JP2019127847A - Pump unit - Google Patents

Abstract

To provide a highly convenient pump unit capable of avoiding the suspension of water supply to the utmost while suppressing ending in protective stop when starting a pump, and also capable of automatically restoring the operating condition to the original when the pump can normally supply water.SOLUTION: A value for a control parameter includes a first control parameter value to be used in starting the pump in first starting conditions for starting the pump when the use of water is started at a water supply destination, and a second control parameter value to be used in starting the pump in second starting conditions for restarting the pump after the protective stop for keeping the pump started in the first starting conditions on standby in a stopped state to protect the pump unit. When predetermined restoring conditions are satisfied after the second starting conditions are satisfied and the pump is determined to be started, a control device changes the value for the control parameter from the second control parameter value to the first control parameter value.SELECTED DRAWING: Figure 16

Description

  The present invention relates to a pump device.

  Conventionally, as a pump device, for example, a water supply device using a variable speed pump described in Patent Document 1 is known. In the water supply system using the conventional variable speed pump, the operating speed of the motor for driving the pump is changed by the inverter device according to the fluctuation of the demand water quantity, and the discharge pressure of the pump is maintained in a constant relationship to continue water supply. It has become.

  Thus, in the water supply apparatus incorporating the inverter device, various protection circuits are incorporated in order to protect the inverter device itself. Since the water is shut off when the inverter device is stopped by the function of the protection circuit, the conventional water supply device is provided with restart means for operating the inverter device again when the inverter device is stopped by the function of the protection circuit. .

Unexamined-Japanese-Patent No. 1-190989

  By the way, in the above conventional water supply apparatus, restart of the inverter apparatus is tried within the range of the number of operation determined as the number of reoperation m, and the value n of the reoperation counter reaches the number of reoperation m If it is determined that it is difficult to restart the inverter device, the pump failure is confirmed, a necessary alarm is issued via the interface circuit, and an emergency call is made to the maintenance manager of the water supply device. It has become.

  In this way, when the cause of the protective stop of the inverter device has been eliminated when the re-operation command is given to the inverter device, the inverter device is operated again, and the inverter device is completely stopped. The probability of being lost can be reduced. However, when the re-operation command is given to the inverter device, if the cause of the protective stop of the inverter device has not been eliminated, the failure of the pump is determined.

  Here, depending on the installation environment and usage of the water supply system, the protective circuit of the inverter system may work due to a transient phenomenon under unstable conditions at the start of the pump. In this case, in the above conventional water supply apparatus, although the pump has a rotational speed of a certain level or more and can be operated normally if it reaches the specified lift, it is determined that the cause of the protection stop is not eliminated and the pump failure is determined. There is a risk of Since the pump device for supplying tap water to a building is a lifeline, it is desirable to avoid the failure of the water by avoiding the determination of the failure due to the transient state at the start of the pump as much as possible.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a highly convenient pump device capable of preventing a stop of protection when the pump is started and avoiding water interruption as much as possible. Another object of the present invention is to provide a pump device capable of automatically returning to the original operating state when the pump can supply water normally.

(1) A pump device according to one aspect of the present invention includes a pump, a motor for driving the pump, an inverter device for supplying power to the motor, and a control device for outputting a control signal of the pump to the inverter device. And, the control device includes a storage unit that stores values of at least one control parameter related to drive control of the motor, and a condition for starting the pump is the water supply destination. After a first start condition for starting the pump when the use of water is started and a protection stop for waiting the pump started under the first start condition as a protection of the pump device in a stop state as protection of the pump device; A second start condition for restarting the pump, and the value of the control parameter is a first control parameter used when starting the pump under the first start condition. The control device includes a meter value and a second control parameter value which is different from the first control parameter value and used when starting the pump under the second start condition, and the control device is configured to perform the second start condition When it is determined that the pump is started and the predetermined return condition is satisfied, the value of the control parameter is changed from the second control parameter value to the first control parameter value.
According to this configuration, after releasing the first start condition for starting the pump when the use of water at the water supply destination is started and the protection stop for waiting the pump in the stop state as protection of the pump device, In the second start condition to restart the pump, the pump starts with the value of the control parameter corresponding to each condition, so that the pump can be prevented from reaching the protection stop, and the pump can recover from the protection stop state The probability increases, and it is possible to avoid water outage as much as possible. Further, when the predetermined return condition is satisfied during the pump operation after the second start condition is satisfied and the pump is started, the control parameter value is changed from the second control parameter value to the first control parameter value. Since the change is made, the values of the various control parameters changed under the second start condition can be automatically returned to the first control parameter values without waiting for the timing when the pump stops.

(2) In the pump device described in (1) above, the control parameters include a torque boost voltage applied to the electric motor at the start of the pump, an overcurrent protection level that is a threshold of an overcurrent trip, and It may include at least one of a soft start time which is an increasing rate of the rotation speed of the electric motor.
In this case, during the pump operation after the second start condition is satisfied and the pump starts, the value of at least one control parameter among the torque boost voltage, the overcurrent protection level, and the soft start time is set to the first value. The second control parameter value can be changed to the first control parameter value.

(3) In the pump device described in the above (1) or (2), the recovery condition is that the pump is operated for a predetermined time or more when the current of the inverter device is below a predetermined current limit level. A condition may be included.
In this case, when the current has been below the predetermined current limit level for a certain period of time during pump operation after the second start condition is satisfied and the pump is started, the control device Therefore, the control parameter value is changed from the second control parameter value to the first control parameter value.

(4) In the pump device described in the above (3), the current limit level may be set to a value equal to or less than an overcurrent protection level which is a threshold value of the overcurrent trip.
For example, when the load on the motor becomes larger than the normal range due to foreign matter caught in the pump, the current flowing through the inverter device increases. If it is below the current protection level, it is determined that the load of the motor is within the normal range, and the control parameter value is changed from the second control parameter value to the first control parameter value.

(5) In the pump device described in the above (3) or (4), the return condition may include a condition in which the amount of water flowing to the pump is equal to or more than the amount of small water.
For example, when the amount of water flowing through the pump is small, it is difficult to determine whether or not pumping can be performed normally even if the current flowing through the inverter device is small and the current is below the current limit level. After confirming the amount of water flowing to the pump, it is determined that the pump has started.

(6) In the pump device described in the above (1) to (5), the control device includes an input unit for inputting the discharge pressure of the pump, and the first start condition is It may be a start condition of a small stop restart where the discharge pressure is reduced from a pressure higher than a predetermined start pressure to the start pressure or less.
In this case, the first start condition is satisfied and the pump is started when the discharge pressure of the pump drops from a pressure higher than a predetermined start pressure to a level lower than the start pressure.

(7) In the pump device described in the above (1) to (6), the control device includes an input unit for inputting the discharge pressure of the pump, and the control device is configured to The minimum value of the discharge pressure after the start of the pump under the start condition is estimated, the first control parameter value is set according to the minimum value, and the first start condition is satisfied. The pump may be started based on the first control parameter value.
In this case, the lowest value of the discharge pressure after the start of the pump under the first start condition is estimated, and the first control parameter value is set according to the lowest value, and then the first control parameter value is set. Since the pump is started on the basis of this, under unstable conditions at the start of the pump, it is possible to suppress the pump from reaching the protection stop, and it is possible to avoid water disconnection as much as possible.

(8) In the pump device described in (1) to (7), the control device includes an input unit for inputting a discharge pressure of the pump, and the second start condition is The start condition of the retry operation may be such that the discharge pressure is equal to or less than a predetermined start pressure after releasing the protection stop for stopping the pump in the stop state as protection of the pump device.
In this case, water failure can be avoided as much as possible by restarting (retrying) the pump whose protection has been stopped under the second start condition.

(9) The pump device according to (1) to (8), wherein the control device counts the number of times the pump is restarted under the second start condition as the number of retries, and the retry The second control parameter value may be changed according to the number of times, and the pump may be started based on the second control parameter value changed according to the number of retries when the second start condition is satisfied. .
In this case, since the second control parameter value is changed according to the number of retries under the second start condition for restarting (retry) the pump whose protection has been stopped, it is possible to suppress the protection stop when the pump is started. , The probability that the pump can recover from the state of protection stop is increased.

(10) In the pump device described in (1) to (9) above, the control device counts the number of times the pump is started under the second start condition as the number of retries, and The interval time from when the protection stop is canceled until the pump is restarted is changed according to the number of retries, and when the second start condition is satisfied, the interval time changed according to the number of retries The pump may be started based on
In this case, the discharge pressure of the pump decreases as the interval time increases, and the starting torque of the motor is reduced. Therefore, changing the interval time according to the number of retries increases the number of retries each time it increases. The probability that the pump can recover from the protection stop state increases.

(11) In the pump device described in the above (1) to (10), the second start condition is a retry in which the discharge pressure is set to be less than the start pressure after releasing the protection stop. Conditions that are less than or equal to the starting pressure may be included.
In this case, since the discharge pressure of the pump is reduced to the retry start pressure or less under the additional condition of the second start condition, it is possible to suppress the protection stop due to the insufficient torque at the start of the pump.

(12) In the pump device described in the above (1) to (11), the control device counts the number of times the pump is started under the second start condition as a retry number, and the retry number Accordingly, the electric motor may be rotated in the direction opposite to the normal rotation direction.
In this case, in the normal rotation direction, the motor is rotated in the direction opposite to the normal rotation direction even if the cause of the abnormality (for example, sticking of the impeller, biting of foreign matter, etc.) is not removed. In some cases, the cause of the abnormality is removed. Thereby, the protection stop of a pump can be suppressed.

(13) The pump apparatus described in the above (1) to (12), wherein the control device is configured to set the first control parameter value to the second start condition when the second start condition is satisfied. The pump may be started based on the second control parameter value changed according to the discharge pressure when the condition is satisfied.
In this case, since the first control parameter value is changed according to the discharge pressure when the second start condition is satisfied, the probability that the pump can recover from the protection stop state increases.

  According to the above aspect of the present invention, it is possible to obtain a highly convenient pump device capable of preventing the water supply from being interrupted as much as possible while suppressing the protection stop at the start of the pump.

It is a front view showing an example of pump device 1 concerning an embodiment of the present invention. It is a longitudinal cross-sectional view which shows an example of the internal structure of the pump casing 30 which concerns on embodiment of this invention. It is a block diagram which shows an example of schematic structure of the pump apparatus 1 which concerns on embodiment of this invention. It is a block diagram showing an example of composition of control unit 4 concerning an embodiment of the present invention. It is a block diagram showing an example of composition of control device 60 concerning an embodiment of the present invention. It is a control flow which shows an example of the automatic control performed by the control apparatus 60 which concerns on embodiment of this invention. 4 is a time chart showing an example of a relationship between a discharge pressure PV of a pump 2 according to an embodiment of the present invention and a voltage applied to an electric motor 3. It is a control flow which shows an example of the pump starting operation | movement performed by the control apparatus 60 which concerns on embodiment of this invention. 4 is a time chart showing an example of a relationship between a discharge pressure PV of a pump 2 according to an embodiment of the present invention, a voltage applied to an electric motor 3, and a current flowing through an inverter device 70. It is a control flow which shows an example of the retry operation | movement performed by the control apparatus 60 which concerns on embodiment of this invention. It is a control flow which shows an example of the process which calculates the torque boost voltage of step S13-1 of FIG. 9A. It is a control flow which shows an example of the retry operation | movement performed by the control apparatus 60 which concerns on the 1st modification of embodiment of this invention. It is a time chart which shows an example of the relation between discharge pressure PV of pump 2 concerning the 2nd modification of an embodiment of the present invention, and the command frequency by inverter control part 60b of control device 60. It is a control flow which shows an example of the retry operation | movement performed by the control apparatus 60 which concerns on the 2nd modification of embodiment of this invention. It is a control flow which shows an example of the process which calculates the interval time of FIG.12A step S33-1. It is a control flow which shows an example of confirmation of the 3rd starting conditions performed by control device 60 concerning the 3rd modification of an embodiment of the present invention. It is a flow which shows the modification of the processing performed from Step S107 (protection stop) of Drawing 5B to Step S109 (retry operation) concerning the 3rd modification of an embodiment of the present invention. It is a time chart which shows an example of the relation between discharge pressure PV of pump 2 concerning the 4th modification of an embodiment of the present invention, and the command frequency from control device 60 to inverter control part 60b. It is a control flow which shows an example of the retry operation | movement performed by the control apparatus 60 which concerns on the 4th modification of embodiment of this invention. It is a control flow which shows an example of the process which calculates the soft start time of FIG.15A step S53-1. It is a control flow which shows an example of the retry operation | movement performed by the control apparatus 60 which concerns on the 4th modification of embodiment of this invention. It is a control flow which shows an example of control parameter initialization performed by the control apparatus 60 which concerns on embodiment of this invention. It is a schematic diagram which shows the 1st usage example of the pump apparatus 1 of this indication. It is a schematic diagram which shows the 2nd usage example of the pump apparatus 1 of this indication. It is a schematic diagram which shows the 3rd usage example of the pump apparatus 1 of this indication.

  Hereinafter, an embodiment of a pump device will be described with reference to the drawings.

FIG. 1 is a front view showing an example of a pump device 1 according to an embodiment of the present invention. FIG. 2 is a longitudinal sectional view showing an example of the internal structure of the pump casing 30 according to the embodiment of the present invention.
As shown in FIG. 1, the pump device 1 includes a pump 2 for pumping water, a motor 3 provided on the back side of the pump 2 and driving the pump 2 (see FIGS. 3 and 4 described later), and A control unit 4 for controlling the operation, a pressure sensor 42 for detecting the discharge pressure of the pump 2 (see FIGS. 2 and 3 described later), and a pressure tank 43 for holding the discharge pressure of the pump 2 (FIG. 3 described later See) and. The pump 2, the electric motor 3, and the control unit 4 are supported by the unit base 5 and are substantially entirely covered by a unit cover 6.

  The pump 2 is a cascade pump that is also referred to as a friction pump, and includes an impeller 20 and a pump casing 30 that forms a pump chamber 31 that houses the impeller 20 as illustrated in FIG. 2. As shown in FIG. 1, a pump casing cover 50 is attached to the front side of the pump casing 30, and the impeller 20 can be accessed when the pump casing cover 50 is removed. As shown in FIG. 2, the impeller 20 is formed in a disk shape having a large number of grooves 21 cut in its peripheral portion, and the peripheral portion makes the water present in the pump chamber 31 approximately one turn. While boosting.

  Although this pump 2 is small in size, a single impeller 20 can obtain a head comparable to several stages of centrifugal pumps, and is suitable for the purpose of small volume high head. Moreover, since the cascade pump has a self-priming property, it is suitable for pumping water and well water stored in a water receiving tank installed at a position lower than the pump 2.

  As shown in FIG. 1, a suction port 7 exposed from the unit cover 6 and a discharge port 8 are provided on the front surface of the pump device 1. The suction port 7 communicates with one end 32a of an internal flow path 32 formed inside the pump casing 30 shown in FIG. 2, and the discharge port 8 communicates with the other end 32b of the internal flow path 32. There is. A pump chamber 31 and a steam / water separation chamber 33 are formed in the internal flow path 32.

  A flow check valve 35 is provided in the suction flow passage 34 from the one end 32 a to the pump chamber 31 in the internal flow passage 32. The flow check valve 35 is provided at a position higher than the pump chamber 31 and fills the inside of the pump chamber 31 to secure a water level necessary for self-priming prior to driving of the pump 2 and at the time of stopping the pump 2 It serves to prevent backflow of water and to always fill the pump chamber 31 with water. That is, the flow check valve 35 closes the suction flow passage 34 by its own weight when the pump 2 is stopped, and is pushed up by water (including air at the start time) rising up the suction flow passage 34 when the pump 2 is driven. And the suction flow path 34 is opened.

