JP6502972B2 - Fluid supply device - Google Patents

Description

  The present invention relates to a fluid supply device.

  BACKGROUND Conventionally, a fluid supply device has been used which transports a liquid such as water or various gases by a pump and supplies the liquid to a demand source. As an example of the fluid supply device, there is a water supply device that pumps water to be supplied to a high place of a building such as a building or an apartment.

  In recent years, there is a growing awareness that it is important to secure water supply even in the event of a power failure due to the occurrence of a large-scale power failure due to the earthquake. Then, although an in-house power generation facility is introduced and a water supply apparatus is driven by an in-house power generation facility at the time of a power failure, driving a water supply system for a long time is required at the time of a power failure. In this regard, the prior art describes a water supply apparatus that performs energy saving operation while securing a constant flow rate.

International Publication Number 2012/099242

  However, the prior art does not take into consideration the energy saving operation of the water supply device when power is supplied from the power storage device.

  That is, in recent years, instead of providing an in-house power generation facility, there is an increasing number of cases where an electricity storage device (storage battery) cheaper than the in-house power generation facility is installed and the water supply device is driven by power supply from the electricity storage device at power failure.

  By using a storage device, water can be supplied even at the time of a power failure, but since the time until power recovery is unclear at the time of a power failure, it is desirable to be able to operate the power supply device for as long as possible. . For example, in order to realize long-time operation by power feeding from the storage device, it is conceivable to increase the capacity of the storage device, but with this, the storage device becomes expensive, so the operation mode on the water supply device side It is required to devise

Then, this invention makes it a subject to implement | achieve the fluid supply apparatus which can lengthen the operating time by the electric power supplied from an electrical storage apparatus.

  The fluid supply device according to the present invention has been made in view of the above problems, and includes a pump for transporting a fluid, a drive unit for driving the pump, and a first power or the first power supplied from a commercial power source. And a control unit configured to control driving of the pump via the power unit.

  When the power supplied to the power unit switches from the first power to the second power, the control unit consumes power of the drive unit when the pump is driven by the second power, The power unit is controlled to be smaller than the power consumption of the drive unit when the pump is driven by the first power.

  Further, when the power supplied to the power unit is switched from the first power to the second power, the control unit sets the set pressure of the pump when the pump is driven by the second power. The power unit can be controlled to be smaller than a set pressure of the pump when driving the pump by the first electric power.

  In addition, when the power unit includes an inverter that converts the first power or the second power into a predetermined frequency and supplies the predetermined frequency to the drive unit, the control unit is configured to supply the power supplied to the inverter to the inverter. When switching from the first power to the second power, the acceleration / deceleration time of the pump drive frequency of the inverter when driving the pump by the second power drives the pump by the first power The inverter can be controlled to be longer than the acceleration / deceleration time of the pump drive frequency of the inverter at that time.

  Further, when the plurality of pumps and the driving unit are operated when the first power is supplied to the power unit, the control unit is configured to control the power supplied to the power unit from the first power. When the power is switched to the second power, the number of operating the pump and the driving unit by the second power may be smaller than the number of operating the pump and the driving unit by the first power. Controlling the power unit.

  Further, the control unit causes the power unit to be set so that the set pressure of the pump at the time of driving the pump by the second electric power decreases stepwise in response to a decrease in the remaining charge amount of the power storage device. Can control.

  In addition, the control unit may be configured such that, in response to a decrease in voltage supplied from the power storage device, the power unit causes the set pressure of the pump at the time of driving the pump to be lowered by the second power. Can be controlled.

  Further, the control unit controls the power unit such that the set pressure of the pump at the time of driving the pump by the second electric power decreases stepwise in response to an increase in the temperature of the power storage device. ,be able to.

  Further, the control unit has a timer function of measuring an operation time by the second power, and the pump at the time of driving the pump by the second power according to the operation time by the second power. The power unit can be controlled such that the set pressure of the valve gradually decreases.

  When the power unit includes an input terminal for receiving AC power output from the storage device, the power unit converts the AC power received via the input terminal into a predetermined frequency and supplies the frequency to the drive unit. It can be done.

  In addition, when the power unit includes an inverter that converts the first power or the second power into a predetermined frequency and supplies the predetermined frequency to the drive unit, the control unit is configured to supply the power supplied to the inverter to the inverter. When switching from the first power to the second power, the carrier frequency of the inverter at the time of driving the pump by the second power is the carrier frequency of the inverter at the time of driving the pump by the first power. The inverter can be controlled to be lower than the carrier frequency.

  In addition, the control unit causes the display unit to display an indication that the pump is driven by the power supplied from the storage device when the power supplied to the power unit is switched from the first power to the second power. Can be displayed.

  The power supply unit may further include an input terminal for receiving an operation signal indicating that the power supplied to the power unit is switched from the first power to the second power.

  Further, in the state where the second power is supplied to the power unit, the control unit puts the device including the display unit in the fluid supply device into the sleep state when there is no request to drive the pump. Can control.

