JP2012246826A - Water supply equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide water supply equipment that enables easy detection of failure in a backflow prevention valve, includes a plurality of sets of water supply devices each comprising a backflow prevention valve, a pump, etc., and is configured by coupling the water supply devices in parallel to each other via water distribution pipes.SOLUTION: The water supply equipment 3 includes: water supply devices 15, 25 which comprise backflow prevention valves 11, 21 and motor drive devices 16, 26 for driving motors including pumps 12, 22; and a pump control device 4 for controlling an operation state of the water supply devices via the motor drive devices. Monitor circuits are added to the motor drive devices, so that no special instrument is required for detecting that any of the motors is reversed. As the result, increase in cost of the water supply equipment 3 can be minimized. When the reversal is detected by the detection circuit, all the water supply devices are temporarily completely stopped by an instruction from the pump control device. After than, all the water supply devices are restarted at the same time, to allow temporal restoration operation of the water supply equipment and improve robustness.

Description

  The present invention relates to a water supply facility that includes a plurality of sets of water supply devices including a backflow prevention valve, a pump, and the like, and these water supply devices are connected in parallel to each other via a water distribution pipe.

  FIG. 4 is a schematic conceptual diagram showing a conventional example of this type of water supply equipment. In addition, in this figure, 2 sets of water supply apparatuses are illustrated as said multiple sets of water supply apparatus.

  That is, the water supply equipment 1 includes motor drive devices 13 and 23 that drive motors (12a and 22a) as AC motors (ACM) that form the backflow prevention valves 11 and 21, pumps 12 and 22, and pumps 12 and 22, respectively. The water supply apparatus 10 and 20 which consists of, and the pump control apparatus 2 which controls the operation state of the water supply apparatuses 10 and 20 via the motor drive devices 13 and 23 are shown.

  FIG. 5 is a detailed circuit diagram of the motor drive device 23 shown in FIG. In this figure, 31 is an input contactor, 32 is an inverter formed of a forward conversion circuit and an inverse conversion circuit as shown, and 33 is an output contactor.

  In this motor drive device 23, first, when the input contactor 31 is closed in response to the input command to the input contactor 31 from the pump control device 2, the input voltage is applied to the inverter 32 from the AC power source such as a commercial power source. Based on the operation command from the pump control device 2 to the inverter 32 and the frequency setting corresponding to the starting frequency of the motor 22a, the output of the inverter 32 has an output voltage of a frequency / voltage corresponding to this frequency setting. appear.

  Next, when the output contactor 33 is closed in response to the input command to the output contactor 33 from the pump control device 2, the output voltage is applied to the motor 22a forming the pump 22, and the pump 22 rotates. The frequency and voltage of the output voltage of the inverter 32 increase with the frequency setting thereafter, and when the pump 22 reaches a predetermined rotational speed, the start of the pump 22 is completed. 20 enters a normal water supply state.

  At this time, for example, when an overcurrent, an overload, or the like occurs as the operation state of the inverter 32, this state is transmitted to the pump control device 2 as an abnormal signal. Since the motor drive device 13 has the same configuration as the motor drive device 23, the description thereof is omitted here.

JP-A-8-200222 (FIG. 1 etc.)

  In the conventional water supply facility 1 shown in FIG. 4, it is known that the backflow prevention valves 11 and 21 provided in the water supply apparatuses 10 and 20 are subject to an operation failure due to aging due to repeatedly applied pressure. .

  When the water supply device on the backflow prevention valve side where the operation failure has occurred is stopped, for example, when the water supply device 20 on the backflow prevention valve 21 side in which the operation failure has occurred in FIG. A part of the liquid that should be supplied from the suction port to the discharge port side via the water supply device 10 circulates to the suction port side via the failed backflow prevention valve 21, and as a result, pressure loss and the suction port side. There was a problem of contamination.

  However, since the operation state of the backflow prevention valve cannot be visually inspected from the outside due to its structure, it is necessary to stop the water supply device for maintenance inspection.

  In order to deal with such a problem, for example, what is disclosed in Patent Document 1 is known. However, the solution in Patent Document 1 is a gate valve around each check valve. , It is necessary to additionally install a dedicated device such as a pressure sensor, which increases the cost of the entire water supply facility due to an increase in the number of parts. Furthermore, although Patent Document 1 can detect a failure of the backflow check valve, there is a problem that the operation must be continued with a pressure loss until the failed backflow check valve is replaced. It was.

  The object of the present invention is to solve the above-mentioned problems, detect a failure of the backflow prevention valve without additionally installing a dedicated device, and generate a pressure loss even if a failure occurs in the backflow prevention valve. It is to provide a water supply facility that can be restored without any trouble.