  An air-water separation chamber 33 is disposed downstream of the pump chamber 31. A baffle 37 in which the liquid discharged from the pump chamber 31 collides is disposed in the connection channel 36 between the pump chamber 31 and the steam separation chamber 33 in the internal channel 32. A hole 33 a communicating with the pump chamber 31 is formed at the bottom of the air-water separation chamber 33. The hole 33a is for returning the water separated from the air in the steam / water separation chamber 33 to the pump chamber 31 again during the self-priming operation at the start of the pump 2, thereby generating a negative pressure in the pump chamber 31. , Remove the air in the suction flow path 34 and suck up the water.

  Above the air-water separation chamber 33, a priming port 38 is formed. The priming port 38 is closed by a priming faucet 39. The priming faucet 39 is opened in a state where water is not filled in the pump casing 30 at the time of installation of the pump 2 and the like, and is opened before the pump 2 is started. The separation chamber 33 is full of water up to the priming water level 40. The self-priming operation is performed by driving the pump 2 described above, the air in the suction flow path 34 is exhausted, and when the water rises, the self-priming operation is finished, and the air-water separation chamber 33 and the air-water separation chamber 33 After the downstream side is filled with water, the pumping operation is performed by driving the pump 2.

  A pressure sensor 42 is provided in the discharge flow path 41 from the air-water separation chamber 33 to the other end 32 b in the internal flow path 32. The pressure sensor 42 is disposed above the priming water level 40 and detects the pressure (discharge pressure) of the discharge channel 41 filled with water after the self-priming operation is completed.

  In addition, a pressure tank 43 is provided in the discharge flow path 41. The pressure tank 43 has a rubber bladder built in the pressure vessel, and when the pressure in the discharge passage 41 rises, the air outside the bladder is compressed and water is stored in a pressurized state. Also, for example, as the pressure in the discharge flow channel 41 decreases with the use of water, the compressed air expands and pushes out the stored water into the discharge flow channel 41. In this manner, immediately after the pump 2 is started, water can be supplied from the pressure tank 43 to the discharge passage 41 for a while even if the rotational speed is not increased to a sufficient level for water supply.

FIG. 3 is a block diagram illustrating an example of a schematic configuration of the pump device 1 according to the embodiment of the present invention. FIG. 4 is a block diagram showing an example of the configuration of the control unit 4 according to the embodiment of the present invention. FIG. 5A is a block diagram showing an example of the configuration of the control device 60 according to the embodiment of the present invention.
As shown in FIG. 3, the control unit 4 has an inverter device 70 for supplying electric power to the motor 3 and a control device 60 for controlling the operation of the pump 2 by outputting a control signal to the inverter device 70. The commercial power source 100 is connected to the inverter device 70, and the AC power supplied from the commercial power source 100 is converted into AC power having a desired frequency by the inverter device 70 and supplied to the motor 3. The above-described flow check valve 35, as shown in FIG. 3, includes a check valve 35a for preventing backflow of water, and a flow sensor 35b for detecting a decrease in the flow rate of water flowing to the pump 2 (under water amount Qmin or less). And.

  As shown in FIG. 5A, the control device 60 includes an I / O unit 61, a calculation unit 62, and a storage unit 63 (control memory). The I / O unit 61 is connected to various sensors such as the pressure sensor 42, the flow sensor 35b, the voltage sensor 71, the current sensor 72, and the temperature sensors 80, 81, and 82, and is an input unit that inputs detection results of the various sensors. The detection result input by the input unit 61a is output to the calculation unit 62. The I / O unit 61 includes an output unit 61b, and the control device 60 outputs a command signal (for example, the rotational speed of the pump 2) from the calculation unit 62 to the inverter device 70 via the output unit 61b. Further, the I / O unit 61 may include an external output terminal (not shown) that outputs the state of the pump device 1 to the outside using a contact signal or communication, or the user selects that the pump device 1 cannot be operated. Alternatively, it may have a contact input that can be released. The calculation unit 62 of the control device 60 is realized by, for example, a CPU (Central Processing Unit), and various control programs for the pump device 1 are executed. For example, the calculation unit 62 calculates a command signal to be output to the inverter device 70 based on detection results of various sensors input via the I / O unit 61, and sends the command signal to the I / O unit 61. Output. Note that the I / O unit 61 may perform input / output using a contact signal or an analog signal, or may perform input / output using wireless or wired communication.

  The arithmetic unit 62 of the control device 60 executes various control programs stored in the storage unit 63 based on information input from the I / O unit 61 and information in the storage unit 63. As an example of the control program executed by the calculation unit 62, the operation stop of the pump 2 is commanded by the signal of the discharge pressure PV and the under-quantity Qmin of the flow sensor 35b, or the discharge pressure PV is received to set the set pressure PA. The known discharge pressure constant control or the estimated terminal pressure constant control is calculated for the target pressure SV, and the rotational speed of the pump 2 is adjusted so that the current discharge pressure PV becomes the target pressure SV. Control. In addition, the calculation unit 62 obtains information indicating the state of the pump device 1 (discharge pressure, rotation speed, accumulated operation time, accumulated operation number, etc.) and stores it in the storage unit 63. The storage unit 63 includes various memories for storing information of the I / O unit 61, various control programs executed by the operation unit 62, various information used by the operation unit 62, and various information obtained by the operation unit 62. Prepare. The I / O unit 61, the computing unit 62, and the storage unit 63 of the control device 60 described above may be provided in each of the pump control unit 60a and the inverter control unit 60b, or may be used in combination.

  Furthermore, the control device 60 may include an operation panel 64 and a communication unit 65. The driving panel 64 includes a setting unit 64a and a display unit 64b. The setting unit 64a includes, for example, an operation button, a switch, and a touch panel, and the user of the pump device 1 can cancel the operation disabling of the pump device 1 or change the set pressure via the setting unit 64a. Various information stored in the storage unit 63 can be changed. The display unit 64b includes, for example, a 7-segment LED, an indicator lamp, a liquid crystal display, and the like, and the user of the pump device 1 visually recognizes various information of the pump device 1 stored in the storage unit 63 via the display unit 64b. be able to.

  The communication unit 65 communicates with an external device such as the external terminal 66 by any communication method such as wired (RS485, RS232C, USB, etc.) or wireless communication (NFC, Bluetooth (registered trademark), Wi-Fi, etc.). . Examples of information transmitted and received by the communication unit 65 include a control program for controlling the pump device 1, device information of the pump device 1, set value information, maintenance information, history information, abnormality information, operation information, and the like. The operation panel 64 and the communication unit 65 may be provided in each of the pump control unit 60a and the inverter control unit 60b or may be used in combination. Further, the control device 60 may include a plurality of communication units 65. For example, the operation unit 62 and the operation panel 64 may be configured as separate substrates, and the operation panel 64 may include a CPU and a communication unit, and may be connected to the operation unit 62 via the communication unit 65. The calculation unit 62 and the communication unit 65 may be configured by separate substrates.

  The external terminal 66 may be a general-purpose device such as a PDA or a dedicated terminal such as a remote monitor. The external terminal 66 acquires various types of information related to the pump device 1 stored in the storage unit 63 through communication with the communication unit 65 and displays the information on the display operation unit 67. Further, the external terminal 66 transmits, to the communication unit 65, a change request of various information stored in the storage unit 63 of the pump device 1 by the operation of the display operation unit 67 of the user.

  Here, various information stored in the storage unit 63 includes at least information for controlling the pump 2 (stop pressure P1, set pressure PA, target pressure SV, start pressure P0, etc.) and drive control of the electric motor 3 described later. Control parameters related to When the storage unit 63 is provided in each of the pump control unit 60a and the inverter control unit 60b, at least information for controlling the pump 2 is stored as a set value in the storage unit of the pump control unit 60a. The storage unit of the unit 60b may store at least control parameters related to the drive control. The control parameters related to the drive control of the motor 3 include a torque boost voltage, an overcurrent protection level, and a soft start time, which will be described later in detail, and further, maximum frequency, base frequency, acceleration time, deceleration time, The electronic thermal operation level, the number of retries of the electronic thermal, the stall prevention operation level, the inverter rated current value, and the operation start frequency may be included.

  As shown in FIG. 4, the control device 60 includes a pump control unit 60 a and an inverter control unit 60 b. The pump control unit 60a and the inverter control unit 60b may each include the I / O unit 61, the calculation unit 62, the storage unit 63 (control memory), the operation panel 64, and the communication unit 65 described above. Some or all of them may be used in combination. The pump control unit 60a and the inverter control unit 60b may be connected by communication or a signal line, or may share various information via a common storage unit.

  As described above, the signal of the flow sensor 35b and the measured value of the pressure sensor 42 are input to the pump control unit 60a so that the discharge pressure PV of the pump 2 becomes the target pressure SV. The inverter control unit 60b is instructed to start and stop the pump 2 and to issue a target rotational speed. Moreover, it is good to calculate the control parameter relevant to the drive control of the electric motor 3 mentioned later, and to send the said control parameter to the inverter control part 60b. Specifically, inverter control unit 60b starts pump 2 based on control parameters and the like related to drive control of electric motor 3, and furthermore, based on the target rotational speed of pump 2 sent from pump control unit 60a The frequency is calculated, and a PWM signal for minimizing the difference between the command frequency and the actual frequency of the electric motor 3 is generated.

  The inverter device 70 is an inverter circuit that generates an AC voltage based on the PWM signal from the inverter control unit 60b and applies the AC voltage to the motor 3. The converter unit 70a, the DC voltage smoothing circuit 70b, and the inverter unit 70c and a gate driver 70d. The converter unit 70 a includes a rectifier circuit configured by a diode or the like in order to convert a three-phase AC voltage supplied from the commercial power supply 100 into a DC voltage. The DC voltage smoothing circuit 70b includes a capacitor, and smoothes the DC voltage converted by the converter unit 70a.

  The inverter unit 70c has a plurality of power devices such as IGBTs (insulated gate bipolar transistors) and a plurality of diodes connected in parallel to the power devices. The inverter unit 70c has three phases from the DC voltage smoothed by the DC voltage smoothing circuit 70b. It is comprised so that an alternating voltage may be produced | generated. The gate driver 70d generates a gate drive signal for switching operation of each power element of the inverter unit 70c based on the PWM signal from the inverter control unit 60b.

  A voltage sensor 71 and a current sensor 72 arranged on the secondary side of the inverter circuit are connected to the inverter control unit 60b. The measured values of the voltage and current obtained by the voltage sensor 71 and the current sensor 72 are input to the inverter control unit 60b. Inverter control unit 60b estimates the actual rotational speed of motor 3 (and pump 2) from the measured value of the current fed back, and PWM for minimizing the difference between the estimated rotational speed and the target rotational speed. Generate a signal. The voltage sensor 71 and the current sensor 72 may be omitted as long as the control device 60 can predict the voltage and current on the secondary side of the inverter circuit.

  Moreover, although the electric current which flows into the inverter apparatus 70 used by subsequent description shows the electric current of the secondary side of an inverter circuit, it may replace with this and the electric current which flows through the electric motor 3 may be used. In the present embodiment, “Vf control” in which the voltage output from the inverter control unit 60 b to the electric motor 3 and the frequency are in a substantially proportional relationship may be performed. Here, when the output frequency becomes low, the influence of the voltage drop becomes large, and the torque decreases, so that the output voltage is increased in the low frequency region to compensate for it. One of the control parameters whose settings can be changed by input is a torque boost voltage.

  In FIG. 4, temperature sensors 80, 81, and 82 for measuring these temperatures are attached to the pump 2, the electric motor 3, and the inverter device 70, respectively. When the measured value of the temperature of at least one of the temperature sensors 80, 81, 82 reaches a predetermined upper limit, the pump control unit 60a reduces the rotational speed of the pump 2 from that during steady operation or heats the pump. A command may be issued to the inverter control unit 60b to stop as protection.

  The control device 60 described above stops the operation of the pump by automatic control when the pump device 1 is not disabled. Specifically, the control device 60 has a predetermined start condition for starting the pump 2, and when the start condition is satisfied, outputs a control signal to the inverter device 70 to start the pump 2. The operation of the pump 2 is controlled, and the pump 2 is stopped when the stop condition is satisfied.

FIG. 5B is a control flow showing an example of automatic control executed by the control device 60 according to the embodiment of the present invention.
In the control flow of FIG. 5B, the pump 2 is operated after the abnormality is removed after the pump device 1 is installed, or after the inoperability of the pump device 1 is canceled by the user, or the like. It may be started after the discharge pressure PV (see FIG. 6 described later) of the pump 2 reaches a predetermined stop pressure P1 (see FIG. 6 described later). Moreover, when the control flow of FIG. 5B is started, the pump 2 is stopping.

  First, the control device 60 determines whether or not the first start condition is satisfied (step S101). In the following, as an example, the first start condition is a small stop restart where the discharge pressure PV of the pump 2 is reduced from a pressure higher than a predetermined start pressure P0 (see FIG. 6 described later) to less than the start pressure P0. The start condition of the pump 2 is described, but for example, the first start condition may be satisfied when the use of water is started at the water supply destination by opening the faucet of the water supply destination. The control device 60 may receive a signal that the first start condition is satisfied, and may determine that the first start condition is satisfied based on the signal, or that the first start condition is satisfied by operating the operation panel 64. You may judge. The starting pressure P0 may be a set value that can be changed by the user.

  When the first start condition is not satisfied (in the case of “NO” in step S101), control device 60 stands by until the first start condition is satisfied. On the other hand, when the first start condition is satisfied (when step S101 is “YES”), the pump 2 is started as a short stop restart (step S102). Specifically, in the small stop restart in step S102, the control device 60 sets a value of a control parameter related to drive control of the electric motor 3 described later, and starts the pump 2 based on the value of the control parameter. . When the pump 2 is restarted in a short stop, the torque required at the time of starting on the electric motor 3 side varies depending on variations in the performance of the electronic components of the control device 60, the usage status of the pump 2, the installation environment, and the like. Therefore, it is preferable to restart the pump 2 in a short stop by changing a control parameter related to the drive control of the electric motor 3. The control device 60 outputs an operation command to the inverter device 70 between the start and the stop of the pump 2.

  After the pump 2 is started in step S102, when it is determined that the pump 2 performs the pumping operation and the start is normal (in the case of “YES” in step S103), the control device 60 controls the pump 2 by constant discharge pressure control. Are operated (step S104). As an example of the method for controlling the rotational speed of the pump 2 in step S104, the discharge for controlling the pump 2 so that the target pressure SV is set to a predetermined set pressure PA and the discharge pressure PV of the pump 2 is set to the set pressure PA. Constant pressure control, the target pressure SV is calculated so that the pressure at the end of the water supply destination becomes a predetermined set pressure PA, and the pump 2 is controlled so that the discharge pressure PV of the pump 2 becomes the calculated target pressure SV Terminal pressure constant control, current constant control that controls the pump 2 so that the value of the current sensor 72 becomes a predetermined value, pump so that the discharge flow rate of the pump 2 becomes a predetermined value using a flow meter (not shown) The constant flow rate control for controlling 2 and the constant rotation speed control for controlling the pump 2 so that the rotational speed of the motor 3 becomes a predetermined value may be mentioned. In the following description, as an example, it is assumed that the discharge pressure is controlled at step S104 and constant pressure control is performed.

  Next, the control device 60 determines whether or not the flow rate of water flowing through the pump 2 is equal to or less than the excessive water amount (step S105). Specifically, when the amount of use of water decreases at the water supply destination and the flow sensor 35b detects the amount of underflow Qmin or less, the flow rate of water flowing to the pump 2 is below the amount of underflow (YES in step S105) ") I judge. When step S105 is "YES", the small amount of water of the pump 2 whose flow rate of water flowing to the pump 2 is equal to or less than the excessive water amount is stopped (step S106).