  In addition, when the power unit includes an inverter that converts the first power or the second power into a predetermined frequency and supplies the frequency to the drive unit, an input terminal that receives DC power output from the power storage device. The inverter may convert DC power received via the input terminal into AC power of a predetermined frequency and supply the AC power to the drive unit.

  Further, according to the fluid supply device of the present invention, a pump for transferring fluid, a drive unit for driving the pump, and a first power supplied from a commercial power source or a second power supplied from a storage device are driven. When the power unit includes an inverter that converts the first power or the second power into a predetermined frequency and supplies the power to the drive unit, the power output from the power storage device And the inverter converts the DC power received through the input terminal into AC power of a predetermined frequency and supplies the AC power to the drive unit.

  According to the invention of the present application, it is possible to realize a fluid supply device capable of extending the operation time by the power supplied from the power storage device.

FIG. 1 is a diagram showing a configuration of a water supply system including the water supply apparatus of the first embodiment. FIG. 2 is a diagram showing an operation control flow by the control unit. FIG. 3 is a diagram showing the power consumption with respect to the set pressure of the motor pump. FIG. 4 is a diagram showing the power consumption with respect to the acceleration / deceleration time of the pump drive frequency of the AC inverter. FIG. 5 is a diagram showing another example of the operation control flow by the control unit. FIG. 6 is a schematic view of an alternating current inverter. FIG. 7 is a diagram showing another example of the operation control flow by the control unit. FIG. 8 is a diagram showing a configuration of a water supply system including the water supply apparatus of the second embodiment.

  Hereinafter, a fluid supply device according to an embodiment of the present invention will be described based on the drawings. Although the following embodiment describes a water supply apparatus as an example, it is not restricted to this.

First Embodiment
FIG. 1 is a diagram showing a configuration of a water supply system including the water supply apparatus of the first embodiment. As shown in FIG. 1, the water supply system 100 of the first embodiment includes a power storage device 200 and a water supply device 300.

Power storage device 200 receives commercial power (first power) supplied from commercial power source 290. Power storage device 200 temporarily converts the input from commercial power source 290 into direct current power, stores it in power storage unit 210 (battery), and outputs it by bypassing a circuit that produces and outputs alternating current power by an inverter and a normal commercial power source. And a circuit to Specifically, power storage device 200 includes power storage unit 210, alternating current inverter 220, control unit 230, direct current inverter 240, and switch 250.

  The DC conversion inverter 240 is an inverter that converts received commercial power into DC power, and supplies the converted DC power to the storage unit 210. Power storage unit 210 is a storage battery for storing direct current power supplied from direct current inverter 240.

  The alternating current inverter 220 is an inverter that converts direct current power output from the storage unit 210 into alternating current power. Switch 250 selects one of commercial power (first power) supplied from commercial power supply 290 and AC power (second power supplied from power storage unit 210) output from AC inverter 220. Output to the water supply device 300. For example, in the normal state where commercial power is supplied from commercial power supply 290, switch 250 selects and outputs the AC power supplied from commercial power supply 290, and at the time of a power failure where commercial power is not supplied from commercial power supply 290 The AC power output from the conversion inverter 220 is selected and output.

  When a power failure occurs, control unit 230 switches the switch 250 to switch the circuit that has supplied the commercial power by bypass to the storage side and continues the power supply by controlling the switching of the power supply. . In addition, control unit 230 changes the power supply from the first power to the second power, or from the second power to the first power, or the state of power storage unit 210 (for example, the remaining amount of power). Output the control signal shown to the external device. Note that power supply to control unit 230 can be performed, for example, from power storage unit 210.

  Next, the water supply device 300 includes motor pumps 310-1 and 310-2, a power unit 320, a control unit 330, a pressure sensor 340, and a display unit 350. The water supply device 300 pumps water from a water storage tank or the like through a pipe provided on the suction side, and transfers the water to the consumer side through a pipe provided on the discharge side. Moreover, the water supply apparatus 300 is provided with the apparatus required for control, such as a check valve and a pressure tank which are not illustrated, in piping by the side of discharge.

  In the present embodiment, a motor pump 310 in which a pump for transferring a fluid such as water and a motor (drive unit) for driving the pump are integrated is described as an example, but the present invention is not limited thereto. The motor may be separate from the motor. In the following description, when one or both of the two motor pumps 310-1 and 310-2 are not specified, the motor pump 310 will be described.

  Power unit 320 supplies to motor pump 310 commercial power (first power) supplied from commercial power supply 290 via switch 250 or second power supplied from power storage unit 210 via switch 250. . Specifically, the power unit 320 includes a direct current inverter 322 and an alternating current inverter 324.

  The DC conversion inverter 322 is an inverter that converts the first power or the second power supplied from the power storage device 200 via the input terminal for receiving AC power for the water supply device 300 into predetermined DC power. The generated DC power is output to the AC inverter 324.