In the first invention, a plurality of water supply devices each including a backflow prevention valve, a pump, and a motor drive device that drives a motor forming the pump, and these water supply devices are connected in parallel via a water distribution pipe, In a water supply facility provided with a pump control device that controls the operating state of each water supply device via each motor drive device,
A failure of the backflow prevention valve is detected by monitoring whether or not the motor of the pump control device stopped by a command from the pump control device is reversely rotated.

2nd invention is the water supply equipment of said 1st invention,
Whether the motor is rotating in reverse is monitored when the stopped water supply device is started.

Moreover, 3rd invention is the water supply equipment of said 1st invention,
Whether the motor is rotating in reverse is monitored at a preset time interval for the water supply apparatus that is stopped.

Moreover, 4th invention is the water supply equipment of the invention in any one of said 1st-3rd,
The reverse rotation of the motor is detected based on the terminal voltage of the primary winding of the motor or the terminal voltage of the primary winding of the motor and the primary winding current.

Furthermore, 5th invention is the water supply equipment of any one of said 1st-4th invention,
When it is detected that the motor forming any of the pumps is rotating in reverse,
In response to a command from the pump control device, the water supply device that was in operation was once completely stopped, and then the water supply device that was in operation and the water supply device that detected the failure of the backflow prevention valve were restarted simultaneously. It is characterized by that.

  According to this invention, in order to detect the malfunction of the backflow prevention valve of the water supply device, no special instrument is required, and as a result, the price increase of the entire water supply facility is suppressed, and the malfunction of the backflow prevention valve is detected. When it is done, by the command from the pump control device, all the water supply devices are temporarily stopped once, and then all the water supply devices are restarted at the same time so that this water supply facility can be temporarily restored. The robustness of the entire water supply facility can be improved.

Typical conceptual block diagram of the water supply equipment which shows the Example of this invention Partial detailed circuit configuration diagram of FIG. Flowchart for explaining the operation of FIG. Schematic conceptual diagram of water supply equipment showing a conventional example Partial detailed circuit configuration diagram of FIG.

  FIG. 1 is a schematic conceptual configuration diagram of a water supply facility showing an embodiment of the present invention. In this diagram, components having the same functions as those of the conventional configuration shown in FIG. 4 are denoted by the same reference numerals. . Furthermore, also in this figure, two sets of water supply apparatuses are illustrated as the plurality of sets of water supply apparatuses.

  That is, the water supply facility 3 shown in FIG. 1 includes water supply devices 15 and 25 in which the motor drive devices 13 and 23 are changed to the motor drive devices 16 and 26 in place of the conventional water supply devices 10 and 20. Further, a pump control device 4 is provided instead of the pump control device 2.

FIG. 2 is a detailed circuit configuration diagram of the motor driving device 26 shown in FIG. In this figure,
Components having the same functions as those of the conventional motor driving device 23 shown in FIG. 5 are denoted by the same reference numerals, and description thereof is omitted here.

  That is, the motor drive device 26 shown in FIG. 2 includes an input contactor 31, an inverter 32, and an output contactor 33, as well as a current detector 34 that detects the primary winding current of the motor 22a (the output current of the inverter 32). A monitoring circuit 35 for detecting reverse rotation of the motor 22a based on the terminal voltage of the primary winding of the motor 22a (output voltage of the inverter 32) or the output of the current detector 34 and the terminal voltage of the primary winding of the motor 22a; Is additionally installed. Since the configuration of the motor driving device 16 is the same as that of the motor driving device 26, the motor driving device 26 will be described below.

  In this motor drive device 26, the normal operation based on the input command to the input contactor 31 from the pump control device 4, the operation command and frequency setting to the inverter 32, and the input command to the output contactor 33 is as described above. This is the same as the motor drive device 23.

  The operation of the monitoring circuit 35 shown in FIG. 2 will be described below with reference to the flowchart shown in FIG.

  First, when the monitoring circuit 35 receives a monitoring command from the pump control device 4 while the water supply device 25 is stopped by a command from the pump control device 4, the terminal voltage of the motor 22a is read (step S1). Whether it is zero or not is confirmed (step S2).

  If the terminal voltage is not zero (step S2, branch Y), it is determined that the motor 22a is a synchronous motor, and the check valve 21 has failed and the motor 22a is rotating in reverse. This is transmitted to the pump controller 4.

  If the read terminal voltage is substantially zero (step S2, branch N), it is recognized that the motor 22a is a synchronous motor and is stopped or the motor 22a is an induction motor. In step S4, the input command to the input contactor 31, the operation command and frequency setting to the inverter 32, and the input command to the output contactor 33 are sequentially issued via the pump control device 4, It waits for an AC voltage having a frequency (approximately several hertz) and a voltage lower than that at the time of startup in the normal phase rotation direction to be applied to the motor 22a (step S5, branch N).

