JP6255444B2 - Water supply unit and method for controlling water supply unit - Google Patents

Description

  The present invention relates to a water supply unit that performs constant discharge pressure control and a method for controlling the water supply unit.

  A water supply unit that controls a pump according to an operation mode selected by a user from a plurality of operation modes is known as a water supply unit that pumps water from a well or a water receiving tank with a pump (for example, see Patent Document 1). .

  In addition, the structure of the water supply unit enables constant discharge pressure control that controls the rotation speed of the pump so that the discharge pressure becomes the target pressure value, and the operation modes include standard operation mode, high-pressure operation mode, and low-pressure operation. A configuration having a mode is conceivable. The standard operation mode is an operation mode in which a preset standard pressure value is a target pressure value. The high-pressure operation mode is an operation mode in which a pressure value higher than a standard pressure value is set as a target pressure value, which enables an operation requiring high discharge pressure such as watering. The low-pressure operation mode is an operation mode that enables energy-saving operation and uses a pressure value lower than the standard pressure value as a target pressure value.

Patent No. 5715803

  The above-described water supply unit that performs constant discharge pressure control in any selected operation mode has the following problems. That is, in each operation mode, the target pressure value of the discharge pressure is different, but the maximum rotational speed of the pump is the same.

  For this reason, even in the low pressure operation mode, when the pump rotation speed reaches the maximum rotation speed, the power consumption of the water supply unit is the same as the power consumption in the standard operation mode in the large flow rate range thereafter. It was not intended to save energy in the area.

  In addition, since the water supply unit is required to keep the temperature rise of the motor windings below the allowable value according to regulations, the maximum power consumption in the high-pressure operation mode is within a predetermined range with respect to the maximum power consumption in the standard operation mode. Need to fit. For this reason, the target pressure value of the discharge pressure in the high pressure operation mode is limited, and the pressure increase effect by the high pressure operation mode is limited.

  Furthermore, the water supply unit needs to be designed in consideration of the temperature increase in the high pressure operation mode in which power consumption is larger than that in the standard operation mode and the low pressure operation mode. If used, the design becomes excessive.

  Therefore, the present invention enables energy-saving operation in the entire flow range during operation in the low pressure operation mode, and increases the target pressure value while preventing increase in power consumption during operation in the high pressure operation mode. It aims at providing the water supply unit which can enlarge a width | variety, and the control method of a water supply unit.

As one aspect of the present invention, a water supply unit includes a pump that boosts and discharges water, a motor that drives the pump, an inverter circuit that supplies AC power to the motor, and a pressure that detects the discharge pressure of the pump A detection unit, a standard operation mode in which a predetermined standard pressure value is set as a target pressure value, and the discharge pressure is constantly controlled within the set maximum rotation speed, and the standard operation mode in which the predetermined standard pressure value can be maintained. The target pressure value is set to a pressure value higher than the standard pressure value in a flow rate range smaller than the maximum value of the discharge flow rate , and the maximum rotation speed of the pump in the standard operation mode is the maximum rotation speed of the pump. A high-pressure operation mode in which a discharge pressure constant control is set to a rotational speed smaller than the speed, a target pressure value is set to a pressure value lower than the standard pressure value, and the pump An operation unit for selecting one of a low pressure operation mode for performing a discharge pressure constant control in which a maximum rotation speed is set to a rotation speed smaller than the maximum rotation speed of the pump in the standard operation mode; and the standard operation mode, A control unit that controls the inverter circuit to control the pump based on a detection result of the pressure detection unit according to an operation mode selected by operating the operation unit among the high pressure operation mode and the low pressure operation mode. And comprising.

As one aspect of the present invention, a control method for a water supply unit includes a standard operation mode in which a predetermined standard pressure value is set as a target pressure value of a pump discharge pressure, and discharge pressure constant control is performed within a set maximum rotation speed, The target pressure value is set to a pressure value higher than the standard pressure value in a flow rate range smaller than the maximum value of the discharge flow rate in the standard operation mode capable of maintaining the predetermined standard pressure value , and the highest pump A high pressure operation mode in which the discharge pressure is constant controlled with a rotation speed set to a rotation speed smaller than the maximum rotation speed of the pump in the standard operation mode, and a pressure value whose target pressure value is lower than the standard pressure value And a discharge pressure constant control in which the maximum rotation speed of the pump is set to a rotation speed smaller than the maximum rotation speed of the pump in the standard operation mode. Select one of the rolling mode, the normal operation mode, the high-pressure operation mode, and the selected operating mode of the low-pressure operation mode, it controls the pump.