  The alternating current inverter 324 converts the direct current power supplied from the direct current inverter 322 into alternating current power of a predetermined frequency, and supplies the alternating current power to the motor pump 310. The motor pump 310 is driven at a rotational speed corresponding to the frequency of the power supplied from the alternating current inverter 324.

The pressure sensor 340 is provided on the discharge side pipe of the motor pump 310, and measures the pressure on the discharge side of the motor pump 310. The pressure value measured by the pressure sensor 340 is
It is output to the control unit 330. The water supply apparatus 300 is configured to supply water at an appropriate pressure to the consumer side by detecting the discharge pressure mainly by the signal of the pressure sensor 340 and outputting a control signal from the control unit 330 to the power unit 320. It is done. In addition, when the water supply apparatus 300 equips the suction side of the motor pump 310 with a water receiving tank, detection of the water level from a water level detector also becomes unnecessary at the time of driving | operation by the electrical storage apparatus 200. However, in order to change the pressure setting value, the signal from the pressure sensor 340 is continuously output to the control unit 330 regardless of the type of the power supply.

  The display unit 350 is a display that displays various information related to the water supply device 300. For example, when the power supplied to power unit 320 is switched from the first power to the second power, display unit 350 displays that motor pump 310 is driven with the power supplied from power storage device 200. In addition, for example, during operation by the power storage device 200, the display unit 350 can also display a signal during water supply device operation by the power storage device 200 alone without passing through the control unit 330 of the water supply device 300. Power saving can be further achieved if it is not necessary to display the driving state of the vehicle. In the state where the second power is supplied to the power unit 320, the control unit 330 sleeps the device such as the display unit 350 in the water supply apparatus 300 when there is no request to drive the motor pump 310. Power control can be achieved.

  The control unit 330 controls the drive of the motor pump 310 via the power unit 320. Specifically, the control unit 330 receives, from the control unit 230, for example, a control signal indicating that the power supply has switched from the first power to the second power due to a power failure. When the power supplied to power unit 320 is switched from the first power to the second power (when control unit 330 determines that the first power is switched to the second power based on the input control signal) The motor pump 310 is operated in the power failure operation mode. That is, the control unit 330 causes the power consumption of the motor pump 310 (power consumption of the drive unit for driving the motor) when driving the motor pump 310 by the second power to drive the motor pump 310 by the first power. The power unit 320 is controlled to be smaller than the power consumption of the motor pump 310 (power consumption of the drive unit for driving the motor).

  Here, the operation control flow by the control unit 330 will be described. FIG. 2 is a diagram showing an operation control flow by the control unit. As shown in FIG. 2, first, the control unit 330 operates the motor pump 310 in the normal operation mode (step S101). That is, the control unit 330 controls the power unit 320 to drive the motor pump 310 with various setting values of the motor pump 310 in the normal operation mode set in advance in the control unit 330.

  Subsequently, control unit 330 determines whether or not the power supplied to power unit 320 is the power (second power) stored in power storage unit 210 (step S102). Specifically, based on the control signal input from control unit 230, control unit 330 determines whether or not the second power is supplied.

  If control unit 330 determines that the power supplied to power unit 320 is not the power (second power) stored in power storage unit 210 (step S102, No), it returns to step S101 and continues the normal operation. Do.

  On the other hand, when control unit 330 determines that the power supplied to power unit 320 is the power (second power) stored in power storage unit 210 (Yes in step S102), motor pump 310 is operated in the power failure operation mode. It drives (step S103). That is, the control unit 330 controls the power unit 320 to drive the motor pump 310 with various setting values of the motor pump 310 in the operation mode at the time of a power failure, which is set in advance in the control unit 330. Details of this point will be described later.

  Subsequently, the control unit 330 determines whether the power supply to the power unit 320 is commercial power (first power) (step S104). Specifically, based on the control signal input from control unit 230, control unit 330 determines whether or not the first power is supplied.

  If it is determined that the power supply to the power unit 320 is not commercial power (first power) (step S104, No), the control unit 330 returns to step S103 and continues the operation at the time of the power failure.

  On the other hand, when control unit 330 determines that the power supply to power unit 320 is commercial power (first power) (step S104, Yes), it returns to step S101, and operates motor pump 310 in the normal operation mode. Do.

  As described above, by changing the control method of the water supply device 300 at the time of power failure and operating it, the power required to drive the water supply device 300 at the time of power failure can be reduced. The operating time of the device 300 can be extended. Hereinafter, details of the control mode by the control unit 330 will be described.

(First control mode)
When the power supplied to the power unit 320 is switched from the first power to the second power, the control unit 330 sets the pressure (discharge pressure) of the motor pump 310 when driving the motor pump 310 by the second power. However, the power unit 320 is controlled so as to be smaller than the set pressure (discharge pressure) of the motor pump 310 when driving the motor pump 310 by the first electric power.

  This point will be described with reference to FIG. FIG. 3 is a diagram showing the power consumption with respect to the set pressure of the motor pump. In the upper drawing of FIG. 3, the horizontal axis indicates the flow rate Q, and the vertical axis indicates the head (head) H. In the lower part of FIG. 3, the horizontal axis represents the flow rate Q, and the vertical axis represents the output (power consumption) P of the motor pump.

