JP4589026B2 - Pump device - Google Patents

Description

  The present invention relates to a pump device, and more particularly, to a pump device that can be started while suppressing a drop in pressure.

  Conventionally, in order to supply water to households, a pump is used to supply water stored in a water receiving tank or well water, and the amount of water supplied or discharge pressure is detected, and the pump is automatically generated based on them. Many automatic water supply devices that stop are used. Such a conventional automatic water supply apparatus is equipped with an inverter device, and this is used as a power source to drive an induction motor to perform constant discharge pressure control (see, for example, Patent Document 1). Furthermore, there has been a pump device that is provided with a pressure tank on the discharge side so that water can be supplied to some extent even when the pump is stopped. Such a pump is started to maintain the pressure when the discharge side pressure drops. Here, the controller that controls the pump device is configured to enable stable control during normal operation.

JP-A-60-142097

  However, in the conventional pump device, starting is performed using a control device capable of stable control during normal operation, but a phenomenon in which the pressure on the discharge side decreases during starting cannot be avoided.

  Then, an object of this invention is to provide the pump apparatus which can be started, suppressing the fall of a pressure.

In order to achieve the above object, a pump device according to the first aspect of the present invention includes, for example, a pump 310 that discharges fluid as shown in FIGS. 1, 2, and 3; a prime mover 210 that drives the pump 310; A controller 230 for controlling the speed of the prime mover 210; the controller 230 sets the acceleration time at the start of the pump 310 to a first acceleration time (1 second in the example of FIG. 1), and sets the acceleration time for normal use A second acceleration time (3 seconds in the example of FIG. 1) that is slower than the first acceleration time is set.

  The prime mover is typically a direct current brushless motor. If comprised in this way, the overshoot at the time of starting can be suppressed, reducing the fall of the pressure at the time of starting.

Further, as in the second aspect , the pump device according to the first aspect may be configured such that the acceleration time is switched from the first acceleration time to the second acceleration time after a predetermined time from the start. .

  Typically, the switching time is shorter than the acceleration time at the start, for example, 90% to 50% thereof.

  With this configuration, the acceleration time is switched from the first acceleration time to the second acceleration time after a predetermined time from the start, so that the switching can be performed by simple control using a timer or the like.

Further, as in the third aspect , in the pump device of the first aspect or the second aspect (see, for example, FIG. 4), the controller 230 is connected to the speed controller unit 13 that controls the speed of the prime mover 210 and the speed controller unit 13. A pressure controller unit 14 that outputs a set speed signal to be input; the pressure controller unit 14 may be configured to control the pressure on the discharge side of the pump 310.

  Typically, the pump device includes a pressure tank for maintaining the pressure on the discharge side while supplying water when the pump is stopped.

Also as in the fourth embodiment, any one of the embodiments of the pump device of the first aspect to the third aspect (see FIG. 4, for example), the motor is a DC brushless motor 210, the controller DC brushless motor 210 The speed controller unit 13 is configured to output a signal for controlling the rotational speed of the DC brushless motor 210, which is input to the DCBL controller 235. Good.

Also as in the fifth embodiment, a pump device according to any one of the embodiments of the first aspect to fourth aspect, the controller 230 adjusts the end pressure of the supply destination of the pressurized fluid at a substantially constant Therefore, it is preferable to have a calculation unit 16 for constant terminal pressure control that calculates the discharge pressure of the pump 310 and inputs the calculation result to the pressure controller unit 14 as a set pressure.

  According to the pump device of the present invention, the pump device includes a pump that discharges fluid, a prime mover that drives the pump, and a controller that controls the speed of the prime mover. The controller sets the acceleration time at the start of the pump to the first acceleration time. Since the normal acceleration time is set to the second acceleration time that is slower than the first acceleration time, it is possible to suppress the overshoot at the start while reducing the pressure drop at the start. .

  Embodiments of the present invention will be described below with reference to the drawings. In addition, in each figure, the same code | symbol is attached | subjected to the mutually same or equivalent member, and the overlapping description is abbreviate | omitted.

  With reference to the acceleration diagram of FIG. 1, the acceleration behavior at the start of the pump device according to the embodiment of the present invention will be described. (A) is an ascending diagram in which the horizontal axis is the elapsed time from the start of the start and the vertical axis is the rotational speed of the pump, and (b) is the elapsed time on the horizontal axis and the vertical axis corresponding to (a). It is an acceleration time diagram which took acceleration time.