  That is, the stop condition of the pump 2 includes a case where the flow rate of water flowing through the pump 2 is less than or equal to the excessive water amount (small water amount stop: step S106). For example, when the amount of water used is reduced at the water supply destination due to the faucet of the water supply destination being closed and the flow sensor 35b detects an excessive water amount Qmin or less (when step S105 is “YES”), the pump 2 Assuming that the stop condition is satisfied, the pump 2 stops.

  Here, stop of the small amount of water in step S106 will be described. In step S106, the control device 60 performs an accumulation operation to control the rotational speed of the pump 2 so that the discharge pressure PV reaches the stop pressure P1 in a predetermined time, and when the discharge pressure PV reaches the stop pressure P1 or more, It is determined that pressure can be accumulated in the pressure tank 43, the pressure accumulation operation is terminated, and the operation of the pump 2 is stopped. The stop pressure P1, which is the target pressure SV at the time of stopping the small amount of water, is a set value that can be changed by the user, and is set to a value higher than the start pressure P0 and the set pressure PA. And after stopping the small amount of water of pump 2 at Step S106, it returns to Step S101.

  Then, when water is used again in the building of the supply destination after the small amount of water is stopped by the pump 2, the discharge pressure PV is lowered to the start pressure P0 or lower, and the first start condition is satisfied (step S101 is " YES ”), a short stop restart that starts the pump 2 is performed (step S102). At the time of a short stop restart, the discharge pressure PV of the pump 2 can be maintained by supplying water with the water stored in the pressure tank 43 until the pump 2 rises to a rotational speed at which water can be supplied. it can. In addition, as a method for detecting the excessive water amount in step S105, other means such as a low load or a deadline lifting height based on the current value of the electric motor 3 may be used without using the detection of the excessive water amount Qmin or less by the flow sensor 35b.

  In step S105, when the flow rate of water flowing to the pump 2 is not equal to or less than the excessive water amount (in the case of "NO" in step S105), the control device 60 assumes that the use of water is continued at the water supply destination, and step S105. It is determined at -1 whether the protection stop condition is met. When the protection stop condition is affirmative (step S105-1 is “YES”), the control device 60 stops protection of the pump 2 (step S107). Specifically, the pump 2 when a current exceeding a predetermined overcurrent protection level flows to the inverter device 70 (overcurrent trip), or when the temperature of the pump 2 exceeds a predetermined value (pump overheat protection). When it is determined that the vehicle has not been able to continue the operation at the prescribed head, a positive determination of the protection stop condition is made. If the protection stop condition is negative (step S105-1 is “NO”), the process returns to step S104 to continue water supply.

  Here, the description returns to step S103. If it is determined at step S103 that the pump 2 can not be started at the time of starting the pump 2 (if step S103 is "NO"), the control device 60 stops the pump 2 as protection stop (step S107). Specifically, the control device 60 determines that the pump 2 cannot be started when the impeller 20 cannot rotate to a rotation speed at which water can be pumped at a predetermined specified head due to some trouble such as overcurrent trip or pump overheat protection. (Step S103 is "NO"), and it transfers to protection stop of step S107.

  In the protection stop of step S107, the pump 2 is put on standby in a stopped state in order to protect each device in the pump device 1 such as the electric motor 3, the inverter device 70, and the pump 2. Specifically, regardless of whether or not the impeller 20 of the pump 2 is rotating, the control device 60 discontinues the operation command and outputs a stop command to the inverter device 70 that has been protected and stopped. The output of the stop command is continued until the release condition is satisfied. In addition, the cancellation condition of protection stop may be predetermined time, and may be based on the fault which resulted in protection stop. For example, if protection is stopped due to an overcurrent trip, protection stop is continued only for a predetermined time, and if protection is stopped due to pump overheat protection, protection is performed until the temperature of pump 2 falls below a predetermined value. The control device 60 stops the pump 2 until it is determined that the cause of the failure has been resolved, such as continuing the stop. Hereinafter, as protection of the pump device 1, an operation in which the control device 60 makes the pump 2 stand by in a stopped state is referred to as “protection stop”.

  When the protection stop is cancelled, for example, when a predetermined time elapses in step S107, next, the control device 60 determines whether the second start condition is satisfied (step S108). Until the second start condition is satisfied ("NO" in step S108), the process returns to step S107 and waits in the state of protection stop (step S107). On the other hand, when the second start condition is satisfied (when step S108 is “YES”), the control device 60 causes a retry operation to restart the pump 2 (step S109). In this way, the pump device 1 can avoid water leakage as much as possible by restarting (retrying operation) the pump 2 that has stopped protection under the second start condition.

  Specifically, the second start condition of step S108 is the start condition of the pump 2 whose discharge pressure PV is equal to or lower than the start pressure P0 after the protection stop of the pump 2 is released. If the discharge pressure PV of the pump 2 is equal to or lower than the predetermined start pressure P0 after canceling the protection stop, the control device 60 satisfies the second start condition (“YES” in step S108). A retry operation to restart is performed (step S109). Although the details will be described later, in the retry operation of step S109, the control device 60 sets the value of the control parameter related to the drive control of the motor 3 in accordance with the number of retries and the discharge pressure PV, etc. A signal for starting the pump 2 is output to the inverter device 70 based on the value of the parameter. Even when the pump 2 is started in the retry operation, the required torque differs on the electric motor 3 side depending on the variation in the performance of the electronic components of the control device 60 and the use condition (environment) of the pump 2. Therefore, if the control parameter is changed and the pump 2 is started, the protection stop of the pump 2 can be suppressed. During the retry operation in step S109, a display indicating that the retry is being performed may be performed on at least one of the operation panel 64 and the external terminal 66.

  Next, the control device 60 determines whether or not the pump 2 has started normally by the retry operation (step S110). Specifically, when the impeller 20 rotates to a rotational speed at which water can be pumped and the pump 2 performs a pumping operation, the control device 60 determines that the pump 2 has started normally ("YES" in step S110). When it is determined that the impeller 20 cannot be rotated to a rotational speed at which pumping can be performed due to some trouble such as overcurrent trip or pump overheat protection, the pump 2 is determined not to start normally ("NO" in step S110). Do. The control device 60 operates the pump 2 (step S104) when it is determined that the pump 2 performs the pumping operation normally at the defined head by the retry operation and starts (when step S110 is "YES").

  On the other hand, when the pump 2 is not started normally due to the retry operation (in the case of "NO" at step S110), the control device 60 determines whether or not the retry is completed (step S111). In the retry operation which will be described in detail later, the number of times the retry operation (step S109) is continuously performed is counted as the number of retries, and when the number of retries reaches a predetermined N times, the end of the retry is determined. If the number of retries is less than N ("NO" in step S111), the control device 60 returns to the protection stop of step S107. If it is determined in step S111 that the retry is completed (the number of retries is N times) (if step S111 is "YES"), the failure of the pump 2 is determined (step S112), and the control flow of FIG. 5B is ended. Here, after the failure determination of the pump 2, the control device 60 may perform failure display on at least one of the operation panel 64 and the external terminal 66. The failure-confirmed pump 2 is preferably disabled until the user presses the reset button or performs a failure reset operation such as restarting the power supply.

  Here, the stop condition of the pump 2 is selected such that the operation is disabled by the user's operation in addition to the condition for stopping the small water amount in step S106 and the protection stop in step S107, and the control device 60 performs the control in FIG. 5B. It is good to include the case that interrupted the flow. That is, even though the pump 2 is in operation during the pressure accumulation operation of the pump 2 during operation (step S104), retry operation (step S109), or small water volume stop (step S106), the user can operate the operation panel 64. Alternatively, when the selection of operation impossible is performed through the I / O unit 61, the control device 60 immediately stops the pump 2 without performing the pressure accumulation operation. And the control apparatus 60 makes the pump 2 stand by in a stop state until cancellation | release of the driving | operation disabled of the pump apparatus 1 by a user is made | formed.

  In the following embodiments and modifications, among the operations of the pump device 1 configured as described above (control method of the pump device 1), specifically, the pump 2 is not operated due to a torque shortage at the start of the electric motor 3. The control flow of the control device 60 for suppressing the stop of the protection (step S107) and avoiding the water break due to the abnormality confirmation in step S112 as much as possible will be described in detail.

  FIG. 6 is a time chart showing an example of the relationship between the discharge pressure PV of the pump 2 and the voltage applied to the motor 3 according to the embodiment of the present invention. In the time chart shown in FIG. 6A, the vertical axis represents pressure, and the horizontal axis represents elapsed time, and shows the change in discharge pressure PV due to elapsed time. In the time chart shown in FIG. 6B, the vertical axis represents voltage and the horizontal axis represents elapsed time, and shows a change in voltage applied to the motor 3 by the control device 60 over time. Moreover, the solid line and the dotted line in FIG. 6 indicate that water is used at the water supply destination at the time of restarting the small stop, the discharge pressure PV is lowered ("YES" in step S101), and the pump 2 is started (step S103 is "YES"), and the change of the discharge pressure PV when water is supplied by pumping operation of the pump (step S104) is shown. FIG. 7 is a control flow showing an example of a pump start operation executed by the control device 60, and is a control flow showing details from steps S101 to S103 of the control flow of FIG. 5B.

  In FIG. 6, when the small amount of water is stopped last time (step S106), the discharge pressure PV of the pump 2 pressurized to the stopping pressure P1 falls from the pressure higher than the starting pressure P0 to the starting pressure P0 or less. An example is shown in which the pump operation (step S104) is reached after the pump 2 is restarted in a short stop (step S102) after the step S101 is “YES”. As shown in FIG. 7, the control device 60 first determines whether or not the discharge pressure PV of the pump 2 is reduced to a pressure level PL0 that is a predetermined threshold, based on the measurement value of the pressure sensor 42. (Step S1). Here, the pressure level PL0 is preferably a pressure value lower than the stop pressure P1 and higher than the starting pressure P0.

  When discharge pressure PV of pump 2 does not decrease to pressure level PL0 (when step S1 is "NO"), control device 60 stands by until discharge pressure PV of pump 2 decreases to pressure level PL0. When the discharge pressure PV of the pump 2 decreases to the pressure level PL0 (when Step S1 is “YES”), the control device 60 starts measuring time ΔT (Step S2). Time ΔT is the time until the discharge pressure PV of the pump 2 decreases from the pressure level PL0 to the starting pressure P0. The control device 60 determines whether the discharge pressure PV of the pump 2 is reduced to the start pressure P0 in the next step S3, and the discharge pressure PV of the pump 2 does not decrease to the start pressure P0. In the case (when step S3 is "NO"), the process returns to step S2 to continue measurement of the time? T, and waits until the discharge pressure PV of the pump 2 decreases to the start pressure P0. That is, steps S1 to S3 are a small water amount stop state that waits until the start condition of the pump 2 is satisfied (step S101 in FIG. 5B is “YES”).

  When the discharge pressure PV of the pump 2 is lowered to the start pressure P0, the first start condition of the pump 2 is satisfied ("YES" in step S3), and step S101 in FIG. 5B changes to "YES". The device 60 estimates the minimum value of the discharge pressure PV after the pump 2 is started (step S4). Then, the pressure level at the start-up discharge pressure PS, which is the lowest value of the estimated discharge pressure PV, is determined (steps S4-1 to S4-2).

  Here, in the example shown by the solid line in FIG. 6, the time ΔT from the timing of “YES” in step S1 until the discharge pressure PV of the pump 2 becomes equal to or lower than the start pressure P0 is ΔT1, and discharge at start is The pressure PS is PS1, and power is supplied to the motor 3 with a delay of ΔT1 from the pressure level PL0. Further, in the example shown by the broken line in FIG. 6, the time ΔT is ΔT2, and the discharge pressure PS at the start is PS2. And if the rotational speed of the impeller 20 rises to the rotational speed which can pump water, the discharge pressure PV will rise from the fall. The discharge pressure PV of the pump 2 at the timing when the discharge pressure PV rises from the lowering is the lowest value of the discharge pressure PV after the pump 2 is started, and is the discharge pressure PS at the start. That is, the lowest value estimated at the timing of step S3 is the discharge pressure PS at the start.

  The start-up discharge pressure PS is estimated based on the inclination at which the discharge pressure PV decreases from the pressure level PL0 to the start pressure P0, which is calculated from the time ΔT and the difference between the pressure level PL0 and the start pressure P0. This inclination depends on the height of the water supply destination, pipe resistance, or the amount of water used. The start-up discharge pressure PS calculated when the first start condition is satisfied is stored in the storage unit 63, and the pump 2 normally supplies water, or a later-described retry operation is completed, and the failure is determined. It is good to be held until you do.

  In the present embodiment, the control device 60 estimates the starting discharge pressure PS based on the slope at which the discharge pressure PV decreases from the pressure level PL0 to the starting pressure P0, but instead of the pressure level PL0. Alternatively, it may be estimated based on a slope that decreases to an arbitrary pressure PZ (PL0> PZ> P0). In that case, the estimation of PS in step S4 does not depend on the condition of step S3 “YES”, and the discharge pressure PV is less than the pressure PZ and the start pressure P0 or more (start pressure P0 ≦ discharge pressure PV ≦ pressure PZ) It is sufficient to implement at the timing of Thus, the start-up discharge pressure PS may be estimated based on the slope at which the discharge pressure PV is reduced under the first start condition.

  Next, the control device 60 sets the torque boost voltage to be applied to the motor 3 at the start of the pump 2 according to the magnitude of the discharge pressure PS at the start of the pump 2 (steps S5-1 to S5-2). . Specifically, if it is determined in step S4-1 that the starting discharge pressure PS is within the range of PL1 (step S4-1 is “YES”), the torque boost voltage is set to V1, and step S4. The starting discharge pressure PS is outside the range of PL1 at -1 (step S4-1 is “NO”), and is within the range of PL2 at step S4-2 (step S4-2 is “YES”). If so, the torque boost voltage is set to V2, which is a value greater than V1. The torque boost voltage is one of the control parameters related to the drive control of the electric motor 3, and the starting torque of the electric motor 3 increases as the torque boost voltage increases. The control device 60 sets the torque boost voltage to a value corresponding to the magnitude of the discharge pressure PS when starting the pump 2.

  As shown by the solid line in FIG. 6, when the discharge pressure PS at the start of the pump 2 is calculated to be within the range of the pressure level PL1, the control device 60 sets the torque boost voltage to V1. Further, as shown by the dotted line in FIG. 6, when the start-time discharge pressure PS of the pump 2 is calculated within the range of the pressure level PL2, which is a pressure value higher than the pressure level PL1, the controller 60 boosts the torque The voltage is set to V2, which is a value greater than V1. The pressure levels PL1 and PL2 may be pressure values equal to or lower than the starting pressure P0 and may be pressure values having a predetermined width.