  The upper diagram in FIG. 3 shows the QH curve 402 at the rotational speed of the motor pump 310 at normal times and the power supplied to the power unit 320 due to a power failure or the like after switching from the first power to the second power. The QH curve 404 in the rotational speed of the motor pump 310 is shown.

  When the power supplied to the power unit 320 is switched from the first power to the second power due to a power failure or the like, the control unit 330 reduces the pump drive frequency in the alternating current inverter 324 of the power unit 320 to reduce Reduce the rotation speed. Thereby, the QH curve of the motor pump 310 changes from the QH curve 402 to the QH curve 404.

  As shown in FIG. 3, the head H for obtaining a predetermined flow rate Q 1 is H 2 in the QH curve 402, and H 1 (<H 2) in the QH curve 404. Normally, the head H1 is set with allowance in consideration of the pressure loss of piping etc. in addition to the height for pumping up water, but at power failure, the head H2 is set with the allowance reduced. In other words, when the power supplied to the power unit 320 is switched from the first power to the second power due to a power failure or the like, the control unit 330 sets the motor pump 310 more than the set pressure of the motor pump 310 at the normal time. It is to reduce the pressure.

  The lower part of FIG. 3 shows an output graph 406 for the drive of the motor pump 310 at normal times and the motor pump 310 after the power supplied to the power unit 320 is switched from the first power to the second power due to a power failure or the like. An output graph 408 at rotational speed is shown.

  As shown in the lower diagram of FIG. 3, the output for obtaining the predetermined flow rate Q1 is P2 under normal conditions, and the power supplied to the power unit 320 is switched from the first power to the second power due to a power failure or the like. The output for obtaining a predetermined flow rate Q1 is P1 (<P2). Therefore, the set pressure of the motor pump 310 after the power supplied to the power unit 320 is switched from the first power to the second power due to a power failure or the like is smaller than the set pressure of the motor pump 310 at the normal time. Thus, the power consumption of the motor pump 310 can be reduced by ΔP. As a result, the operation time of water supply device 300 by the power supplied from power storage device 200 can be extended.

(Second control mode)
When the power supplied to power unit 320 (AC inverter 324) is switched from the first power to the second power, control unit 330 causes AC inverter 324 to drive motor pump 310 with the second power. Power unit 320 (AC inverter 324 so that the acceleration / deceleration time of the pump drive frequency is longer than the pump drive frequency acceleration / deceleration time of AC drive inverter 324 when driving motor pump 310 with the first power. Control).

  This point will be described with reference to FIG. FIG. 4 is a diagram showing the power consumption with respect to the acceleration / deceleration time of the pump drive frequency of the AC inverter. In the upper view of FIG. 4, the horizontal axis indicates the passage of time, and the vertical axis indicates the rotational speed of the motor pump 310. Further, in the lower part of FIG. 4, the horizontal axis indicates the passage of time, and the vertical axis indicates the output (power consumption) of the motor pump 310.

  The upper diagram in FIG. 4 shows an acceleration time graph 412 during acceleration / deceleration of the pump drive frequency of the alternating current inverter 324 at normal times and power supplied to the power unit 320 due to a power failure etc. from the first power to the second power. The acceleration time graph 414 in the acceleration-deceleration of the pump drive frequency of the alternating current inverter 324 after having switched is shown.

  When the power supplied to power unit 320 is switched from the first power to the second power due to a power failure or the like, control unit 330 accelerates the rotational speed of motor pump 310 from N1 to N2 from time t1. Make it longer to t2. As a result, the pump drive frequency of the AC inverter 324 changes from the acceleration time graph 412 to the acceleration time graph 414.

  In the lower part of FIG. 4, the power graph 416 during acceleration / deceleration of the pump drive frequency of the alternating current inverter 324 at normal times and the power supplied to the power unit 320 due to a power failure switched from the first power to the second power. The output graph 418 in the acceleration-deceleration of the pump drive frequency of subsequent AC-conversion inverter 324 is shown.

  As shown in the lower diagram of FIG. 4, the output of the motor pump 310 rises from P1 to P2 under normal conditions because the acceleration time for accelerating the rotational speed of the motor pump 310 from N1 to N2 is t1 and is relatively short. In the process of On the other hand, after the power supplied to the power unit 320 is switched from the first power to the second power due to a power failure or the like, the acceleration time when accelerating the rotational speed of the motor pump 310 from N1 to N2 is longer than t1. Since t2 is set, the output of the motor pump 310 gently increases from P1 to P2. Therefore, by increasing the acceleration / deceleration time of the pump drive frequency of the AC drive inverter 324 after the power supplied to the power unit 320 is switched from the first power to the second power due to a power failure or the like, as compared to normal time. The power consumption of the motor pump 310 can be reduced. As a result, the operation time of water supply device 300 by the power supplied from power storage device 200 can be extended.