  In the pump device of the present embodiment, a DC brushless motor is used as a prime mover. Further, a pressure tank, which will be described in detail later, is provided on the discharge side of the pump. The pressure tank has an action of maintaining the pressure on the discharge side while supplying water to the demand side when the pump is stopped.

  The acceleration time shown in (b) will be described. Here, the case of a system that performs cascade control of a pressure controller that controls the discharge pressure of the pump and a speed controller that controls the speed of the inverter motor for driving the pump will be considered. The pressure controller performs PI (proportional integration) control. In response to the discharge pressure, a speed signal is output from the pressure controller based on the deviation from the set pressure. The speed controller controls the motor using the speed of the speed signal as a set value. Since the pressure controller performs PI control, as long as there is a deviation between the set pressure and the actual pressure, the speed signal becomes larger (in the case of starting).

  This rate of increase of the speed signal is called a slew rate. An upper limit is set for this slew rate. For example, the slew rate at start-up is 3000 revolutions / minute / second (speed 0-100% is 1 second), and that during normal operation is 1000 revolutions / minute / second (speed 0-100% is 3 seconds). To do. There are upper limits due to the torque of the motor, the moment of inertia of the impeller / motor rotor of the pump, and fluid resistance, but in small pumps the upper limits are far greater than 3000 revolutions / minute / second. Accordingly, the acceleration time is governed by the slew rate.

  When the rotation speed of all speeds is 3000 revolutions / minute, if the slew rate is 3000 revolutions / minute / second, the so-called acceleration time is 1 second, and if it is 1000 revolutions / minute / second, the acceleration time is 3 seconds. The former is said to accelerate faster than the latter, or the acceleration time is shorter.

  In the example of FIG. 1, the slew rate at the start is 3000 rpm / min / sec (acceleration time is 1 sec as the first acceleration time), and the slew rate at regular operation is 1000 rpm / min / sec ( The acceleration time is 3 seconds as the second acceleration time), and the former is switched to the latter 0.5 seconds (sec) from the start of the start. For the switching time, a clock (clock function) in the controller may be used as a timer. The timer starts when the start starts.

  If the slew rate is 1000 revolutions / minute / second (acceleration time 3 seconds), the control during normal operation is sufficiently stable. Further, since the slew rate at the start of the start is 3000 revolutions / minute / second (acceleration time 1 second), the discharge pressure of the pump immediately rises, and the pressure drop on the discharge side can be suppressed.

  The first acceleration time is 1.5 times the acceleration time (acceleration speed (hereinafter the same)) or more (the number of seconds of the acceleration time is 1 / 1.5 times or less (the same applies below)). Preferably it is 2.0 times or more, More preferably, it is 3.0 times or more. Moreover, it is good to make it 6.0 times or less (the number of seconds of acceleration time is 1 / 6.0 times or more (the same applies hereinafter)). If the multiple is too large, the balance between the control response speed during normal operation and the ascending speed during start-up becomes poor. Preferably it is 5.5 times or less, More preferably, it is 5.0 times or less. The magnification is set in advance in consideration of the capacity of the pressure tank, the maximum supply flow rate to the water demand destination, the fluctuation range of the supply flow rate, etc., or the controller is configured so that it can be set on site. The second acceleration time is preferably 5 seconds or less. When this is long, the responsiveness is deteriorated and the usability is deteriorated.

  The switching time is shorter than the acceleration time at the start (first acceleration time: 1 second), for example, 50% to 90% of the time (if the acceleration time at the start is 1 second, the predetermined switching time is 0. 5 to 0.9 seconds).

If it is 50% or more, the pressure drop can be minimized. Preferably, it is 60% or more. More preferably, if it is 70% or more, the drop in pressure can be suppressed to such an extent that it can be practically used.
Moreover, it is good to set it as 90% or less. If this ratio is increased too much, the rotational speed may exceed the normal value at the time of starting, and the speed may overshoot. Preferably it is 80% or less. When there is a range in the normal rotation speed, the minimum normal rotation speed is used as a reference.

  When the pump is controlled by setting in this way, it is possible to suppress the overshoot of the rotational speed at the start, while reducing the pressure drop on the discharge side at the start.