  Next, the control device 60 restarts the pump 2 in a short stop based on the set torque boost voltage (step S6). In other words, the control device 60 sets the torque boost voltage that is the first control parameter value in accordance with the discharge pressure PV of the pump 2 under the first start condition, and the first start condition is satisfied when the first start condition is satisfied. The pump 2 is started based on the control parameter value. In steps S5-1 to S5-2, the torque boost voltage to be applied to the electric motor 3 when the pump 2 is started is set according to the magnitude of the discharge pressure PS when the pump 2 is started. Starting torque can be obtained. That is, in the example shown in FIG. 6, when the discharge pressure PS at the start of the pump 2 is higher, the rotation of the impeller 20 is less likely to start and a start torque is required. Therefore, when the start pressure discharge pressure PS is PS2 and the torque boost voltage is V1 used at PS1, the torque is temporarily insufficient and a current larger than the allowable current flows, and the control device 60 The torque boost voltage is set to V2 larger than V1 when the discharge pressure PS at the time of start is PS2, because there is a possibility that the protection is stopped by the over current trip protection or the pump overheat protection. Thus, by setting the torque boost voltage to a value corresponding to the magnitude of the discharge pressure PS at the start of the pump 2 and restarting the pump 2 for a short stop, the pump 2 due to a transient torque shortage at the start Stop the protection of the

  Further, when the torque boost voltage is increased, the current flowing to the inverter device 70 also increases when the pump 2 is started. Therefore, the overcurrent protection level may be set according to the torque boost voltage. Specifically, the controller 60 may set the overcurrent protection level proportional to the torque boost voltage. Thereby, the protection stop by the overcurrent trip of the pump 2 started on 1st start conditions can be suppressed.

  As described above, according to the embodiment described above, the pump 2, the motor 3 for driving the pump 2, the inverter device 70 for supplying power to the motor 3, and the control device for outputting the control signal of the pump 2 to the inverter device 70 60. The control device 60 is an input unit 61a for inputting the discharge pressure PV of the pump 2 and a storage unit 63 for storing values of control parameters related to drive control of the motor 3. The control device 60 has, as a condition for starting the pump 2, a first start condition in which the discharge pressure PV is reduced from a pressure higher than a predetermined start pressure P0 to a value equal to or lower than the start pressure P0. At the same time, the starting discharge pressure PS, which is the minimum value of the discharge pressure PV after the pump 2 is started under the first starting condition, is estimated, and the control performance is controlled according to the starting discharge pressure PS. The pump 2 is configured by setting a torque boost voltage which is one of the values of the meter, and starting the pump 2 based on the set torque boost voltage when the first start condition is satisfied. Thus, it is possible to obtain a highly convenient pump device 1 capable of eliminating torque shortage that occurs transiently at the time of starting, and preventing the protection stop at the time of starting the pump 2 and avoiding water interruption as much as possible.

  In FIG. 6, the torque boost voltage V1 is set to a value smaller than V2 when the discharge pressure PS1 at the start is a value smaller than the discharge pressure PS2 at the start, but regardless of this, the discharge at the start The torque boost voltage may be determined according to the pressure PS. Depending on the installation environment of the pump device 1 and the state of the load, the start-up discharge pressure PS1 is smaller than the discharge-out pressure PS2 at the start-up, but the start-up is performed by setting V1 to a value greater than V2. Sometimes it is possible to avoid protection stoppages.

  Therefore, at least one function for calculating an appropriate torque boost voltage from the discharge pressure PS at startup may be stored in the storage unit 63 as a program executed by the calculation unit 62. Further, which function to use among a plurality of functions may be stored in the storage unit 63 as a changeable setting value. For example, at least one of addition, subtraction, multiplication, and division is performed using the set argument according to the discharge pressure at startup using the argument that can be changed in setting, and the torque boost voltage set at start is determined May be.

  Here, the graph shown by the solid line in FIG. 6 is, for example, a case where a flush valve or the like is installed at the water supply destination and a large amount of water is used at the time of a short stop restart, and the discharge pressure PV shown by the dotted line is It can be considered that a change in discharge pressure PV is shown when the amount of water is small compared to the solid line (a faucet or the like is connected to a water supply destination). The graph shown by the solid line in FIG. 6 is a graph in the case where a large amount of water is used at the time of the small stop restart, and the discharge pressure PV shown by the dotted line is the discharge pressure PV when the amount of water is smaller than the solid line. Showing change. In the graph shown by the solid line, since a large amount of water is used at the time of a short stop restart, the pump 2 is started and discharged in step S6, and there is a case where the torque becomes insufficient until the pressure PV reaches the vicinity of the target pressure SV. Conceivable.

  Specifically, even if the electric motor 3 obtains an appropriate starting torque at the torque boost voltage V1 and the impeller 20 rotates once, if the torque of the electric motor 3 is insufficient due to the acceleration of the electric motor 3 thereafter, the impeller 20 of the pump 2 Will stop protection before it reaches the speed at which it can pump water. That is, depending on the environment in which the pump device 1 is installed, the performance of the pump 2, the output and efficiency of the electric motor 3, etc., when the discharge pressure PS at the start of the pump 2 is low, the torque is transiently insufficient at the start. Thus, the pump 2 may stop protection.

  In such an environment, assuming that the torque boost voltage when the start-up discharge pressure PS is estimated to be, for example, PL1 is, for example, V11, and the start-up discharge pressure PS is estimated to be PL2, which is a value larger than, for example, PL1. For example, the torque boost voltage of V12 may be V12, and a value greater than V12 may be V11. Since the inverter control unit 60b performs “Vf control”, the electric motor 3 can prevent torque shortage after the impeller 20 has once rotated by increasing the torque boost voltage V11. In this way, by setting the value in accordance with the magnitude of the discharge pressure PS at the time of starting, the protection stop of the pump 2 due to the transient torque shortage at the time of starting is suppressed, and the rotation speed at which water can be pumped at a predetermined specified head is achieved. It is possible to increase the rotational speed of the impeller 20.

  As described above, by estimating the discharge pressure PS at the time of start based on the inclination at which the discharge pressure PV has decreased to the start pressure P0, it is possible to estimate the torque necessary for the motor 3 after the start of the pump 2 The value of the control parameter according to the torque required for the electric motor 3 after the pump 2 is started can be set.

  Note that step S6 corresponds to step S102 in FIG. 5B, and after the control flow in FIG. 7 ends, the control device 60 executes step S103 in FIG. 5B. As described in the present embodiment, by setting the torque boost voltage V11 to a value corresponding to the magnitude of the discharge pressure PS at startup, suppression of protection stop of the pump 2 due to transient torque shortage at startup can be suppressed. Can do.

  FIG. 8 is a time chart showing an example of the relationship between the discharge pressure of the pump 2 according to the embodiment of the present invention, the voltage applied to the motor 3, and the current flowing through the inverter device 70. In the time chart shown in FIG. 8A, the vertical axis represents the pressure value, and the horizontal axis represents the elapsed time, which shows the change of the discharge pressure PV with the passage of time. In the time chart shown in FIG. 8B, the vertical axis represents voltage, and the horizontal axis represents elapsed time, and shows changes in voltage applied to the motor 3 by the control device 60 according to the elapsed time. In the time chart shown in FIG. 8C, the vertical axis represents the current value, and the horizontal axis represents the elapsed time, and shows the change in the current flowing through the inverter device 70 due to the elapsed time. FIG. 9A is a control flow illustrating an example of a retry operation executed by the control device 60 according to the embodiment of the present invention, and details of the retry operation in step S109 in the control flow of FIG. 5B.

  In FIG. 8, in the embodiment described above, the discharge pressure PV of the pump 2 falls from the stop pressure P1 to the start pressure P0 or less (“YES” in step S101 of FIG. 5B) to start the pump 2 (FIG. 5B) When trying to perform step S102), the rotational speed of the impeller 20 cannot be increased to a rotational speed at which water can be pumped at a predetermined specified head due to insufficient torque at the time of starting, etc. (step S103 in FIG. 5B is “NO”). 2 illustrates a case where the protection is stopped (step S107 in FIG. 5B), and then a retry operation (step S109 in FIG. 5B) for restarting the pump 2 is performed.

  Specifically, the control device 60 causes the electric motor 3 to supply power at the torque boost voltage VL0 at the timing when the discharge pressure PV of the pump 2 becomes equal to or less than the start pressure P0 (tr1; “YES” in step S101 of FIG. 5B). Although supplied, the impeller 20 of the pump 2 cannot rotate normally, and the current flowing through the inverter device 70 reaches the overcurrent protection level AL0 (protection level) (tr2, step S103 in FIG. 5B is “NO”). Therefore, the protection of the pump 2 was stopped during the overcurrent trip between tr2 and tr3 (step S107 in FIG. 5B). Thereafter, after releasing the protection stop of the pump 2 (tr3), the control device 60 satisfies the second starting condition in which the discharge pressure PV of the pump 2 is equal to or lower than the starting pressure P0 (step S108 in FIG. 5B is “YES”. And the retry operation (step S109 in FIG. 5B) for restarting the pump 2 was performed. As a result, in the first retry operation (tr3 to tr4), the impeller 20 of the pump 2 can not rotate normally again, and the current flowing to the inverter device 70 reaches the overcurrent protection level AL1 (protection level) ( tr4, step S110 in FIG. 5B is “NO”. In an overcurrent trip, the pump 2 is stopped for protection from tr4 to tr5 (step S107 in FIG. 5B), but the second retry operation (tr5, FIG. 5B). In step S109), the pump 2 is normally started (tr6, step S110 in FIG. 5B is "YES") and water can be supplied at the set pressure PA which is the prescribed lift (tr7, step S104 in FIG. 5B) Illustrated.

  As shown in the time charts of FIGS. 8B and 8C, the control device 60 performs torque boost voltage and / or over-current protection according to the number of consecutive retry operations (step S109 of FIG. 5B). Increase the level. Specifically, as shown in FIG. 8B, when the number of retries is 0 (tr1), that is, when the stop is restarted, the torque boost voltage is VL0 that is a reference value. This VL0 is a torque boost voltage (for example, V1 or V2) applied to the electric motor 3 at the time of the small stop start of the pump 2 according to the magnitude of the discharge pressure PS at the start of the pump 2 in the embodiment described above. Good. When the number of retries is the first (tr3), the control device 60 sets the torque boost voltage to VL1 larger than VL0. Further, when the number of retries is the second time (tr5), the control device 60 sets the torque boost voltage to VL2 larger than VL1. Depending on the number of retries, VL1 and VL2 may be obtained by adding or multiplying VL0 by a predetermined value. By increasing the torque boost voltage every time the number of retries increases, protection stop due to insufficient torque of the pump 2 started under the second start condition can be suppressed, and further water cutoff due to abnormality confirmation can be avoided as much as possible.

  Further, as shown in the time chart of FIG. 8C, the overcurrent protection level is increased in order to cope with the torque boost voltage that increases every time the retry operation is performed. Specifically, control device 60 sets overcurrent protection levels AL0, AL1, and AL2 (AL0 <AL1 <AL2) corresponding to torque boost voltages VL0, VL1, and VL2 (VL0 <VL1 <VL2), respectively. . When the torque boost voltage is increased, the current flowing through the inverter device 70 at the start of the pump 2 also increases. Therefore, by setting an overcurrent protection level corresponding to the torque boost voltage, the pump 2 started under the second start condition It is possible to suppress the protection stop due to the overcurrent trip, and to avoid the water stoppage due to the abnormality confirmation as much as possible. Further, the overcurrent protection levels AL0, AL1, and AL2 (AL0 <AL1 <AL2) may be set according to the number of retries without depending on the torque boost voltage.

  Next, the retry operation (step S109 in FIG. 5B) in FIG. 8 will be described in detail with reference to FIG. 9A. Specifically, in the control flow of the retry operation shown in FIG. 9A, the retry operation of tr3 to tr4 and tr5 to tr6 in the example shown in FIG. 8 will be described in detail. The retry operation shown in FIG. 9A satisfies the second start condition in which the discharge pressure PV of the pump 2 is equal to or lower than the start pressure P0 (tr3, tr5) after releasing the protection stop of the pump 2 (step S107 in FIG. 5B). This is executed when step S108 in FIG. 5B is “YES”). In the retry operation shown in FIG. 8, the control device 60 first counts the number of retries (step S11). The number of retries is the number of times the protection stop (step S107 in FIG. 5B) occurs continuously and the retry operation is performed, and for example, the small stop restart of the pump 2 (step S102 in FIG. 5B) (Step S110 in FIG. 5B) and resetting may be performed by powering off the pump device 1 or the like.

  The control device 60 determines the current number of retries (steps S12-1 to S12-N). Then, the control device 60 sets a torque boost voltage to be applied to the motor 3 at the time of starting the pump 2 according to the current number of retries (steps S13-1 to S13-N). Specifically, if the number of retries is the first ("YES" in step S12-1), the torque boost voltage is set to VL1 which is a value larger than the reference value VL0 (step S13-1). If the number of retries is the second time (step S12-2 is “YES”), VL2 that is larger than the VL1 set to the first time in step S13-1 is set (step S13-2). . Alternatively, the torque boost voltage may be increased only once every several retries. The torque boost voltage is one of the control parameters related to the drive control of the motor 3 as described above, and the larger the torque boost voltage, the larger the start torque of the motor 3. Therefore, by increasing the torque boost voltage according to the number of retries, it is possible to suppress the protection stop due to the lack of torque.

  Next, the control device 60 increases the overcurrent protection level according to the number of retries (steps S14-1 to S14-N). For example, as shown in FIG. 8, in the case where the number of retries is zero, that is, the small stop restart (tr1, step S102 in FIG. 5B), the overcurrent protection level is the reference value AL0. When the number of retries is the first time (tr3, Step S12-1 in FIG. 9A is “YES”), control device 60 sets the overcurrent protection level to AL1 larger than AL0 (Step S14-1). Further, when the number of retries is the second time (tr5, "YES" in step S12-2 in FIG. 9A), the control device 60 sets the overcurrent protection level to AL2 larger than AL1 (step S14-2). AL1 and AL2 may be obtained by adding or multiplying AL0 by a predetermined value.

  Next, as a retry execution, the control device 60 starts the pump 2 using the set torque boost voltage value and overcurrent protection level value (step S15). Specifically, the control device 60 outputs an operation signal for starting the pump 2 to the inverter device 70 with the set torque boost voltage. Next, in step S16, if the control device 60 determines that the pump 2 is started and pumps water at the specified head and supplies water normally (step S16 is “YES”), the pump 2 is normally started as shown in FIG. 9A. End the control flow.

  On the other hand, before judging water supply by pumping operation at the prescribed head of the pump 2 in step S16, if it is judged that normal start is negative due to over-current trip, pump overheat protection, etc. (step S16 is "NO") In the case where the control device 60 checks the number of retries (step S18), and if the number of retries is less than the predetermined N (if step S18 is “NO”), the control flow of FIG. 9A ends. . If the number of retries is N or more (when step S18 is “YES”), the end of the retry is confirmed (step S100), and the control flow of FIG. 9A is ended. After the completion of the retry in step S100 is confirmed, the normal start is determined as “NO” in step S110 of FIG. 5B, and further, the retry end is determined as “YES” in step S111. The failure of is fixed. Note that N, which is the number of retries until the failure of the pump 2 is confirmed, is, for example, about N = 5, and may be a setting value that can be changed by the user.

  Here, in steps S13-1 to S13-N, the torque boost voltage is set higher as shown in FIG. 8 in accordance with the number of retries, so that the starting torque increases as the number of retries increases. Further, as the number of retries increases, time passes, so the discharge pressure PV decreases. In the case shown in FIG. 8, the pump 2 could not be restored due to insufficient starting torque in the first retry operation, but in the second retry operation, the torque boost voltage VL2 higher than the torque boost voltage VL1 in the first retry operation. Is set, and the discharge pressure PV is lower than PV1, so that the current flowing to the inverter device 70 reaches the set overcurrent protection level to restore the water supplied by the pump 2 without stopping the protection. Is done. Thus, by increasing the torque boost voltage and / or the overcurrent protection level according to the number of retries, there is a probability that the pump 2 can be normally started by the retry execution in step S15 each time the number of retries increases. It is possible to suppress the protection stop of the pump started under the second start condition, and to avoid the water cut due to the abnormality confirmation as much as possible. In this embodiment, as the number of retries increases, the torque boost voltage is set higher and the overcurrent protection level is raised. However, even if only one of the torque boost voltage or the overcurrent protection level is raised, Good.