(Third control mode)
As in the first embodiment, when the two motor pumps 310-1 and 310-2 are operated when the first power is supplied to the power unit 320, the control unit 330 sends the power unit 320 to the power unit 320. When the supplied electric power switches from the first electric power to the second electric power, the number of operating the motor pump 310 by the second electric power may be smaller than the number of operating the motor pump 310 by the first electric power. , Motive power unit 320 is controlled.

  That is, in the present embodiment, at normal times, the two motor pumps 310-1 and 320-2 are operated by the first electric power. On the other hand, when the power supplied to the power unit 320 is switched from the first power to the second power due to a power failure or the like, the control unit 330 supplies the second power only to the motor pump 310-1, for example, One motor pump 310-1 is operated.

  The power consumption of the motor pump 310 can be reduced by reducing the number of operating motor pumps from the normal time. As a result, the operation time of water supply device 300 by the power supplied from power storage device 200 can be extended.

(Third control mode)
Control unit 330 causes power to be set such that the set pressure of motor pump 310 when driving motor pump 310 is lowered stepwise by the second electric power in response to a decrease in the remaining charge amount of power storage unit 210 in power storage device 200. The unit 320 can be controlled.

  That is, a control signal indicating the state of the power storage unit 210 (such as the remaining amount of power storage) is input to the control unit 330 from the control unit 230. Control unit 330 grasps the remaining amount of charge of power storage unit 210 based on the input control signal. Then, control unit 330 lowers the set pressure of motor pump 310 step by step as the remaining charge amount of power storage unit 210 decreases. About the aspect which reduces the setting pressure of the motor pump 310, since it is the same as that of the above-mentioned 1st control aspect, detailed description is abbreviate | omitted.

  The third control mode will be described with reference to FIG. FIG. 5 is a diagram showing another example of the operation control flow by the control unit. As shown in FIG. 5, the control unit 330 first operates the motor pump 310 in the normal operation mode (step S201). That is, the control unit 330 controls the power unit 320 to drive the motor pump 310 with various setting values of the motor pump 310 in the normal operation mode set in advance in the control unit 330.

  Subsequently, control unit 330 determines whether or not the power supply supplied to power unit 320 is the power (second power) stored in power storage unit 210 (step S202). Specifically, based on the control signal input from control unit 230, control unit 330 determines whether or not the second power is supplied.

  If control unit 330 determines that the power supplied to power unit 320 is not the power stored in storage unit 210 (the second power) (No at step S202), the process returns to step S201 and continues the normal operation. Do.

  On the other hand, when control unit 330 determines that the power supplied to power unit 320 is the power (second power) stored in power storage unit 210 (Yes in step S202), motor pump 310 is operated in the power failure operation mode. It drives (step S203). Specifically, the control unit 330 operates the motor pump 310 at a set pressure 1 lower than the normal operation mode.

  Subsequently, control unit 330 determines whether or not the remaining charge level of power storage unit 210 is smaller than a preset threshold (D1) (step S204).

  If control unit 330 determines that the remaining charge level of power storage unit 210 is not smaller than the preset threshold value (D1) (step S204, No), the process returns to step S203, and motor pump 310 at set pressure 1 Continue driving.

  On the other hand, when control unit 330 determines that the remaining charge level of power storage unit 210 is smaller than the preset threshold value (D1) (step S204, Yes), the motor pump is operated at set pressure 2 lower than set pressure 1 Operation 310 is performed (step S205).

  Subsequently, control unit 330 determines whether or not the remaining charge level of power storage unit 210 is smaller than a preset threshold (D2) smaller than D1 (step S206).

  If control unit 330 determines that the remaining charge level of power storage unit 210 is not smaller than the preset threshold value (D2) (No at step S206), the process returns to step S205 and motor pump 310 at set pressure 2 Continue driving.

  On the other hand, when control unit 330 determines that the remaining charge level of power storage unit 210 is smaller than the preset threshold value (D2) (step S206, Yes), the motor pump is operated at set pressure 3 lower than set pressure 2 Operation 310 is performed (step S207).

  Subsequently, control unit 330 determines whether or not the remaining charge level of power storage unit 210 is smaller than a preset threshold (D3) smaller than D2 (step S208).

  If control unit 330 determines that the remaining charge level of power storage unit 210 is not smaller than the preset threshold value (D3) (step S208, No), the process returns to step S207, and motor pump 310 at set pressure 3 Continue driving.

  On the other hand, when control unit 330 determines that the remaining charge level of power storage unit 210 is smaller than the preset threshold value (D3) (step S208, Yes), operation of motor pump 310 is stopped (step S209) .

  According to the third control mode, the set pressure of the motor pump 310 is lowered stepwise as the remaining charge amount of the power storage unit 210 decreases, so the power consumption of the motor pump 310 is reduced according to the decrease of the remaining charge amount. It can be made smaller. As a result, the operation time of water supply device 300 by the power supplied from power storage device 200 can be extended.