  With reference to the top view (a) and partial sectional front view (b) of FIG. 2, the water supply apparatus 201 as a pump apparatus of embodiment of this invention is demonstrated. In the present embodiment, a cascade pump 310 is provided as a pump. The cascade pump is a pump also called a friction pump, and includes an impeller 311 formed as a disk having a large number of grooves formed on the periphery. Although this pump is small in size, a single impeller can obtain a lift comparable to several stages of centrifugal pumps, and is suitable for the purpose of a small capacity and high lift. Moreover, since it has a self-absorbing property, it is suitable for supplying water or well water stored in a water receiving tank to supply water to the home. The impeller 311 is housed in the pump casing 312. A pump casing cover 313 is attached with bolts to the front of the pump casing 312 as viewed from the impeller shaft direction. When the pump casing cover 313 is removed, the impeller 311 can be accessed to facilitate maintenance and inspection.

  The automatic water supply apparatus 201 includes an electric motor 210 that drives the pump 310. The pump 310 includes an inverter device 230 so that the discharge pressure can be controlled by performing variable speed operation. The inverter device 230 is arranged in the vicinity of the electric motor 210.

  A check valve 321 is disposed in the flow path between the pump suction port 326 and the impeller 313. From the viewpoint of maintaining the pressure on the discharge side, the check valve 321 is not limited to the above position, and may be upstream of the pressure tank 322 mounting position of the discharge pipe 325. However, it is preferable to provide the pump 310 on the suction side from the viewpoint of holding the expiration water.

  A steam / water separation chamber 112 is provided downstream of the impeller 311, a flow switch 324 is disposed downstream of the steam / water separation chamber 112, and a pressure detector (pressure sensor) (pressure transmitter) 323 is disposed in the vicinity thereof. ing. The flow switch 324 and the pressure sensor 323 are disposed in a discharge pipe 325 provided downstream of the steam / water separation chamber 112. A discharge port 327 of the pump device is provided downstream of the discharge pipe 325. A pressure tank 322 is connected to the discharge pipe 325. An expelling tap 328 is provided in the upper part of the pressure tank 322 in the vertical direction. The pressure tank 322 is provided on the discharge side of the pump 310 and on the downstream side of the flow switch 324.

  The above components, the pump 310, the electric motor 210, the inverter device 230, and the pressure tank 322 are placed on the unit base 332 and fixed with bolts, and are compactly assembled as a whole. Further, a resin unit cover 331 is provided to cover the entire apparatus. The unit cover 331 is formed with openings 331a and 331b that are accessible from the outside to the suction port 326 and the discharge port 327 of the pump 310, respectively. The unit cover 331 and the unit base 332 substantially seal the entire component device. Covering. Therefore, the components can be protected from wind and rain, and a high soundproofing effect is provided.

  An antifreeze heater 333 is attached to the outside of the pump casing 313, substantially outside the air / water separation chamber, and an antifreeze heater 334 is attached to the outside of the discharge pipe 325, respectively.

  With reference to the flow sheet of FIG. 3, the arrangement and operation according to the flow of water will be described for each component of the water supply device 201 as a pump device. Here, the water supply apparatus 201 is an automatic water supply apparatus, and automatically starts and stops the pump 310 according to the amount of water used, and automatically changes the operation speed.

  In FIG. 3, water W is accumulated up to level L in the well Well dug from the ground S. The automatic water supply apparatus 201 is installed on the ground S close to the well Well.

  The suction pipe 309 is connected to the suction port 326 of the pump 310 of the water supply apparatus 201. The sucked water is sucked into the impeller 311 of the pump 310 through the check valve 321. The check valve 321 is a check valve that prevents water from flowing back to the well Well when the pump 310 is stopped. Since the pump 310 is a cascade pump, even if there is air in the suction pipe 309 at the start, it can be discharged to suck up the water W. However, since the check valve 321 is provided, There is no need to expel the air.

  The flow switch 324 detects the amount of water discharged from the pump 310, transmits the detection result to the inverter device 230, and starts and stops the electric motor 210. The pressure sensor 323 detects the discharge pressure of the pump 310 and transmits the detection result to the microcomputer 11 in the inverter device 230.

  The pressure tank 322 provided in the discharge pipe 325 has a rubber bladder built in the pressure vessel, and when the pressure on the discharge side rises, the air outside the bladder is compressed and water is stored in a pressurized state. . Further, as the pressure on the discharge side decreases, the compressed air expands and pushes the stored water to the discharge pipe 325. In this way, even if the pump 310 is stopped, water is supplied from the pressure tank 322 to the discharge pipe 325 for a while.

  With reference to the flowchart of FIG. 4, it demonstrates per control apparatus and effect | action of a water supply apparatus of this Embodiment. In the figure, the signal indicated by (D) in the signal line is a digital signal, and the signal indicated by (A) is an analog signal. The inverter device 230 (indicated by a two-dot chain line) includes an IPM (Intelligent Power Module) 232 that supplies driving power to a DC brushless motor 210 as an electric motor, a DCBL controller 235 that controls the IPM 232, and a microcomputer 11 that controls the DCBL controller 235.