  In addition, as shown in FIG. 9A, the control device 60 reverses the pump 2 in the normal rotation direction only once in some of the number of retries (for example, the number of retries is 3 × m: m is a natural number). (Step S17). That is, in the normal rotation direction, even if the cause of the abnormality (for example, the impeller 20 is stuck or the foreign object is caught) is not removed, the pump 2 (electric motor 3) is reverse to the normal rotation direction. In some cases, the cause of the abnormality is removed and the normal start can be performed by rotating the), and the step S16 may be "YES". Thereby, it can suppress that the pump 2 reaches protection stop (step S107 of FIG. 5B) and failure confirmation (S112 of FIG. 5B). When the pump 2 is reversely rotated in step S17, the torque boost voltage may be a value corresponding to the number of retries as described above, or a value preset for reverse rotation may be used. Good.

  Thus, according to the above-described form, the control device 60 cancels the protection stop (step S107 in FIG. 5B) that causes the pump 2 to stand by in the stopped state as the protection of the pump device 1 as a condition for starting the pump 2. After that, the controller 60 has a second starting condition (step S108 in FIG. 5B is “YES”) in which the discharge pressure PV is equal to or lower than the starting pressure P0. The number of times the pump 2 is started is counted as the number of retries (step S11), and one of the values of the control parameter set according to the magnitude of the start discharge pressure PS which is the lowest value under the first start condition The torque boost voltage is changed according to the number of retries, and the pump 2 is changed based on the torque boost voltage changed according to the number of retries when the second start condition is satisfied. To start, by adopting the configuration that suppresses the protective stop or failure determination of the pump 2, as much as possible the pump device 1 highly convenient that can be avoided obtain a suspension of water supply.

  Here, an example of a method for calculating the torque boost voltage in steps S13-1 to S13-N in FIG. 9A will be described with reference to FIG. 9B. The control flow shown in FIG. 9B shows an example of the process of calculating the torque boost voltage in step S13-1 of FIG. 9A. Note that similar processing is performed in steps S13-2 to S13-N in FIG. 9A.

  The storage unit 63 of the control device 60 has the coefficients PL1V and PL2V for changing the torque boost voltage according to the number of retries, and corrects the coefficients PL1V and PL2V according to the magnitude of the discharge pressure PS at startup. It is also good. It is assumed that the discharge pressure PS at the time of start is estimated (step S4 in FIG. 7) when the first start condition is satisfied, and the value is stored in the storage unit 63.

  As shown in FIG. 9B, first, the control device 60 determines the pressure level at the start-up discharge pressure PS when the first start condition is satisfied (steps S13-1-1 to S13-1-2). . Here, the pressure level PL1 shown in step S13-1-1 and the pressure level PL2 shown in step S13-1-2 in this embodiment are the same as the pressure level PL1 and pressure level PL2 shown in FIG. However, the present invention is not limited to this, and may have any range or value. However, it is assumed that PL2 is higher than PL1.

  Next, in step S13-1-3, if the pressure level at the discharge pressure PS at the start is within the range of PL1, the control device 60 determines that the pressure level at the discharge pressure PS at the start is within the range of PL2. If it is, in step S13-1-4, the torque boost voltage VL1 applied to the motor 3 at the time of the first start of the retry is calculated.

  Here, after releasing the protection stop of the pump 2 (step S107 of FIG. 5B), the control device 60 discharge pressure PV when the second start condition is satisfied (“YES” of step S108 of FIG. 5B). Accordingly, a torque boost voltage (control parameter) to be applied when starting the pump 2 may be set. Specifically, since the discharge pressure PV at the time of making the determination in step S12-1 is PV1 (see FIG. 8A), in step S13-1-3, the control device 60 discharges the discharge pressure PV. Torque boost voltage VL1B corresponding to (PV1) is set. At this time, the torque boost voltage VL1B may be increased in proportion to the difference between the starting pressure P0 and the discharge pressure PV (PV1). Similarly, in steps S12-2 to S12-N, torque boost voltages VL2B to VLNB corresponding to the discharge pressure PV when performing the determinations in steps S12-2 to S12-N may be set. As a result, VL0 <VL1B <VL2B <... <VLNB. Since the discharge pressure PV (PV1, PV2,..., PVN) at the time of performing the determination in steps S12-1 to S12-N varies depending on the supply destination, the installation site, etc., the control device 60 determines that the torque boost voltage VL1B is It may be calculated by adding or multiplying a predetermined value according to the discharge pressure PV (PV1, PV2,..., PVN) to VL0, or a predetermined value according to the number of retries in addition to the discharge pressure PV The torque boost voltage VL1B may be calculated by adding or multiplying VL0.

  Next, the control device 60 corrects the coefficients PL1V and PL2V for changing the torque boost voltage according to the number of retries according to the magnitude of the discharge pressure PS at the start (steps S13-1-3 to S13-1). -4). Specifically, if the pressure level in the discharge pressure PS at start-up is within the range of PL1 in step S13-1-1 ("YES" in step S13-1-1), step S13-1-3 is performed. Run. PL1V shown in step S13-1-3 is a coefficient for calculating VL1, and is calculated according to the size of the discharge pressure PS at start-up and the pressure level PL1 when the first start-up condition is satisfied. Good. In step S13-1-3, the coefficient PL1V is added to the torque boost voltage VL1B (base value of VL1 in FIG. 9A) set according to the number of retries and the discharge pressure PV. The coefficient PL1V may be multiplied by VL1B.

  In addition, if the pressure level at the start-up discharge pressure PS is within the range of PL2 in step S13-1-2 (step S13-1-1 is "NO" and step S13-1-2 is "YES"). , Step S13-1-4. PL2V shown in step S13-1-4 is a coefficient for calculating VL1, and is calculated according to the magnitude of discharge pressure PS at start-up and pressure level PL2 when the first start-up condition is satisfied. Good. In step S13-1-4, control device 60 calculates VL1 by adding coefficient PL2V to VL1B, which is a torque boost voltage set according to the number of retries. In step S13-1-4, the coefficient PL2V may be multiplied by VL1B. Thereby, the torque boost voltage VL1 set in step S13-1 can be set to a larger value in the case of PL2, which is a higher value than in the case where the starting discharge pressure PS is PL1.

  Note that the coefficient PL1V and the coefficient PL2V may use different calculation formulas, or may be larger as the number of retries increases. The VL1B and the coefficients PL1V and PL2V may be constant values. As described above, the rotation of the impeller 20 is less likely to start when the discharge pressure PV is high when the pump 2 is started. When torque is required, the torque boost voltage at the time of PL2 may be increased rather than the discharge pressure PS at the time of start at PL1. Specifically, VL1 to VLN when starting discharge pressure PS is PL2 are larger than VL1 to VLN when starting discharge pressure PS is PL1 (VLN is a torque boost voltage at the N-th retry). The coefficients PL1V and PL2V may be used as values.

  As described above, the coefficients PL1V and PL2V for changing the value of the torque boost, which is the control parameter, according to the number of retries are calculated based on the magnitude of the start-up discharge pressure PS estimated when the first start condition is satisfied. It is good to correct accordingly. In addition, although the two methods of calculating the discharge pressure PS at start-up in the present embodiment, the pressure level PL1 and the pressure level PL2 have been shown, the pressure level is X (X is an arbitrary natural number of 1 or more) regardless of this. And PL1V to PLXV may be calculated as coefficients corresponding to the pressure levels PL1 to PLX.

Further, in the present embodiment, the following first modification may be employed.
FIG. 10 is a control flow showing an example of a retry operation executed by the control device 60 according to the first modification of the embodiment of the present invention.
The control flow shown in FIG. 10 expands steps S4-1 to S4-2 shown in FIG. 7 of the above-described embodiment to steps S24-1 to S24-X, and steps S5-1 to S5-2 include steps It is replaced with S25-1 to S25-X. In FIG. 6, “X” in step S24-X and step S25-X represents a pressure range below starting pressure P0 divided into two stages of pressure levels PL1 and PL2 in FIG. A natural number of X) means X stage when divided into stages. Steps S1, S2, S3, S4-1 to S4-2, S6 shown in FIG. 7 and steps S21, S22, S23, steps S24-1 to S24-X, S26 shown in FIG. 10 are the same processing. Therefore, the description is omitted.

  In steps S25-1 to S25-X, the control device 60 sets a soft start time, which is an increase rate of the rotation speed of the electric motor 3, in accordance with the magnitude of the discharge pressure PS at the start of the pump 2. The soft start time is one of the control parameters related to the drive control of the motor 3. When the control device 60 of this embodiment accelerates the motor 3, the rotational speed of the motor 3 is calculated based on the soft start time. Limit the increase in The soft start time may be, for example, a time when the rotational speed of the motor 3 reaches a predetermined rotational speed (for example, maximum output rotational speed) from a value of zero. As the soft start time is longer, the acceleration of the motor 3 can be suppressed, and the current flowing to the inverter device 70 at the time of acceleration can be suppressed. The control device 60 sets the soft start time to a value according to the magnitude of the discharge pressure PS at the start.

  For example, as shown by the solid line in FIG. 6A, the control device 60 sets the soft start time to ST1 when the discharge pressure PS at start-up of the pump 2 is calculated as the pressure level PL1. Further, as shown by the solid line in FIG. 6A, the control device 60 calculates the pressure level PL2 which is a pressure value higher than the pressure level PL1 when the discharge pressure PS of the pump 2 is started. Control device 60 sets the soft start time to ST2, which is longer than ST1. As described above, setting the soft start time according to the magnitude of the discharge pressure PS at the start of the pump 2 prevents the current flowing to the inverter device 70 from reaching the over-current protection level at the start of the pump 2 As a result, it is possible to prevent the pump 2 from stopping protection before reaching the predetermined specified head.

  Here, when the starting discharge pressure PS is PL1 smaller than PL2, the soft start time ST1 is set to a value smaller than ST2. However, regardless of this, similarly to the torque boost voltage V1 or V2 described above. The soft start time may be determined according to the discharge pressure at the time of start, such as setting the soft start time ST1 to a value of ST2 or more according to the installation environment or the like.

  Note that the control flow shown in FIG. 10 and the control flow shown in FIG. 7 may be executed in parallel. The control flow shown in FIG. 10 extends steps S4-1 to S4-2 shown in FIG. 7 of the embodiment of the present invention described above to steps S24-1 to S24-X, and steps S5-1 to S5-2 Are replaced with steps S25-1 to S25-X, but when the control flow shown in FIG. 10 and the control flow shown in FIG. 7 are executed in parallel, step S25-1 to S25- in FIG. This is a control flow to which X processing is added. Specifically, steps S4-1 to S4-2 in FIG. 7 are expanded to S4-X, and additionally, steps S5-1 to S5-2 are also expanded to S5-X. Then, steps S25-1 to S25-X may be added and executed after steps S5-1 to S5-X.

  For example, when the discharge pressure PS at the time of startup of the pump 2 is calculated as the pressure level PL1 (when "YES" in step S4-1), the control device 60 sets the torque boost voltage to V1 (step S5- 1), the soft start time is set to ST1 (step S25-1), and the pump 2 is started (step S6). Further, when the control device 60 calculates the pressure PS at the time of startup of the pump 2 as the pressure level PL2 which is a pressure value higher than the pressure level PL1 (when "YES" in step S4-2), the control device In step 60, the torque boost voltage is set to V2 higher than V1 (step S5-2) and the soft start time is set to ST2 longer than ST1 (step S25-2) to start the pump 2 (step S25-2). S6).

  Thus, by setting the control parameter according to the magnitude of the discharge pressure PS at the start of the pump 2, the current flowing through the inverter device 70 at the start of the pump 2 is suppressed, and the protection stop of the pump 2 is suppressed. It becomes possible. In addition to the embodiment described above, the first modification may be implemented. Further, the reference value VL0 of the torque boost voltage may be a constant value regardless of the discharge pressure PS at the time of start, or the user may change the setting or calculation method thereof by the setting unit 64a or the like.

  The control device 60 sets the above-described control parameter (for example, VL0 shown in FIG. 8) according to the set starting pressure P0 when the setting changeable starting pressure P0 is changed by the user ( For example, it may be changed as an initial value of the control parameter.

  Further, in the present embodiment, the following second modification may be employed. In the following description, the same or equivalent components and steps as those of the above-described embodiment are denoted by the same reference numerals, and the description thereof is simplified or omitted.

  FIG. 11 is a time chart showing an example of the relationship between the discharge pressure PV of the pump 2 according to the second modification of the embodiment of the present invention and the command frequency by the inverter control unit 60b of the control device 60. In the time chart of FIG. 11A, the vertical axis indicates the pressure value, the horizontal axis indicates the elapsed time, and the change in the discharge pressure PV due to the elapsed time. In the time chart shown in FIG. 11B, the vertical axis represents the frequency, the horizontal axis represents the elapsed time, and changes in the command frequency output from the control device 60 to the inverter device 70 due to the elapsed time. FIG. 12A is a control flow showing an example of a retry operation (step S109 in FIG. 5B) executed by the control device 60 according to the second modified embodiment of the present invention.

  In FIG. 11, after the small water amount stop (tr11, step S106 in FIG. 5B), the discharge pressure PV pressurized to the stop pressure P1 decreases to the start pressure P0 or less (tr12, step S101 in FIG. 5B is “YES”). ) When the pump 2 is to be restarted in a short stop, due to a malfunction such as an overcurrent trip (step S103 in FIG. 5B is “NO”), the pump 2 stops protection (tr13, step S107 in FIG. 5B). After that, the pump 2 is started by the retry operation (step S109 in FIG. 5B) (tr14), but the pump 2 cannot be normally started (step S110 in FIG. 5B is “NO”), and the retry is not completed. (Step S111 in FIG. 5B is “NO”), the pump 2 again stops protection (tr15, Step S107 in FIG. 5B), and then Illustrates a case where the pump 2 is normally started (tr17, step S110 of FIG. 5B is “YES”) when the pump 2 is started by the second retry operation (tr16, step S109 of FIG. 5B). There is.

  As shown in FIG. 11, when the number of retries is the first time, the control device 60 sets an interval time from the end of protection stop of the pump 2 (step S107 in FIG. 5B) to the start to T1. Further, when the number of retries is the second time, the control device 60 sets an interval time to start the pump 2 to T2 which is longer than T1. In this way, the control device 60 increases the interval time according to the number of retries. In the present embodiment, for easy explanation, the protection stop in step S107 in FIG. 5B is canceled immediately after the pump 2 stops.

  Next, the retry operation in FIG. 11 will be described in detail with reference to FIG. 12A. FIG. 12A is a control flow executed at the timing when the protection stop of the pump 2 is canceled after the pump 2 is stopped at tr13 or tr15 shown in FIG. 11, and in the retry operation of step S109 of FIG. It is a control flow which explained the details. In the control flow of the retry operation shown in FIG. 12A, the control device 60 first counts the number of retries (step S31). Next, the control device 60 determines the current number of retries (steps S32-1 to S32-N). Then, the control device 60 sets an interval time from when the protection stop of the pump 2 is canceled to when the pump 2 is restarted by the retry execution according to the current number of retries (steps S33-1 to S33). -N).

  Specifically, when the number of retries is the first (step S32-1 is “YES”), the interval time is set to the initial value T1 (step S33-1), and the number of retries is the second (step S32-1). Is “NO” and step S32-2 is “YES”), the interval time is set to T2, which is larger than T1 (step S33-2). Thus, it is preferable to increase the interval time each time the number of retries increases (T1 <T2 <... <TN). Note that T2 to TN may be values calculated by adding or multiplying a predetermined value to T1, which is an initial value, or may have a table in the storage unit 63 and hold that value.

