the operation of starting the plurality of pumps in order from the side where the impeller is disposed in order, and the smoothing operation for smoothing the cumulative operation time of the plurality of pumps. ,
In the smoothing operation, the control device closes the discharge valve, the air inflow valve, the on-off valve, and the air valve corresponding to at least one of the plurality of pumps, Suppress the rise of the water level in the pump without using a pressure device,
Pump equipment characterized by that.   A pump facility comprising a plurality of pumps for discharging the liquid in the water tank,
  Each of the plurality of pumps includes an inlet for the liquid, and an impeller for pumping the liquid from the inlet.
  The impellers of the plurality of pumps are respectively arranged at different positions in the height direction,
  The suction ports of the plurality of pumps are each arranged at the same height position,
  Each of the plurality of pumps is connected with an air inflow pipe for allowing air to flow between the impeller and the suction port,
  The air inlet pipe is provided with an air inlet valve for opening and closing the air inlet pipe,
  A controller capable of performing a smoothing operation for smoothing the cumulative operation time of the plurality of pumps;
  In the smoothing operation, the control device closes the air inflow valve corresponding to at least one pump pumping the liquid out of the plurality of pumps, so that the water level of the water tank is changed to the pump. The pumping of the liquid by the pump is continued even when the impeller is lower than
  Pump equipment characterized by that.

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