  The microcomputer 11 includes a CPU 12, a memory 17 that stores a program used by the CPU 12, and an I / O (input / output interface) 18 that receives an input signal from the outside and outputs a signal to the outside.

  Since the pressure tank 322 is installed on the downstream side of the flow switch 324, the flow switch 324 does not detect the water flow supplied from the pressure tank 322 when the pump 310 is stopped.

  The IPM 232 receives the feedback of the magnetic pole signal from the DC brushless motor 210, synchronizes the frequency of the driving power with the rotational speed of the DC brushless motor 210, and forms a rotating magnetic field in the stator of the motor 210.

  The DCBL (direct current brushless) controller 235 transmits a PWM waveform signal to the IPM 232. The IPM 232 supplies power corresponding to the signal (with the same waveform) to the DC brushless motor 210.

  A pressure signal from the pressure sensor 323 is input to the pressure controller unit 14, and the pressure controller unit 14 sends a speed set value to the speed controller unit 13. The speed controller unit 13 receives feedback of the rotation speed of the motor 210 and outputs a control signal (voltage signal Ve) corresponding to the difference between the set speed and the actual operation speed to the DCBL controller 235.

  The IPM 232 supplies driving power to the electric motor 210 as described above. The IPM 232 receives the PWM drive waveform signal from the DCBL (direct current brushless) controller 235 and generates power having the same waveform as the signal waveform. It is an amplifier. The IPM 232 has a built-in power transistor, and an on / off signal is input to its gate, and the same on / off power as that signal is output. The power transistor performs a so-called switching operation.

  The brushless DC motor 210 used in the present embodiment includes a rotor incorporating a permanent magnet and a stator that includes a coil and forms a rotating magnetic field. The structure itself which consists of a rotor and a rotor is the same structure as an AC synchronous motor. However, it differs from an AC synchronous motor in that a magnetic pole signal is transmitted to the DCBL controller 235.

  The DCBL controller 235 transmits an on / off DC signal to the IPM 232. The generation cycle of on and off is constant, and the duration of on is wide. The width of ON / OFF is repeated at a predetermined cycle. The ratio of the duration width is called the duty ratio. The DCBL controller 235 changes the duty ratio according to the voltage signal Ve (0 to 5 volts) input from the speed controller unit 13. When Ve is high, the duty ratio is changed so that the overall width becomes large.

  Furthermore, with reference to FIG. 4, the control apparatus and effect | action of the water supply apparatus of this Embodiment are demonstrated. The IPM 232 causes the power transistor to perform a switching operation at the same cycle as the on / off signal from the DCBL controller 235. As a result, DC power having a constant voltage can be obtained in which the ON / OFF generation cycle is constant, the ON duration is wide, and the ON / OFF width is repeated periodically. Although it is a direct current, the effective value is low at a portion where the time width is narrow, and the high value is high at a wide portion, and the power is equivalent to AC power having a predetermined cycle as a whole.

  Further, when the signal voltage Ve is high, the time width is widened as a whole, so that the overall effective value when viewed as AC power is high. In this way, the rotational speed is maintained even when the load on the pump 310 increases.

  The DCBL controller 235 receives the voltage signal Ve from the speed controller unit 13 in the CPU 12. The voltage signal Ve is a digital signal when output from the CPU 12, but is converted into an analog signal (0 to 5 V) by a D / A (digital-analog converter) 20 provided in the middle and input to the DCBL controller 235. To do. The CPU 12 has an IC structure. The duty ratio determined by the voltage signal Ve is determined by one set for one period instead of one wide and narrow width.

  On the other hand, the DCBL controller 235 receives the feedback of the magnetic pole signal from the electric motor 210 and adjusts the period T of the PWM drive waveform signal that is an output signal. This is because if the rotational speed of the rotor 210a of the electric motor 210 is not equal to the rotational speed of the rotating magnetic field of the stator 210b, so-called step-out occurs.

  For example, when the load of the pump 310 increases and the rotation of the rotor of the motor decreases, it is fed back to the DCBL controller 235, and the rotation speed of the rotating magnetic field of the stator also decreases. At this time, since the pump discharge pressure is reduced, the pressure controller unit 14 and the speed controller unit 13 work to increase the voltage signal Ve. As described above, the effective voltage of the driving power from the IPM 232 increases, and the motor The output of 210 increases, the rotational speed of the pump 310 is maintained, and the discharge pressure is maintained.