  The pump 2 cannot be started in a state where the water supply pipe is released (for example, the faucet is open) (Step S103 in FIG. 5B is “NO”), and the pump 2 is protected and stopped (in FIG. 5B). After step S107), the discharge pressure PV that has been pressurized in the pressure accumulation operation gradually decreases. By setting the interval time and decreasing the discharge pressure PV when starting the pump 2, the starting torque of the motor 3 is reduced. Therefore, the interval time is one of the control parameters related to the drive control of the electric motor 3.

  Next, the control device 60 determines whether the set interval time has elapsed (step S34). When the interval time has elapsed ("YES" in step S34), the control device 60 confirms the start condition ("YES" in step S35a), and executes retry (step S35). Specifically, at step S34, the control device 60 prohibits the operation for the interval time (while the step S34 is "NO"), and makes the pump 2 stand by in the stop state. When the interval time has elapsed ("YES" in step S34), control device 60 determines whether or not the starting condition is satisfied, at the time of canceling the operation impossibility. If it is determined that the starting condition is satisfied (in the case of "YES" in step S35a), the pump 2 is started in the process of retry execution in step S35. Here, in step S35a, a second start condition in which the discharge pressure PV is equal to or lower than the start pressure P0 after the protection of the pump 2 is stopped, and further, a third start condition to be described later, which is an additional condition of the second start condition, is set. If satisfied, “YES” is set, and step S35a is determined as “NO” and waits until the second start condition and further the third start condition are satisfied. Next, in step S36, the control device 60 confirms the normal start by the pumping operation of the pump 2 and determines the water supply of the pump 2 (when step S36 is “YES”), the retry operation is finished.

  On the other hand, when an overcurrent trip or the like occurs before the rotation speed increases to the rotation speed at which the pump 2 can pump water at the specified head in step S36 (when step S36 is “NO”), the control device 60 The number of retries is confirmed (step S38). If the number of retries is less than N (step S38 is “NO”), the control flow in FIG. 12A is terminated. If the number of retries is N times or more (when step S38 is “YES”), the control flow of FIG. 12A is terminated as a retry end (step S100), and the normal start is “NO” in step S110 of FIG. 5B. Then, in step S111, it is determined that the retry end is "NO", and protection of step S107 is stopped again. When the retry is completed in step S100, the normal start is “NO” in step S110 of FIG. 5B, “YES” is determined in step S111, and the failure of the pump 2 is determined (step S112).

  Here, in the steps S33-1 to S33-N, since the interval time is set longer according to the number of retries, the retry operation is executed later as the number of retries increases. As shown in FIG. 11, the discharge pressure PV of the pump 2 decreases with the passage of time. Therefore, the longer the interval time is, the smaller the starting torque of the motor 3 is. In this way, by increasing the interval time according to the number of retries, the pump device 1 is defined by the pump 2 before the number of retries exceeds the set number (for example, N = 5) and the pump 2 is determined to be faulty. The probability of being able to drive at the lift increases. As in the above-described embodiment, the control device 60 causes the pump 2 to reverse the normal rotation direction once every several times (for example, the number of retries is 3 × m: m is a natural number). It may be rotated in the direction (step S37).

  In addition, after determining the protection stop of the pump 2, the control device 60 disables the pump 2 for a predetermined period (tr13 to tr14 and tr15 to tr16 in FIG. 11), and makes the pump 2 stand by in a protection stop state. May be. In this case, an interval time may be set in addition to the operation disabled time due to the protection stop.

  Thus, according to the second modification described above, the control device 60 counts the number of times the pump 2 is started under the second start condition as the number of retries, and from when the protection stop of the pump 2 is released. The interval time until the pump 2 is restarted is changed according to the number of retries, and when the second start condition is satisfied, the pump 2 is started based on the changed interval time according to the number of retries. By adopting the above, it is possible to obtain a highly convenient pump device 1 that can suppress protection stoppage of the pump 2 and avoid water cut as much as possible.

  Further, the control device 60 sets the coefficients PL1T and PL2T for changing the interval time according to the number of retries, the magnitude of the starting discharge pressure PS that is the lowest value estimated when the first start condition is satisfied. You may correct | amend according to. The start-up discharge pressure PS is estimated when the first start condition is satisfied as described above (step S4 in FIG. 7), and is stored in the storage unit 63. Specifically, this process is executed according to the control flow shown in FIG. 12B. The control flow shown in FIG. 12B shows an example of processing for calculating the interval time in step S33-1 in FIG. 12A. The same process is performed in steps S33-2 to S33-N in FIG. 12A.

  As shown in FIG. 12B, first, the control device 60 determines the pressure level at the start discharge pressure PS (steps S33-1-1 to S33-1-2). Here, the pressure level PL1 shown in step S33-1-1 and the pressure level PL2 shown in step S33-1-2 in this embodiment are assumed to be the same as the pressure level PL1 and the pressure level PL2 shown in FIG. However, the present invention is not limited to this, and may have any range or value. However, it is assumed that PL2 is higher than PL1.

  Next, the control device 60 corrects the coefficients PL1T and PL2T, which change the interval time according to the number of retries, according to the magnitude of the discharge pressure PS at the time of start when the first start condition is satisfied (step S33-1-3 to S33-1-4). Specifically, if the pressure level at the starting discharge pressure PS in step S33-1-1 is within the range of PL1 (step S33-1-1 is “YES”), step S33-1-3 is executed. Run. PL1T shown in step S33-1-3 is a coefficient for calculating the interval time T1, which corresponds to the size of the discharge pressure PS at start-up when the first start-up condition is satisfied or the pressure level PL1. It may be calculated. In step S33-1-3, the coefficient PL1T is added to T1B (base value of T1 in FIG. 12A) which is an interval time set according to the number of retries. The coefficient PL1T may be multiplied by T1B.

  In addition, if the pressure level at the start-up discharge pressure PS is within the range of PL2 in step S33-1-2 (step S33-1-1 is "NO" and step S33-1-2 is "YES"). Step S33-1-4 is executed. PL2T shown in step S33-1-4 is a coefficient for calculating T1, and is calculated according to the magnitude of the starting discharge pressure PS or the pressure level PL2 when the first start condition is satisfied. Good. In step S33-1-4, the coefficient PL2T is added to T1B, which is an interval time set according to the number of retries. Also in step S33-1-4, the coefficient PL2T may be multiplied by T1B. Thereby, the interval time T1 set in step S33-1 can be set to a larger value in the case of PL2, which is a higher value than in the case where the starting discharge pressure PS is PL1.

  The coefficients PL1T and PL2T may use different calculation formulas, or may increase as the number of retries increases. That is, since the slope of the decrease in the discharge pressure PV when the water is used at the water supply destination but the pump 2 is not operating can be assumed to be constant, the start-up discharge pressure PS is PL1. This is because the discharge pressure PV when the protection stop of the pump 2 is released becomes larger at PL2 than at the time. As described above, when the discharge pressure PV at the time of starting the pump 2 is higher, the rotation of the impeller 20 is less likely to start, and when starting torque is required, the value at the time of starting discharge pressure PS being PL1. It is better to make the interval time at PL2 longer than that. Specifically, T1 to TN when starting discharge pressure PS is PL2 are larger than T1 to TN when starting discharge pressure PS is PL1 (TN is the interval time in the N-th retry). The coefficients PL1T and PL2T may be set as

  Thus, when the coefficients PL1T and PL2T for changing the value of the interval time according to the number of retries are corrected according to the magnitude of the starting discharge pressure PS estimated when the first start condition is satisfied. Good. In addition, although the discharge pressure PS at the time of start-up in the present embodiment shows two calculation methods of the pressure level PL1 and the pressure level PL2, the pressure level is X (X is an arbitrary natural number of 1 or more) regardless of this. And PL1T to PLXT may be calculated as coefficients corresponding to the pressure levels PL1 to PLX.

  Moreover, in this embodiment, the following 3rd modifications can be employ | adopted. In the following description, the same or equivalent components and steps as those of the above-described embodiment are denoted by the same reference numerals, and the description thereof is simplified or omitted.

FIG. 13A is a control flow showing an example of the confirmation of the third start condition executed by the control device 60 according to the third modification of the embodiment of the present invention.
The control flow shown in FIG. 13A is the various conditions of the second start condition in the above-described retry operation (step S109 in FIG. 5B) (the discharge pressure PV is less than the start pressure P0 after canceling the protection stop of the pump 2) Further, a case where a condition (third start condition) which is equal to or less than a later-described retry start pressure RPL set to be lower than the start pressure P0 is shown. That is, the third start condition is an additional condition of the second start condition. For example, the control flow shown in FIG. 13A may be executed after the determination of the conditions of the second start condition in step S35a shown in FIG. 12A, or the determination of the conditions of the second start condition in step S108 of FIG. 5B. Sometimes it may be executed. The control device 60 determines whether the discharge pressure PV has decreased to the retry start pressure RPL shown in FIG. 11 as the determination of the third start condition (step S41).

  The retry start pressure RPL is a pressure value lower than the starting pressure P0, and is preferably a pressure at which the starting torque does not become insufficient due to the retry operation. The retry start pressure RPL may be a set value that can be changed by the user, or may be changed by the control device 60 according to the number of retries. Alternatively, the retry start pressure RPL may be calculated by subtracting or dividing a predetermined value from the discharge pressure PV when protection is stopped. When the control device 60 changes the retry start pressure RPL according to the number of retries, the retry start pressure RPL may be a small value as the number of retries increases.

  If the discharge pressure PV has not decreased below the retry start pressure RPL (when step S41 is “NO”), the control device 60 waits until the discharge pressure PV decreases below the retry start pressure RPL. When the discharge pressure PV at the start of the pump 2 due to retry execution is higher, rotation of the impeller 20 is more difficult to start and requires a starting torque. Therefore, at the timing when the discharge pressure PV is lowered to the retry start pressure RPL ( By performing the retry operation ("YES" in step S41) (step S42), it is possible to suppress the protection stop due to the insufficient torque at the start of the pump 2 as compared with the case where the pump 2 is started at the start pressure P0. .

  An example in which the process shown in step S42 in FIG. 13A is applied to the retry operation in step S109 in FIG. 5B described above will be described. This process may be performed along the flow shown in FIG. 13B. Note that the flow shown in FIG. 13B shows processing that is executed in place of step S107 (protection stop) to step S109 (retry operation) in FIG. 5B described above. Specifically, when the third start condition shown in step S41 of FIG. 13A is satisfied in addition to the various conditions of the second start condition described above (step S108 is “YES”) (step S108-1 is “YES In the case of (1), the retry operation of step S109 in FIG. 5B may be performed. As a result, when the retry is executed and the pump 2 is started, the discharge pressure PV is reduced to the retry start pressure RPL or less, so that protection stop due to insufficient torque at the start of the pump 2 can be suppressed. Also, in the case where the various conditions of the second start condition are negative (step S108 is “NO”) or the third start condition shown in step S41 of FIG. 13A is negative (step S108-1 is “NO”). Then, the process returns to the protection stop of step S107.

  An example in which the process shown in step S42 in FIG. 13A is applied to the retry execution in step S35 in FIG. 12A described above will be described. Specifically, in step S35a in FIG. 12A, when the third start condition shown in step S41 in FIG. 13A is satisfied (when step S41 is “YES”), the retry execution process in step S35 in FIG. 12A. It is good to do. When the discharge pressure PV is higher than the retry start pressure RPL in step S41 of FIG. 13A, the third start condition is negative (step S108-1 is “NO”), and the discharge pressure PV is the retry start pressure. Wait until it is below RPL.

  Thus, in addition to the various conditions of the second start condition, the start condition of the pump 2 includes a third start condition in which the discharge pressure PV is equal to or lower than the retry start pressure RPL set to be less than the start pressure P0. Good. As a result, since the discharge pressure PV is reduced to the retry start pressure RPL or less when the third start condition is satisfied and the pump 2 is started, suppression of protection stop due to insufficient torque at the start of the pump 2 can be suppressed. it can.

Further, in the present embodiment, the following fourth modification may be employed.
FIG. 14 is a time chart showing an example of the relationship between the discharge pressure PV of the pump 2 and the command frequency from the control device 60 to the inverter control unit 60b according to the fourth modification of the embodiment of the present invention. In the time chart shown in FIG. 14A, the vertical axis represents pressure, and the horizontal axis represents elapsed time, and shows the change in discharge pressure PV due to elapsed time. In the time chart shown in FIG. 14B, the vertical axis represents frequency and the horizontal axis represents elapsed time, and shows a change in the command frequency from the control device 60 to the inverter device 70 according to the elapsed time. FIG. 15A is a control flow showing an example of a retry operation (step S109 in FIG. 5B) executed by the control device 60 according to the fourth modified embodiment of the present invention.

  In FIG. 14, the discharge pressure PV of the pump 2 pressurized to the stop pressure P1 is started from the stop pressure P1 after the small amount of water stop (tr20, step S106 in FIG. 5B) as in the second modification described above. When the pressure drops to P0 (tr21, step S101 in FIG. 5B is “YES”) and the first start condition is satisfied and the pump 2 is to be restarted in a short stop (step S102 in FIG. 5B), the starting torque is insufficient. Pump 2 cannot be started (step S103 in FIG. 5B is “NO”), and pump 2 stops protection (tr22, step S107 in FIG. 5B). Thereafter, the second start condition is satisfied, and the retry operation ( A case where the pump 2 is restarted in step S109) of FIG. 5B is illustrated.

  The control device 60 increases the soft start time according to the number of retries for restarting the pump 2. For example, as shown in FIG. 14, in the case of the small stop restart where the number of retries is 0 (tr21), that is, the first start condition is satisfied, the soft start time is ST0 which is a reference value. When the number of retries is the first time (tr23), the control device 60 sets the soft start time to ST11 longer than ST0. In addition, when the number of retries is the second (tr25), control device 60 sets the soft start time to ST12 that is longer than ST11. Note that ST11 and ST12 may be obtained by adding or multiplying a predetermined value to ST0, or in FIG. 10 described above, values set according to the discharge pressure PS at start-up of the pump 2 (ST1 to STN) May be obtained by adding or multiplying a predetermined value to ST0.

  Here, as described above, the soft start time is one of the control parameters related to the drive control of the electric motor 3, and the longer the soft start time, the more the acceleration of the electric motor 3 can be suppressed. The current flowing through the inverter device 70 can be suppressed. In this embodiment, as an example, as shown in FIG. 14, when the command frequency by the inverter control unit 60 b when setting the pressure PA is PAF, as shown in FIG. 14, the command frequency from the initial value (zero) This corresponds to the length of the command time taken to reach the PAF (for example, ST12 from tr25 to tr26). However, the soft start time may be, for example, the time for the rotational speed of the motor 3 to reach a predetermined rotational speed (for example, maximum output rotational speed) from a value of 0 (zero) regardless of the command frequency PAF.

  Next, the retry operation in FIG. 14 will be described in detail with reference to FIG. 15A. The control flow of the retry operation shown in FIG. 15A is that when the protection stop is released after the protection stop of the pump 2 (tr22, tr24) (tr23, tr25), the discharge pressure PV is determined to be equal to or less than the starting pressure P0. 5B is a control flow illustrating the details of the retry operation in step S109 of FIG. 5B. In the control flow of the retry operation shown in FIG. 15A, the control device 60 first counts the number of retries (step S51). Next, the control device 60 determines the current number of retries (steps S52-1 to S52-N). Then, the control device 60 sets the soft start time according to the current number of retries (steps S53-1 to S53-N).