(Fourth control mode)
The control unit 330 controls the power unit 320 such that the set pressure of the motor pump 310 at the time of driving the motor pump 310 by the second electric power decreases stepwise in response to the increase of the temperature of the storage unit 210. Can.

  That is, there is a correlation that the temperature of power storage unit 210 becomes higher as the remaining charge amount of power storage unit 210 decreases. Therefore, control unit 330 can gradually lower the set pressure of motor pump 310 as the temperature of power storage unit 210 becomes higher.

  According to this, since the set pressure of motor pump 310 is lowered as the remaining amount of power storage unit 210 decreases, the power consumption of motor pump 310 can be reduced according to the decrease in remaining power amount. . As a result, the operation time of water supply device 300 by the power supplied from power storage device 200 can be extended.

(Fifth control mode)
The control unit 330 can have a timer function of measuring the operation time of the water supply device 300 using the second power. In this case, the control unit 330 causes the set pressure of the motor pump 310 to be lowered stepwise when the motor pump 310 is driven by the second power, in accordance with the operation time of the water supply device 300 by the second power. The power unit 320 can be controlled.

  That is, the operation time of the water supply device 300 by the second electric power is correlated with the remaining power storage amount of the general power storage unit 210. Therefore, the control unit 330 can gradually reduce the set pressure of the motor pump 310 as the operation time of the water supply device 300 by the second power becomes longer.

  According to this, since the set pressure of motor pump 310 is lowered as the remaining amount of power storage unit 210 decreases, the power consumption of motor pump 310 can be reduced according to the decrease in remaining power amount. . As a result, the operation time of water supply device 300 by the power supplied from power storage device 200 can be extended.

(Sixth control mode)
When the power supplied to power unit 320 (AC inverter 324) is switched from the first power to the second power, control unit 330 causes AC inverter 324 to drive motor pump 310 with the second power. The power unit 320 (AC inverter 324) can be controlled such that the carrier frequency of the AC power inverter 320 is lower than the carrier frequency of the AC inverter 324 when driving the motor pump 310 by the first electric power.

  This point will be described with reference to FIG. FIG. 6 is a schematic view of an alternating current inverter. As shown in FIG. 6, the alternating current inverter 324 switches the direct current (DC) power converted by the direct current inverter 322 by using switches 422-1 to 422-6 (for example, semiconductor switching elements), It is converted into alternating current (AC) power and supplied to the motor pump 310.

  Specifically, the AC inverter 324 switches three-phase AC power by switching the switches 422-1 and 422-2, the switches 422-3 and 422-4, and the switches 422-5 and 422-6. It generates and supplies to the motor pump 310.

  As described above, the alternating current inverter 324 used in the water supply device 300 supplies the required rotational speed (frequency) and voltage to the motor pump, so that high-speed switching (ON / OFF) operation is performed by the semiconductor switching element. I am The period of this switching is determined by the carrier frequency of the inverter.

  Here, the controller 330 controls the ON / OFF cycle (= carrier frequency) of the switches 422-1 to 422-6 to 10 kHz in order to reduce an offensive sound caused by the carrier frequency during normal operation. Set as high as ~ 20 (kHz). By separating the carrier frequency from the audible frequency range in this manner, noise reduction can be realized. However, since the carrier frequency is high, the energy loss by the semiconductor switch used in the alternating current inverter 324 becomes large.

  On the other hand, the control unit 330 reduces the energy loss due to the semiconductor switching used in the alternating current inverter 324 by lowering the carrier frequency to several kHz at the time of operation by power feeding from the storage unit 210 at the time of power failure. It is preferred to operate the AC inverter 324 with high efficiency as much as possible. Thereby, the water supply device 300 can be operated for a long time.

  The flow of the sixth control mode will be described with reference to FIG. FIG. 7 is a diagram showing another example of the operation control flow by the control unit. As shown in FIG. 7, first, the control unit 330 operates the motor pump 310 at a carrier frequency (for example, about 10 (kHz) to 20 (kHz)) in the normal operation mode (step S301).

  Subsequently, control unit 330 determines whether or not the power supply supplied to power unit 320 is the power (second power) stored in power storage unit 210 (step S302). Specifically, based on the control signal input from control unit 230, control unit 330 determines whether or not the second power is supplied.

  If control unit 330 determines that the power supplied to power unit 320 is not the power stored in storage unit 210 (the second power) (No at step S302), the process returns to step S301, and the carrier frequency at the normal time is used. Continue driving.

  On the other hand, when control unit 330 determines that the power supplied to power unit 320 is the power (second power) stored in power storage unit 210 (Yes in step S302), the carrier frequency in the power failure operation mode (for example, The motor pump 310 is operated at several kHz (step S303).

  Subsequently, the control unit 330 determines whether the power supply to the power unit 320 is commercial power (first power) (step S304). Specifically, based on the control signal input from control unit 230, control unit 330 determines whether or not the first power is supplied.