  The period of the PWM drive waveform, which is the output of the DCBL controller 235, is variable, that is, the frequency is variable, and the rotational speed of the electric motor 210 is variable, so that an appropriate discharge pressure is obtained according to the flow rate of the pump 310. Control becomes possible.

  The CPU 12 includes a speed controller unit 13, a pressure controller unit 14, and an estimated terminal pressure constant control calculation unit 15. Further, an automatic start / stop control portion 16 is also included. The estimated terminal pressure constant control will be described with reference to another drawing.

  A set speed signal (digital signal) from the pressure controller unit 14 is input to the speed controller unit 13. The digital speed signal output from the DCBL controller 235 is fed back. The digital speed signal here is a pulse output with the number of pulses per time proportional to the number of revolutions.

  The speed controller unit 13 performs PI (proportional integration) control so that the difference between the set speed from the pressure controller unit 14 and the fed back speed becomes zero. A set speed signal from the pressure controller unit 14 is input to the speed controller unit 13. An analog pressure signal from the pressure transmitter 323 that has detected the discharge pressure of the pump 310 is converted into a digital signal by the A / D converter 19 and input to the pressure controller unit 14. On the other hand, a set pressure signal (digital signal) is input from the estimated terminal pressure constant control calculation unit 15.

  The pressure controller unit 14 adjusts the set speed signal so that the discharge pressure of the pump 310 becomes the set pressure based on the set pressure signal. That is, when the pump discharge pressure decreases, the set speed is adjusted to increase. This is also PI control.

  In the present embodiment, the output of the pressure controller unit is used as the set rotational speed of the speed controller unit 13. The slew rate as the upper limit of the speed of increase (acceleration time) of the output of the pressure controller is configured to be set in at least two stages as described above.

  Further, since the speed controller unit 13 is provided, it is possible to set so as to suppress the upper limit of the maximum rotation speed of the pump 310. That is, control for preventing overspeed is possible.

  Further, since the speed controller unit 13 is provided, the set speed signal input thereto can be used as a rotation speed signal used in the calculation unit for the estimated terminal pressure constant control. Note that the speed signal from the DCBL controller 235 may be used for the above purpose. The calculation unit 15 for the estimated terminal pressure constant control will be described later.

The CPU 12 has an automatic start / stop control unit 16, receives an automatic start / stop signal from the outside, and transmits a stop signal to the speed controller unit 13 and the DCBL controller 235.
There are two main types of automatic start / stop:
(1) Switching between operation and stop based on flow rate and pressure (automatic start / stop during normal operation)
(2) Stop for protection in case of abnormality and restart operation by retry (automatic start / stop in case of abnormality)
In the case of (1), the start / stop signal to the DCBL controller 235 remains in the operating state. When stopping, only Ve = 0 is set, and the start / stop signal does not change from the operating state.
In the case of (2), in some protections (for example, an IPM 232 error), the start / stop signal to the DCBL controller 235 is stopped and Ve = 0, but in other protections, Ve = 0. Just do it.

  When the digital signal input to the CPU 12 is an on / off signal from the flow switch 324, the start / stop is determined by the CPU 12 in combination with, for example, a pressure signal separately taken into the CPU 12.

  Further, when the automatic start / stop signal is related to, for example, the motor temperature, the signal taken into the CPU 12 is a temperature signal, and the automatic start / stop control unit 16 stores the upper limit value. Determine whether or not, and send a stop signal if necessary.

  The CPU 12 is a core component of the microcomputer. A program for the CPU 12 to calculate is stored in the memory 17 in the microcomputer 11.

  As described above, the CPU 12 includes the pressure controller unit 14, the speed controller unit 13, the estimated terminal pressure constant control calculation unit 15, and the automatic start / stop control unit 16, and the control program and calculation stored in the memory 17. Arithmetic processing is performed by the program. The DCBL controller 235 is composed of an IC and receives various information signals.