  Next, the control device 60 executes retry execution based on the set soft start time (step S54). Specifically, the control device 60 starts the pump 2, accelerates the electric motor 3 with the increasing rate of the soft start time, and operates so that the discharge pressure PV of the pump 2 becomes the set pressure PA. Next, in step S55, the control device 60 confirms normal startup for pumping operation at a prescribed head of the pump 2 and determines water supply of the pump 2 (in the case where “YES” in step S55), FIG. This completes the control flow. On the other hand, when it is not possible to confirm the normal start due to an overcurrent trip or the like before judging the water supply according to the prescribed head of the pump 2 in step S55 (in the case of "NO" in step S55), the control device 60 confirms the number of retries. If the number of retries is less than N (step S57 is “NO”), the control flow of FIG. 15A ends. If the number of retries is N times or more (if step S57 is “YES”), the control flow of FIG. 15A is ended as retry completion (step S100) in order to confirm the failure of the pump 2.

  Here, in steps S53-1 to S53-N, since the soft start time is set longer according to the number of retries, the current associated with the acceleration of the motor 3 can be suppressed as the number of retries increases. It is possible to prevent the current flowing to the inverter device 70 from reaching the set overcurrent protection level and stopping the protection. Thus, by increasing the soft start time according to the number of retries, the probability that the pump 2 can recover before the number of retries exceeds the set number N increases. As in the above-described embodiment, the control device 60 causes the pump 2 to reverse the normal rotation direction once every several times (for example, the number of retries is 3 × m: m is a natural number). It may be rotated in the direction (step S56).

  Thus, according to the above-described fourth modification, the control device 60 counts the number of times of starting the pump 2 under the second start condition as the number of retries as shown in FIG. 15A (step S51). The soft start time, which is one of the control parameter values set according to the magnitude of the start discharge pressure PS, which is the lowest value under the first start condition, is changed according to the number of retries, and the second start condition By adopting a configuration in which the pump 2 is started based on the soft start time changed according to the number of retries when the condition is satisfied, the protection stop and failure confirmation of the pump 2 are suppressed, and the water cut is avoided as much as possible. A highly convenient pump device 1 can be obtained.

  In addition, the control device 60 sets the coefficients PL1ST and PL2ST for changing the soft start time according to the number of retries to the maximum value of the starting discharge pressure PS that is the lowest value estimated when the first start condition is satisfied. You may correct | amend according to it. The start-up discharge pressure PS is estimated when the first start condition is satisfied as described above (step S4 in FIG. 7), and is stored in the storage unit 63. Specifically, this process is executed along the control flow shown in FIG. 15B. Note that the control flow shown in FIG. 15B shows an example of processing for calculating the soft start time in step S53-1 in FIG. 15A. The same process is performed in steps S53-2 to S53-N in FIG. 15A.

  As shown in FIG. 15B, first, the control device 60 determines the pressure level at the start-up discharge pressure PS when the first start condition is satisfied (steps S53-1-1 to S53-1-2). . Here, the pressure level PL1 shown in step S53-1-1 and the pressure level PL2 shown in step S53-1-2 in this embodiment are assumed to be the same as the pressure level PL1 and the pressure level PL2 shown in FIG. However, the present invention is not limited to this, and may have any range or value. However, it is assumed that PL2 is higher than PL1.

  Next, control device 60 corrects coefficients PL1ST and PL2ST for changing the soft start time according to the number of retries according to the magnitude of discharge pressure PS at the time of start when the first start condition is satisfied ((1) Steps S53-1-3 to S53-1-4). Specifically, if the pressure level at the starting discharge pressure PS in step S53-1-1 is within the range of PL1 (step S53-1-1 is “YES”), step S53-1-3 is executed. Run. PL1ST shown in step S53-1-3 is a coefficient for calculating ST11, and is calculated according to the magnitude of the starting discharge pressure PS or the pressure level PL1 when the first start condition is satisfied. Good. In step S53-1-3, the coefficient PL1ST is added to ST11B (base value of ST11 in FIG. 15A) which is the soft start time set according to the number of retries. The coefficient PL1ST may be multiplied by ST11B.

  If the pressure level at the starting discharge pressure PS is within the range of PL2 in step S53-1-2 (step S53-1-1 is “NO” and step S53-1-2 is “YES”). , Step S53-1-4 is executed. PL2ST shown in step S53-1-4 is a coefficient for calculating ST11, and is calculated according to the magnitude of the starting discharge pressure PS or the pressure level PL2 when the first start condition is satisfied. Good. In step S53-1-4, the coefficient PL2ST is added to ST11B, which is the soft start time set according to the number of retries. Also in step S53-1-4, the coefficient PL2ST may be multiplied by ST11B. As a result, in step S53-1, the soft start time ST11 can be set to a larger value in the case where the discharge pressure PS at the time of start-up is PL2 than in the case where it is PL1.

  The coefficients PL1ST and PL2ST may use different calculation formulas, or may increase as the number of retries increases. That is, since the slope of the decrease in the discharge pressure PV when the water is used at the water supply destination but the pump 2 is not operating can be assumed to be constant, the start-up discharge pressure PS is PL1. This is because the discharge pressure PV when the protection stop of the pump 2 is released becomes larger at PL2 than at the time. As described above, when the discharge pressure PV at the time of starting the pump 2 is higher, the rotation of the impeller 20 is less likely to start, and when starting torque is required, the value at the time of starting discharge pressure PS being PL1. It is better to lengthen the soft start time at PL2 than it does. Specifically, control device 60 has coefficients PL1ST and PL2ST in which ST11 to ST1N when starting discharge pressure PS is PL2 are larger than ST11 to ST1N when starting discharge pressure PS is PL1. And it is sufficient.

  In this way, the magnitude of the starting discharge pressure PS estimated when the coefficients PL1ST and PL2ST for changing the value of the soft start time as the control parameter according to the number of retries is satisfied when the first start condition is satisfied. It is good to correct according to. In addition, although the discharge pressure PS at the time of start-up in the present embodiment shows two calculation methods of the pressure level PL1 and the pressure level PL2, the pressure level is X (X is an arbitrary natural number of 1 or more) regardless of this. Then, PL1ST to PLXST may be calculated as coefficients corresponding to the pressure levels PL1 to PLX.

  Further, the process of FIG. 15A may be added to the process of FIG. 12A described above. Specifically, as shown in FIG. 15C, after steps S33-1 to S33-N, steps S53-1 to S53-N are performed to set ST11 to ST1N as the soft start time, and the process proceeds to step S35a. 2) When the start condition (in the case of “YES”) is satisfied, retry execution may be performed in step S35. In this way, by changing the interval time and the soft start time according to the number of retries, it is possible to obtain a highly convenient pump device 1 that suppresses protection stoppage of the pump 2 at the start and avoids water break as much as possible. Furthermore, the process of FIG. 13A may be added to the process of FIG. 15C. Specifically, when the above-described third start condition is satisfied in step S35a, the flow illustrated in FIG. 13A may be executed.

FIG. 16 is a control flow showing an example of control parameter initialization executed by the control device 60 according to the embodiment of the present invention. That is, an example of a predetermined return condition for changing the value of the control parameter changed when the second start condition is satisfied and the pump 2 is started from the second control parameter value to the first control parameter value is shown.
In the present embodiment, a control flow will be described in which the control parameter changed in the above-described embodiment and each modification is returned to the initial control parameter used in the small stop restart during the operation of the pump 2. In the above-described retry operation (step S109 in FIG. 5B), protection stop due to a transitional state at the start can be avoided (“YES” in step S110 in FIG. 5B), and then water is continuously supplied (FIG. 5B). In step S104), without waiting for the pump 2 to stop, the pump 2 is appropriately operated by returning the control parameter changed in the retry operation to the initial control parameter (control parameter at the time of small stop restart). can do.

  Specifically, for example, when the pump 2 is started under the first start condition in step S102 of FIG. 5B, for example, the control device 60 stores the value of the control parameter as the first control parameter value in the storage unit 63. To do. Moreover, the control apparatus 60 memorize | stores the value of the control parameter used when starting the pump 2 on 2nd starting conditions in the memory | storage part 63 as 2nd control parameter in step S109 of FIG. 5B. Thus, the value of the control parameter is the first control parameter value used when starting the pump 2 under the first start condition, and the second control parameter value used when starting the pump 2 under the second start condition And the controller 60 satisfies the second start condition, restarts the pump 2, and determines that the pump 2 has started normally in step S110 of FIG. If satisfied, the value of the control parameter is changed from the second control parameter value to the first control parameter value.

  In the case shown in FIG. 8, the torque boost voltage VL2 set in the second retry operation is returned to the torque boost voltage VL0 after the water supply by the pump 2 is restored. Thus, by reducing the torque boost voltage changed at the time of the retry to the torque boost voltage at the time of the restart at the short stop, the electric motor 3 can be driven by the optimum “Vf control”, so that the driving energy of the electric motor 3 can be saved. Can be made. The pump device 1 of the third usage example shown in FIG. 19 described later is used as a water supply device for condominiums, etc., and there is little opportunity for the pump 2 to stop a small amount of water due to recent diversification of living environment, and the amount of water supply in the morning etc. Keep driving at low speed except during heavy hours. In such a usage example, the effect of saving the driving energy of the electric motor 3 by returning the torque boost voltage raised during the retry operation to VL0 without waiting for the timing of stopping the small amount of water is high. Further, it is preferable to return the soft start times ST11 to ST1N set according to the number of retries shown in FIG. 15A to ST0 shown in FIG. By shortening the soft start time, the followability of the discharge pressure PV accompanying the flow rate fluctuation at the water supply destination is improved. In addition, when the pump 2 stops a small amount of water or stops protection during execution of the flow of FIG. 16, the flow of FIG. 16 is interrupted.

  The control flow shown in FIG. 16 is executed after the determination of “YES” in step S110 of FIG. 5B, and is performed in parallel with step S104 of FIG. 5B. The determination of step S110 “YES” in FIG. 5B corresponds to step S16 “YES” in FIG. 9A, step S36 “YES” in FIG. 12A, step S55 “YES” in FIG. In order to confirm that the pump 2 is normally supplying water in the pumping operation, the control device 60 determines that the discharge pressure PV is close to the pressure of a predetermined specified head as a determination of step S110 “YES” in FIG. 5B. It is good to check whether it has reached. Further, it is preferable to check that the discharge pressure PV has turned from a drop to a rise and a predetermined time has elapsed, or that the discharge pressure PV has reached a predetermined pressure or the like with a flow sensor 35b.

  Step S62 in FIG. 16 shows an example of return conditions for changing the value of the control parameter from the second control parameter value to the first control parameter value, and the control device 60 supplies the current to the motor 3 (specifically, Determines whether the measured value of the current sensor 72 is less than or equal to a predetermined current limit level. As indicated by tr5 to tr6 in FIG. 8, the current flowing through the inverter device 70 transiently increases when the pump 2 is started. In addition, when a load of the electric motor 3 becomes larger than the normal range due to foreign matter caught in the impeller 20 of the pump 2 and the load becomes greater than the normal range, the current flowing through the inverter device 70 increases. If the current flowing through the device 70 is less than or equal to the predetermined current limit level ("YES" in step S62), it is determined that the load of the motor 3 is within the normal range, and the process proceeds to the next step S63. On the other hand, if the determination in step S62 is "NO", control device 60 waits until the current flowing through inverter device 70 falls below a predetermined current limit level. Here, the current limit level is a value smaller than an overcurrent protection level (for example, AL0, AL1, AL2, etc.) that is an overcurrent trip threshold, and the inverter device 70 is supplied when the pump 2 supplies water at a specified head. It is recommended to add a margin to the current flowing through the

  In the next step S63, another example of the return condition for changing the value of the control parameter from the second control parameter value to the first control parameter value is shown. The control device 60 determines that the amount of water flowing to the pump 2 is a predetermined amount of water. It is determined whether this is the case. Specifically, the control device 60 determines whether or not the flow sensor 35b has detected an underwater amount Qmin or less. When the flow sensor 35b does not detect the excessive water amount Qmin and the amount of water flowing through the pump 2 is equal to or greater than the excessive water amount (when step S63 is “YES”), the control device 60 supplies the water in the pumping operation. Then, the process proceeds to the next step S64. On the other hand, if the determination in step S63 is “NO”, the pump 2 is not pumping water or water is not used before the supply destination and only pressure is accumulated in the pressure tank 43. The pump 2 is shut off and the control flow is exited. If the determination in step S63 is "NO", the control device 60 returns to the determination in step S62. When the amount of water flowing to the pump 2 is small, it is difficult to determine whether or not pumping can be normally performed even if the current flowing to the inverter device 70 is small and the current is equal to or less than the current limit level. The controller 60 confirms the amount of water flowing to the pump 2. However, step S63 may be omitted as long as it can be determined whether or not the water is pumped normally.

  In the next step S64, the control device 60 is in a state (step S62 and / or step S63) in which the current flowing through the inverter device 70 that is the return condition is equal to or lower than the current limit level and / or the flow sensor 35b does not detect the excessive water amount Qmin. If “YES”), it is determined whether or not a predetermined time has elapsed. When the predetermined time has elapsed (when Step S64 is “YES”), the control device 60 proceeds to the next Step S65. On the other hand, if the determination in step S64 is "NO", the process returns to step S62, and the controller 60 determines that the current flowing to the inverter device 70 is below the current limit level and / or the flow sensor 35b does not detect the excessive water amount Qmin. While confirming that it has become, wait until a predetermined time has elapsed.

  If "YES" in any of steps S62 to S64, the control device 60 determines that the cause of the abnormality has been removed, and initializes control parameters (step S65). Specifically, the various control parameters changed in the above-mentioned retry operation (step S109 in FIG. 5B) are returned to the control parameters used in the small stop restart (step S102 in FIG. 5B). On the other hand, if any one of Steps S62 to S64 is “NO”, there is a possibility that the cause of the abnormality has not yet been removed. Therefore, the control device 60 continues to use the control parameter changed during the retry operation.

  As described above, according to the above-described embodiment, the pump 2, the motor 3 for driving the pump 2, the inverter device 70 for supplying power to the motor 3, and the control device 70 for outputting a control signal to the inverter device 70 A pump device 1 comprising a control device 60 for controlling operation, wherein the control device 60 sets control parameter changing means for changing control parameters related to drive control of the motor, and a current flowing through the inverter device 70 is set Reset means for returning the changed control parameter to the control parameter at the time of the restart at a short stop when the constant time is below the set current limit level and / or when the predetermined amount of time has passed without detecting the excessive water amount Qmin. By adopting the configuration of having the maintenance parameter, the maintenance worker hassle to change after the control parameter is changed. Better even without reset operations of the control parameter to go to the scene, the convenience of the pump device 1 is increased. In addition, when the pump 2 is started, torque shortage occurs due to friction of the sliding surface of the shaft seal portion of the pump 2, so if the pump 2 starts and operates normally and the current stabilizes for a certain period of time, retry is performed. The various control parameters changed at the time of operation can be returned to the values at the time of the small stop restart.

  Although preferred embodiments of the present invention have been described and described above, it should be understood that these are exemplary of the present invention and should not be considered as limiting. Additions, omissions, substitutions, and other modifications can be made without departing from the scope of the present invention. Accordingly, the invention is not to be seen as limited by the foregoing description, but is limited by the scope of the claims.

  For example, the control flow combinations and replacements of the above-described embodiments can be appropriately performed.

  Further, for example, the various control parameters described above may be stored in the storage unit 63 of the control device 60 and may be changeable in setting from the I / O unit 61. In addition, you may calculate the value of the various control parameters mentioned above used at the time of retry operation | movement before judging 2nd starting conditions. For example, before determining the second start condition (step S108 in FIG. 5B) such as when the protection is stopped (step S107 in FIG. 5B) or the retry is ended (step S111 in FIG. 5B), the control device 60 A value may be calculated and stored in the storage unit 63, and in the retry operation (step S109 in FIG. 5B), the pump 2 may be started based on the value of the control parameter stored in the storage unit 63.