  When the control unit 330 determines that the power supply to the power unit 320 is not commercial power (first power) (step S304, No), the control unit 330 returns to step S303 and continues the operation at the carrier frequency at the time of power failure.

  On the other hand, when control unit 330 determines that the power supply to power unit 320 is commercial power (first power) (step S304, Yes), the process returns to step S301, and the motor pump is operated at the carrier frequency in the normal operation mode. Drive 310.

  As described above, when the power supplied to motive power unit 320 is switched from the first power to the second power, control unit 330 lowers the carrier frequency to operate motor pump 310, so that power is supplied from power storage device 200. The operating time of the water supply device 300 by the power consumption can be extended.

Second Embodiment
In the first embodiment, an example is shown in which the storage device 200 switches between commercial power (first power) and stored power (second power). However, the present invention is not limited to this. In the second embodiment, switching between the first power and the second power is performed on the water supply device side.

  The water supply system 600 of the second embodiment includes a power storage device 700 and a water supply device 800. Power storage device 700 receives commercial power (first power) supplied from commercial power supply 790. Power storage device 700 temporarily converts the input from commercial power supply 790 into DC power, stores the stored DC power in power storage unit 720 (battery), and outputs the stored DC power and a circuit that bypasses and outputs the normal commercial power. Have. Specifically, power storage device 700 includes DC conversion inverter 710 and power storage unit 720.

The DC conversion inverter 710 is an inverter that converts received commercial power into DC power, and supplies the converted DC power to the storage unit 720. Power storage unit 720 includes a DC inverter 24.
It is a storage battery that stores DC power supplied from 0.

  Power storage device 700 also includes a first output terminal 730 that outputs AC power supplied from commercial power supply 790 as it is, and a second output terminal 740 that outputs DC power stored by power storage unit 720. Power storage device 700 outputs a control signal indicating that the power supply has switched from the first power to the second power, or from the second power to the first power, to the external device (water supply device 800).

  Next, the water supply apparatus 800 includes a motor pump 810, a power unit 820, a control unit 830, a pressure sensor 840, a first power receiving terminal 850, a second power receiving terminal 860, and a switch 870. The water supply device 800 draws water from a water storage tank or the like through a pipe provided on the suction side, and transfers the water to the consumer side through a pipe provided on the discharge side. Moreover, the water supply apparatus 800 is provided with the apparatus required for control of a check valve, a pressure tank, etc. which are not shown in figure by the piping by the side of discharge.

  In the present embodiment, a motor pump 810 in which a pump for transporting a fluid such as water and a motor (drive unit) for driving the pump are integrated is described as an example, but the present invention is not limited thereto. The motor may be separate from the motor.

  Power unit 820 supplies to motor pump 810 commercial power (first power) supplied from commercial power supply 790 via switch 870 or second power supplied from power storage unit 720 via switch 870. . Specifically, power unit 820 includes a direct current inverter 822 and an alternating current inverter 824.

  The DC conversion inverter 822 is an inverter that converts the first power supplied from the first power reception terminal 850 via the switch 870 into a predetermined DC power, and outputs the converted DC power to the AC conversion inverter 824.

  The alternating current inverter 824 converts the direct current power supplied from the direct current inverter 322 or the second power supplied from the second power receiving terminal 860 through the switch 870 into alternating current power of a predetermined frequency, and thereby generates a motor pump. Supply to 810. The motor pump 810 is driven at a rotational speed corresponding to the frequency of the power supplied from the alternating current inverter 824.

  The pressure sensor 840 is provided on the discharge side pipe of the motor pump 810, and measures the pressure on the discharge side of the motor pump 810. The pressure value measured by the pressure sensor 840 is output to the control unit 830. The water supply apparatus 800 is configured to supply water at an appropriate pressure to the consumer side by detecting the discharge pressure mainly by the signal of the pressure sensor 840 and outputting a control signal from the control unit 830 to the power unit 820. It is done. In the case where the water supply apparatus 800 is provided with a water receiving tank on the suction side of the motor pump 810, detection of the water level from the water level detector is also unnecessary during operation by the power storage apparatus 700. However, the signal from the pressure sensor 840 is continuously output to the control unit 830 regardless of the type of power supply in order to change the pressure setting value.

  First power receiving terminal 850 receives the AC power output from first output terminal 730, and outputs the power to switch 870. Second power reception terminal 860 receives DC power output from second output terminal 740 and outputs the power to switch 870. The control unit 830 outputs a switching control signal to the switch 870 in addition to the same function as that of the first embodiment.

  The switch 870 outputs the first power received at the first power receiving terminal 850 to the DC conversion inverter 822 or receives power at the second power receiving terminal 860 based on the switching control signal from the control unit 830. It switches whether to output the power of 2 to the alternating current inverter 824.

  Specifically, switch 870 outputs the first power received at first power reception terminal 850 to direct-current inverter 822 at the normal time when the commercial power from commercial power source 790 is supplied. The DC conversion inverter 822 converts the first power supplied from the first power reception terminal 850 into DC power, and outputs the DC power to the AC conversion inverter 824. The alternating current inverter 824 converts the direct current power supplied from the direct current inverter 822 into alternating current power and outputs the alternating current power to the motor pump 810.