  When the AC voltage is applied to the motor 22a (step S5, branch Y), the applied voltage to the motor 22a and the motor current via the current detector 34 are sequentially read by sampling at a time interval of about 10 milliseconds. (Step S6).

  From the read voltage change and current change of the motor 22a, the phase relationship is grasped. If the motor 22a is in a braking state (step S7, branch Y), the motor 22a is an induction motor, and Since the check valve 21 is broken and it is determined that the motor 22a is rotating in reverse, the process proceeds to step S3, and this is transmitted to the pump control device 4.

  If the motor 22a is in a driving state (step S7, branch N), it is determined that the motor 22a is normal and the backflow prevention valve 21 is normal. It transmits to the control apparatus 4.

  It should be noted that the monitoring circuit 35 may monitor whether or not the motor 22a is reversely rotated when the stopped water supply device is activated, or set in advance. The monitoring circuit 35 may monitor whether or not the motor 22a reverses periodically at time intervals.

  In step S3, when the state signal indicating that the motor 22a is reversely rotated is transmitted from the monitoring circuit 35 to the pump control device 4 while the water supply device 25 is stopped, the pump control device 4 that has received this signal receives the backflow prevention valve 21. Indicates that is malfunctioning. On the other hand, the pump control device 4 that has received the notification that the check valve 21 is out of order temporarily stops all the water supply devices 15 that are currently operating, stops the water supply device 15 that is currently operating, The water supply device 25 in which the backflow prevention valve 21 is detected to be broken together with the water supply device 15 is restarted simultaneously. This makes it possible to perform a temporary restoration operation while maintaining the function as a water supply facility.

  Here, the water supply device 15 in operation is temporarily stopped in order to reliably start the water supply device 25 in which the backflow prevention valve 21 is broken. That is, if the water supply device 15 in operation is not stopped, the water supply device 25 in which the backflow prevention valve 21 is broken may not be able to start normally due to the backflow pressure from the discharge port, and the water supply device 15 in operation is By stopping, the backflow pressure from the discharge port is relaxed, and the water supply device 25 in which the backflow prevention valve 21 is broken is surely started.

  The motor drive circuit 15 has the same function as the monitoring circuit 35 described above. Further, in this embodiment, two sets of water supply devices are illustrated, but three or more sets of water supply devices can be similarly realized by providing a monitoring circuit in each motor drive circuit.

  Therefore, in order to detect that any of the motors 12a and 22a is reversed, no special instrument is required, and as a result, the price of the water supply facility 3 is slightly increased. In response to a command from the pump control device 4, all the water supply devices are temporarily stopped once, and then the water supply device 25 in which the backflow prevention valve 21 is detected to be broken together with the water supply device 15 being operated is restarted simultaneously. In this manner, the water supply facility 3 can be temporarily restored, and the robustness can be improved.

  DESCRIPTION OF SYMBOLS 1,3 ... Water supply equipment, 2,4 ... Pump control apparatus 10, 15, 20, 25 ... Water supply apparatus 11,21 ... Backflow prevention valve, 12, 22 ... Pump, 12a, 22a ... Motor, 13, 16, DESCRIPTION OF SYMBOLS 23,26 ... Motor drive device, 31 ... Input contactor, 31 ... Inverter, 33 ... Output contactor, 34 ... Current detector, 35 ... Monitoring circuit.

Claims (5)

A plurality of water supply devices each including a backflow prevention valve, a pump, and a motor drive device that drives a motor forming the pump, and these water supply devices are connected in parallel via a water distribution pipe, and each of the motor drive devices is In a water supply facility provided with a pump control device that controls the operation state of each water supply device through
A water supply facility characterized by monitoring whether the motor of the pump control device stopped by a command from the pump control device is rotating in reverse and detecting a failure of the backflow prevention valve. In the water supply equipment according to claim 1,
Monitoring of whether the motor is rotating in reverse is performed when starting the stopped water supply apparatus. In the water supply equipment according to claim 1,
Monitoring of whether the motor is rotating in reverse or not is performed at a preset time interval for the water supply apparatus that is stopped. In the water supply equipment according to any one of claims 1 to 3,
The water supply facility characterized in that the reverse rotation of the motor is detected based on the terminal voltage of the primary winding of the motor or the terminal voltage of the primary winding of the motor and the primary winding current. In the water supply equipment according to any one of claims 1 to 4,
When it is detected that the motor forming any of the pumps is rotating in reverse,
In response to a command from the pump control device, the water supply device that was in operation was once completely stopped, and then the water supply device that was in operation and the water supply device that detected the failure of the backflow prevention valve were restarted simultaneously. Water supply equipment characterized by that.

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