  The estimated terminal pressure constant control will be described with reference to the pump operation characteristic curve diagram of FIG. The horizontal axis is the amount of water, the vertical axis is the head, that is, the head (hereinafter also referred to as “pressure” as appropriate), and the curve Hzx is the operation characteristic with a constant pump rotational speed. Here, the resistance curve R is a pipe loss corresponding to the amount of water used from the pump 310 to the end of the demand destination, and is a curve proportional to the square of the amount of water used when the point where the water amount Q is 0 is the origin. . Therefore, in order to control the pressure on the discharge side of the pump 310 at a constant level, the rotational speed of the pump may be controlled between Hzo and Hzb ′ so that the pressure Pb at the demand end is constant. When such control is performed, the pressure at the end becomes more than necessary at the minimum flow rate. On the other hand, in the estimated terminal pressure constant control, it is necessary to allow for the pipe loss (indicated by the resistance curve R) according to the amount of water used. To do. At an intermediate flow rate, operation is performed at an intermediate rotational speed Hza. The discharge pressure of the pump changes along the resistance curve R.

  The estimated terminal pressure constant control calculation unit 15 described above calculates a set pressure f (N) that rides on the resistance curve R according to the rotational speed N of the pump 310 and calculates the set value f (N). Is given to the pressure controller section 14 as a set value.

  The automatic water supply apparatus 201 sets a lower limit of the amount of water used, and when the flow switch 324 detects the lower limit value, the microcomputer 11 operates to stop the electric motor 210 and thus the pump 310. After that, when water is used, water is supplied from the pressure tank 322 for a while. When the water in the pressure tank 322 decreases and the pressure further decreases, the pressure sensor 323 detects this, and the microcomputer 11 detects the electric motor. 210 is started.

  At this time, when the amount of water decreases and the electric motor 210 is stopped, the discharge pressure is increased by temporarily increasing the operation speed of the pump so that sufficient water is stored in the pressure tank 322. . The pump 310 may be stopped due to a decrease in the water flow rate based on the lower limit value of the rotation speed without depending on the flow switch 323.

  The pump device of the present invention is not limited to the embodiment described above, and is not limited to the illustrated examples, and various modifications can be made without departing from the scope of the present invention. Needless to say.

It is a speed-up diagram of the water supply apparatus by embodiment of this invention. It is the top view and front view of the water supply apparatus by embodiment of this invention. It is a flowchart explaining the water supply apparatus by embodiment of this invention. It is a flowchart explaining about the control apparatus and effect | action of a water supply apparatus by embodiment of this invention. It is a driving | operation characteristic figure of a pump explaining estimation terminal pressure fixed control.

Explanation of symbols

11 Microcomputer 12 CPU
13 Speed controller section 14 Pressure controller section 15 Estimated terminal pressure constant control calculation section 16 Automatic start / stop control section 17 Memory 18 I / O
19 A / D
20 D / A
DESCRIPTION OF SYMBOLS 201 Water supply apparatus 210 Electric motor 211 Electric motor main body 230 Inverter apparatus 232 IPM element 309 Suction pipe 310 Pump 311 Impeller 312 Pump casing 313 Pump casing cover 321 Check valve 322 Pressure tank 323 Pressure sensor 324 Flow switch 325 Discharge pipe 326 Suction opening 327 Discharge opening 328 Expiration tap 331 Unit cover 331a Unit cover opening (suction side)
331b Unit cover opening (discharge side)
332 Unit base 333, 334 Antifreeze heater L Level S Ground W Water Well Well

Claims (5)

A pump for discharging fluid;
A prime mover driving the pump;
A controller for controlling the speed of the prime mover;
The controller sets the acceleration time at the start of the pump to a first acceleration time, sets the acceleration time for normal use to a second acceleration time that is slower than the first acceleration time, and a predetermined time after the start the first configured to switch to the second acceleration time from acceleration time, a predetermined time from the start was set to 90% of the time 50% of the first acceleration time;
Pump device. 2. The pump device according to claim 1, wherein the predetermined time from the start is configured to use a clock in the controller as a timer and to start the timer when the pump starts. The controller includes a speed controller unit that controls a speed of the prime mover and a pressure controller unit that outputs a set speed signal input to the speed controller unit;
The pressure controller portion is configured to control the pressure on the discharge side of the pump;
The pump device according to claim 1 or 2.   The prime mover is a DC brushless motor, the controller has a DCBL controller that controls driving power supplied to the DC brushless motor, and the speed controller unit inputs the DC brushless motor to the DCBL controller. The pump device according to any one of claims 1 to 3, wherein the pump device is configured to output a signal for controlling a rotation speed of the electric motor.   The controller calculates the discharge pressure of the pump for adjusting the terminal pressure of the supply destination of the boosted fluid to be substantially constant, and inputs the calculation result as a set pressure to the pressure controller unit. The pump device according to any one of claims 1 to 4, further comprising a constant control arithmetic unit.

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