  Moreover, although the pump apparatus 1 demonstrated by the said embodiment was equipped with one pump, the number of pumps may be two or more. In that case, the number of motors 3 and the number of inverter devices 70 may be set according to the number of pumps. Furthermore, the inverter device 70 may switch the connection to a pump to be started. Moreover, the pump 2 should just be a turbo pump irrespective of a cascade pump.

FIG. 17 is a schematic view showing a first use example of the pump device 1 of the present disclosure.
The pump device 1 shown in FIG. 17 is configured to pump water from the well 103a, which is a water supply source, and supply water to the faucet 102, which is an example of a plurality of water supply destinations at different heights in the building 101. There is. The pump device 1 is installed on the ground 103, the faucet 102a is installed at a height h1 from the ground 103, the faucet 102b is installed at a height h2 from the ground 103, and the faucet 102c is installed at a height h3 from the ground 103 It is done. As the installation height of the faucet 102 is higher, the discharge pressure PS at the time of starting the pump 2 at the time of restarting the stop increases, and the protection stop of the pump 2 is more likely to occur. Therefore, since the optimal control parameter differs depending on which faucet 102a-102c is opened at the time of the small stop restart, it is effective to install the pump device 1 of the present disclosure in such a use example.

  Further, depending on the building in which the pump device 1 is installed, the desired pressure at the heights h1, h2, h3 and the taps 102a to 102c differs. Therefore, the set pressure P suitable for the height of the building 101 and the amount of water supplied is changed, and the starting pressure P0 is also changed based on the set pressure PA. The discharge pressure PV of the pump 2 when the first start condition is satisfied is substantially equal to the start pressure P0. As described above, when the pump 2 is started, the motor 3 is driven by the discharge pressure PV of the pump 2. The torque required for starting differs on the side. Therefore, the value of the control parameter at the start may be changed by the discharge pressure PV of the pump 2 that is substantially equal to the start pressure P0. Specifically, instead of estimating the discharge pressure PS at the start of the pump 2 in steps S1 to S4 of FIG. 7, the start pressure P0, that is, when the first start condition of the pump 2 is satisfied. The discharge pressure PV is set to the discharge pressure PS at the start, and the controller 60 sets the torque boost voltage to be applied to the motor 3 at the start of the pump 2 according to the magnitude of the discharge pressure PS at the start (step S5 -1 to S5-2). Also in the subsequent operations, the discharge pressure PV when the first start condition of the pump 2 is satisfied may be set as the discharge pressure PS at the start and executed. Similarly, instead of estimating the discharge pressure PS at the start of the pump 2 in steps S21 to S23 in FIG. 10, the discharge pressure PV when the first start condition of the pump 2 is satisfied is started. When the discharge pressure PS is set, it is preferable to execute the following operation.

FIG. 18 is a schematic view showing a second usage example of the pump device 1 of the present disclosure.
The pump device 1 shown in FIG. 18 includes a ground unit 170 and a submersible motor pump 180, and the ground unit 170 and the submersible motor pump 180 are connected by a water pump tube TB. Such a pump device 1 is provided with the above-described pump 2 and electric motor 3 as the submersible motor pump 180 outside the unit cover 6, and is suitable, for example, for pumping water from the deep well DW. The submersible motor pump 180 is directly connected to a lower portion of a pump 181 which is a single suction centrifugal type or a mixed flow submersible submersible motor pump, for example, by a shaft coupling a motor 182 which is a submersible three phase induction motor.

  The ground unit 170 generally has a configuration in which the pump 2 and the motor 3 are omitted from the pump device 1 described above. Specifically, the ground unit 170 includes a control unit 60 and a pressure tank 43 fixed on the unit base 5, a unit cover 6 covering them, a display control unit 140 provided on the control unit 60, and a unit cover 6 is provided with a display 150 attached. In FIG. 18, the casing, the piping, and the pressure tank 43 that form the water flow path are not shown in the unit cover 6. Such a ground unit 170 supplies the water pumped from the submersible motor pump 180 to the water supply destination through the pumping pipe TB and further through the discharge pipe 111.

  The ground unit 170 performs the first short distance communication C1 between the display control unit 140 and the display 150, and displays information indicating the state of the pump device 1 on the display 150 attached to the unit cover 6 It is possible. Further, the ground unit 170 can display the information indicating the state of the pump device 1 on the display screen DP of the external display 160 by performing the second short-range communication C2 with the external display 160.

  The submersible motor pump 180 has a substantially cylindrical outer diameter shape including the pump 181 and the electric motor 182, and is used in a state of being submerged in water. The pump 181 is, for example, a stainless steel pump, and is driven by an electric motor 182. The electric motor 182 drives the pump 181 under the control of the control device 60. For example, as shown in FIG. 18, the submersible motor pump 180 is disposed so as to be located below the water surface WL (submerged in water) in the deep well DW dug downward from the depression 101, and through the pumping pipe TB. The water is pumped to the ground unit 170. The electric motor 182 is connected to the ground unit 170 via a submersible cable (not shown) wired substantially in parallel with the pumping pipe TB. The control signal calculated by the controller 60 and the electric power of the motor 182 are input to the motor 182 via the underwater cable. In addition, a pressure sensor and a flow rate detector (not shown) are attached to the pumping pipe TB or the discharge pipe 111 which is a discharge flow path of the pump 181, and the discharge pressure of the pump 181 is detected by the pressure sensor. The flow rate of the pump 181 (under water amount Qmin or less) is detected by the flow rate detector. These pressure sensor and flow rate detector are electrically connected to the I / O unit 61 (see FIG. 5A) of the control device 60.

  As described above, the pump device 1 shown in FIG. 18 attaches the display 150 capable of the first short-distance communication C1 and the second short-distance communication C2 to the upper surface 115U of the unit cover 6 and displays information indicating the state of the pump device 1 Are transmitted from the display 150 to the external display 160 by the second short distance communication C2 and displayed on the display screen DP of the external display 160. As a result, even if the pump device 1 is installed in an environment with poor workability, various information such as the operating state and the alarm can be easily confirmed without removing the unit cover 6. A communicator can be applied instead of the display 150. Furthermore, the window portion 115a of the unit cover 6 formed for the display 150 can be omitted, and an NFC with the communicator is possible. It is desirable to put a mark on the upper surface of the unit cover 6 indicating that the portion is a visible portion (visible portion). Even if it is such a structure, if this invention is applied, since it can suppress reaching protection stop at the time of the start of the pump 181, it becomes the highly convenient pump apparatus 1 which can avoid water interruption as much as possible.

FIG. 19 is a schematic view showing a third use example of the pump device 1 of the present disclosure.
The pump device 1 shown in FIG. 19 includes two pumps 2. The two pumps 2 are connected in parallel to the suction passage 34 branched into two. The upstream side of the suction channel 34 branched into two merges and communicates with the suction port 7 connected to the water source 110. A check valve 35a and a flow sensor 35b are disposed downstream of the two pumps 2, respectively, and the discharge flow path 41 merges on the downstream side of the two flow sensors 35b, and the merged discharge flow path 41 A pressure sensor 42 for detecting a discharge pressure PV of the pump 2 and a pressure tank 43 are provided. The discharge pressure PV of the pump 2 detected by the pressure sensor 42 is input to the pump control unit 60a (see FIG. 4) via a signal line.

  Inside the unit cover 6 are provided two motors 3 for driving the two pumps 2 respectively, and two inverter devices 70 for supplying electric power to the two motors 3 respectively. Two inverter control units 60 b are provided corresponding to the two inverter devices 70. On the other hand, the pump control unit 60a is one unit, controls the two inverter control units 60b in an integrated manner, and outputs control signals of the two pumps 2 to the two inverter devices 70, respectively. In such a configuration, one or a plurality of pumps 2 may be activated at the time of the small stop restart in step S102 of FIG. 5B. Moreover, it is good to add the number of operation | uses of the pump 2 or to disconnect it with the change of the amount of water used of a supply destination. In addition, even with such a configuration, if the present invention is applied, the pump 2 can be prevented from reaching protection stop at the time of start-up, so that the pump device 1 with high convenience can be obtained that can avoid water interruption as much as possible. The unit cover 6 may accommodate only the inverter device 70 and the pump control unit 60a.

  Here, the display 150 and the external display 160 of the pump device 1 shown in FIG. 18 are also applicable to the pump device 1 of FIGS. 1 and 19, and the operation panel 64, the external terminal 66, the display 150, In addition, at least one of the external display devices 160 has a number of retries, a control parameter value changed according to the number of retries, and a control parameter value changed from the second control parameter value to the first control parameter value. It is preferable to display the time of the return condition and the other state of the pump device 1 as a retry history. Thereby, the cause of the end of the retry can be identified. In the retry history, a history regarding the operation of the pump device 1 such as start / stop of the pump 2 during retry operation, the value of the pressure sensor 42, the state of the flow sensor 35b, and the steps of each flowchart may be stored along with time. .

Reference Signs List 1 pump device 2 pump 3 electric motor 4 control unit 5 unit base 6 unit cover 7 suction port 8 discharge port 20 impeller 21 groove 30 pump casing 31 pump chamber 32 internal flow path 32a one end 32b other end 33 air-water separation chamber 33a hole 34 suction flow path 35 flow check valve 35a check valve 35b flow sensor 36 connection flow path 37 baffle 38 priming water port 39 call water tap 40 priming water level 41 discharge flow path 42 pressure sensor 43 pressure tank 50 pump casing cover 60 control device 60a Pump control unit 60b Inverter control unit 61 I / O unit 61a Input unit 61b Output unit 62 Calculation unit 63 Storage unit 64 Operation panel 64a Setting unit 64b Display unit 65 Communication unit 66 External terminal 67 Display operation unit 70 Inverter device 70a Converter unit 70b DC voltage smoothing 70c Inverter section 70d Gate driver 71 Voltage sensor 72 Current sensor 80 Temperature sensor 81 Temperature sensor 82 Temperature sensor 100 Commercial power supply 101 Building 102 Faucet 102a Faucet 102b Faucet 102c Faucet 103 Ground 103a Well 110 Water source 111 Discharge pipe 115a Window part 115U Upper surface 140 Display control unit 150 Display 160 External display 170 Ground unit 180 Submersible motor pump 181 Pump 182 Motor AL0 Overcurrent protection level AL1 Overcurrent protection level C1 First short distance communication C2 Second short distance communication DP Display screen DW Deep well N Number of retries P0 Start pressure P1 Stop pressure PA Set pressure PAF Command frequency PL0 to PLN Pressure level PL1V Coefficient PL2V Coefficient PS Start discharge pressure PV Discharge pressure Qmin Underflow RPL Retor Start pressure S1 Step S2 Step S3 Step S4 Step S4-1 to S4-N Step S5-1 to S5-N Step S5 Step S6 Step S11 Step S12-1 to S12-N Step S13-1 to S13-N Step S13- 1-1 to S13-1-4 step S14-1 to S14-N step S15 step S16 step S17 step S18 step S21 step S22 step S23 step S24-1 to S24-X step S25-1 to S25-X step S25 step S26 Step S31 Step S32-1 to S32-N Step S33-1 to S33-N Step S33-1-1 to S33-1-4 Step S34 Step S35 Step S35a Step S36 Step S37 Step S38 Step S41 Step S51 Step S52-1 to S52-N Step S53-1 to S53-N Step S53-1-1 to S53-1-4 Step S54 Step S55 Step S56 Step S57 Step S61 Step S62 Step S63 Step S64 Step S65 Step S100 Step S101 Step S102 Step S103 Step S104 Step S105 Step S105-1 Step S106 Step S107 Step S108 Step S108-1 Step S109 Step S110 Step S111 Step S112 Step ST0 to STN Soft Start Time ST11 to ST1N Soft Start Time ST11B Soft start time base value PL1S Coefficient PL2ST coefficient SV target pressure T1 to TN interval time T1B interval time base value TB pump pipe PL1T coefficient PL2T coefficient V1 to V2 torque boost voltage V11 to 1N torque boost voltage V11B torque boost voltage base value VL0 to VLN torque boost voltage WL Water surface ΔT Time ΔT1 Time ΔT2 Time

Claims (13)

A pump for conveying water to the water supply destination;
An electric motor for driving the pump;
An inverter device for supplying electric power to the motor;
A control device for outputting a control signal of the pump to the inverter device;
The control device includes a storage unit that stores a value of at least one control parameter related to drive control of the electric motor,
The conditions for starting the pump are:
A first start condition for starting the pump when use of water is started at the water supply destination;
As a protection of the pump device, there is provided a second start condition for restarting the pump after a protection stop for stopping the pump started under the first start condition in the stop state,
The value of the control parameter is
A first control parameter value used when starting the pump under the first start condition;
A second control parameter value that is different from the first control parameter value and is used when starting the pump under the second start condition,
The controller determines the value of the control parameter from the value of the second control parameter to the value of the first control parameter when the controller determines that the second start condition is satisfied and the pump is started and then a predetermined return condition is satisfied. The pump apparatus characterized by changing to.   The control parameter includes at least one of a torque boost voltage applied to the motor at the start of the pump, an overcurrent protection level that is a threshold of an overcurrent trip, and a soft start time that is an increase rate of the rotation speed of the motor. The pump device according to claim 1, comprising one.   The pump device according to claim 1, wherein the return condition includes a condition in which the current of the inverter device is equal to or lower than a predetermined current limit level and the pump is operating for a predetermined time or more.   The pump device according to claim 3, wherein the current limit level is set to a value equal to or less than a rated current of the electric motor.   The pump apparatus according to claim 3 or 4, wherein the return condition includes a condition in which the amount of water flowing to the pump is equal to or more than the amount of insufficient water. The control device comprises an input unit for inputting the discharge pressure of the pump,
The first start condition is a start condition for a short stop restart in which the discharge pressure is reduced from a pressure higher than a predetermined start pressure to a value lower than the start pressure. The pump apparatus as described in any one. The control device includes an input unit for inputting a discharge pressure of the pump,
The controller is
Estimating a minimum value of the discharge pressure after starting the pump under the first starting condition, and setting the first control parameter value according to the minimum value;
The pump apparatus according to any one of claims 1 to 6, wherein the pump is started based on the first control parameter value when the first start condition is satisfied. The control device comprises an input unit for inputting the discharge pressure of the pump,
The second start condition is a start condition of a retry operation in which the discharge pressure is equal to or less than a predetermined start pressure after releasing the protection stop for stopping the pump in the stop state as protection of the pump device. The pump apparatus as described in any one of Claims 1-7 characterized by these. The controller is
The number of times the pump is restarted under the second start condition is counted as the number of retries, and
Changing the second control parameter value according to the number of retries;
9. The pump according to claim 1, wherein when the second start condition is satisfied, the pump is started based on the second control parameter value changed according to the number of retries. Description pump device. The controller is
The number of times the pump is started under the second start condition is counted as the number of retries, and
The interval time from when the protective stop of the pump is released until the pump is restarted is changed according to the number of retries,
10. The pump according to claim 1, wherein when the second start condition is satisfied, the pump is started based on the interval time changed according to the number of retries. apparatus.   11. The second start condition includes a condition in which the discharge pressure is equal to or lower than a retry start pressure set to be lower than the start pressure after releasing the protection stop. The pump device according to claim 1. The controller is
The number of times the pump is started under the second start condition is counted as the number of retries, and
The pump device according to any one of claims 1 to 11, wherein the motor is rotated in a direction opposite to a normal rotation direction according to the number of retries.   The control device changes the first control parameter value according to the discharge pressure when the second start condition is satisfied, when the second start condition is satisfied. 13. A pump device according to any one of the preceding claims, characterized in that the pump is started on the basis of.

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