  On the other hand, switch 870 outputs the second power received at second power receiving terminal 860 to alternating current inverter 824 at the time of a power failure where the commercial power from commercial power source 790 is not supplied. The AC inverter 824 converts DC power supplied from the second power receiving terminal 860 into AC power and outputs the AC power to the motor pump 810.

  According to the present embodiment, direct-current power output from power storage device 700 is directly received, converted to a predetermined frequency by alternating-current inverter 824, and supplied to motor pump 810, thereby reducing the number of times of direct-current and alternating-current conversion. Energy efficiency can be improved. As a result, it is possible to reduce the power required to drive the water supply device 800 at the time of a power failure, so the operating time of the water supply device 800 by the power supplied from the power storage device 700 can be extended.

100, 600 Water supply system 200, 700 Power storage device 210, 720 Power storage unit 220 AC inverter 230 Control unit 240, 710 DC conversion inverter 250 Switch 290, 790 Commercial power supply 300, 800 Water supply device 310, 810 Motor pump 320, 820 Power unit 322, 822 DC inverter 324, 824 AC inverter 330, 830 control unit 340, 840 pressure sensor 350 display unit 730 first output terminal 740 second output terminal 850 first power receiving terminal 860 second power receiving terminal 870 switch

Claims (9)

A pump for transferring fluid,
A drive unit for driving the pump;
A power unit that supplies a first power or a second power to the drive unit, wherein the first power is supplied from a commercial power supply, and the second power stores the first power . A storage unit , and switching a power supply from the first power to the second power, or from the second power to the first power, or externally outputting a control signal indicating a state of the storage unit A power unit supplied from a power storage device capable of outputting to the device;
A control unit configured to control the driving of the pump via the power unit;
The control unit determines that the power supplied to the power unit has switched from the first power to the second power based on the control signal from the power storage device , and in that case, the second power Controlling the power unit such that the power consumption of the drive unit when driving the pump by using the power consumption is smaller than the power consumption of the drive unit when driving the pump by the first power;
When the power unit includes an inverter that converts the first power or the second power into a predetermined frequency and supplies the predetermined frequency to the drive unit.
The controller accelerates or decelerates a pump drive frequency of the inverter when driving the pump by the second power when the power supplied to the inverter is switched from the first power to the second power. The inverter is controlled such that the time is longer than the acceleration / deceleration time of the pump drive frequency of the inverter when driving the pump by the first power.
A fluid supply device characterized in that. In the fluid supply device of claim 1,
When the power supplied to the power unit switches from the first power to the second power, the control unit sets the set pressure of the pump when the pump is driven by the second power. Controlling the power unit to be smaller than a set pressure of the pump when driving the pump by the first electric power;
A fluid supply device characterized in that. In the fluid supply device of claim 1,
When the plurality of pumps and the driving unit are operated when the first power is supplied to the power unit,
When the power supplied to the power unit is switched from the first power to the second power, the control unit controls the number of operating the pump and the drive unit by the second power. Control the power unit so that the power of the motor and the number of operating the pump and the drive unit are smaller than
A fluid supply device characterized in that. In the fluid supply device of claim 1,
And an input terminal for receiving AC power output from the power storage device,
The power unit includes an inverter that converts AC power received through the input terminal into a predetermined frequency and supplies the converted power to the drive unit.
A fluid supply device characterized in that. In the fluid supply device of claim 1,
When the power unit includes an inverter that converts the first power or the second power into a predetermined frequency and supplies the predetermined frequency to the drive unit.
When the power supplied to the inverter is switched from the first power to the second power, the control unit controls the carrier frequency of the inverter at the time of driving the pump by the second power, Controlling the inverter to be lower than the carrier frequency of the inverter when driving the pump by a power of 1;
A fluid supply device characterized in that. In the fluid supply device of claim 1,
When the power supplied to the power unit switches from the first power to the second power, the control unit displays on the display unit that the pump is driven by the power supplied from the power storage device. ,
A fluid supply device characterized in that. In the fluid supply device of claim 1,
It has an input terminal for receiving an operation signal indicating that the power supplied to the power unit switches from the first power to the second power.
A fluid supply device characterized in that. In the fluid supply device of claim 1,
The control unit controls a device including a display unit in the fluid supply device to a sleep state when there is no request for driving the pump in a state where the second power is supplied to the power unit. ,
A fluid supply device characterized in that. In the fluid supply device of claim 1,
When the power unit includes an inverter that converts the first power or the second power into a predetermined frequency and supplies the predetermined frequency to the drive unit.
It has an input terminal for receiving DC power output from the power storage device,
The inverter converts direct current power received through the input terminal into alternating current power of a predetermined frequency and supplies the alternating current power to the drive unit.
A fluid supply device characterized in that.

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