  According to the present invention, energy saving operation is possible in the entire flow rate range during operation in the low pressure operation mode, and increase in the target pressure is prevented while increasing power consumption during operation in the high pressure operation mode. It is possible to provide a water supply unit capable of increasing the size and a method for controlling the water supply unit.

The top view which shows the structure of the water supply unit which concerns on one Embodiment of this invention. The diagram which shows the relationship between the discharge pressure and flow volume in each operation mode of the water supply unit. The diagram which shows the relationship between the rotational speed and flow volume of the pump in each operation mode of the water supply unit. The diagram which shows the relationship between the power consumption and flow volume in each operation mode of the water supply unit.

  A water supply unit 10 according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a plan view showing the configuration of the water supply unit 10. FIG. 2 is a diagram showing the relationship between the discharge pressure and the discharge flow rate in each operation mode of the water supply unit 10. FIG. 3 is a diagram showing the relationship between the rotational speed of the pump 41 and the discharge flow rate in each operation mode of the water supply unit 10. FIG. 4 is a diagram showing the relationship between the power consumption and the discharge flow rate in each operation mode of the water supply unit 10. The discharge flow rate here is the flow rate of water flowing on the secondary side of the pump 41.

  The water supply unit 10 is, for example, a self-priming water supply unit that is installed in a well or a water receiving tank and configured to pump water and supply water. As shown in FIG. 1, the water supply unit 10 includes a base 20, a suction pipe 30, a pump device 40 connected to the secondary side of the suction pipe 30, a self-priming chamber 50 provided on the secondary side of the pump device 40, It has a detection device 60 provided on the secondary side of the self-priming chamber 50 and capable of detecting the discharge flow rate and discharge pressure, a discharge pipe 70 connected to the secondary side of the detection device 60, and an electrical component 80. . The suction pipe 30, the pump device 40, the self-suction chamber 50, the detection device 60, the discharge pipe 70, and the electrical component 80 are provided on the base 20.

  The suction pipe 30 is formed to be connectable to a suction pipe installed in a well or a water receiving tank. The suction pipe 30 is formed so that water from the suction pipe can be supplied to the pump 41 of the pump device 40.

The pump device 40 includes a pump 41 configured to be able to increase the pressure of water sucked through the suction pipe 30, and a motor 42 that drives the pump 41. The pump device 40 is a vertical pump device in which a motor 42 is installed on the top of a pump 41. The pump 41 is, for example, a vortex pump. The pump 41 has a casing that forms a pump chamber 43 therein, an impeller 44 disposed in the pump chamber 43, and a rotating shaft fixed to the impeller 44.
The motor 42 includes a motor casing supported on an upper portion of the casing of the pump 41, a stator fixed in the motor casing, and a rotor disposed in the motor casing and provided to be rotatable with respect to the stator. have. The rotor is formed to be able to rotate the rotation shaft of the impeller 44.

  The self-priming chamber 50 has a suction port for sucking in water whose pressure has been increased from the pump chamber 43, and a return port for returning water to the pump chamber 43. The suction port and the return port communicate with the pump chamber 43. A priming port is formed in the upper part of the self-priming chamber 50. A detachable plug 53 is provided at the priming port. The priming port is an opening formed so that priming water can be injected into the self-priming chamber. By circulating water in the self-priming chamber 50 and the pump chamber 43, the water supply unit 10 can perform a self-priming operation.

  The detection device 60 is provided in the upper part of the self-priming chamber 50. The detection device 60 has a flow channel forming a part of the flow channel to the discharge pipe 70 in the inside thereof. When the self-priming operation is completed and the self-priming chamber is filled with water, the water increased in pressure by the pump 41 flows to the detection device 60.

  The detection device 60 has a flow path that is formed inside and through which water flows from the self-priming chamber 50 to the discharge pipe 70. The detection device 60 also includes a flow rate detection unit 61 provided in the flow path and a pressure detection unit 62 provided in the flow path. The flow rate detection unit 61 and the pressure detection unit 62 are connected to the control unit 81 of the electrical unit 80 by a signal line S.

  The flow rate detection unit 61 is configured to be able to detect a stop flow rate at which the driving of the pump 41 is stopped, and is configured to be able to output a signal corresponding to the detection result. The pressure detection unit 62 is configured to detect the pressure of water flowing through the flow path in the detection device 60, which is the discharge pressure of the pump 41, and to output a signal corresponding to the detection result pressure.

  The electrical unit 80 includes a control unit 81, an inverter circuit 82 that supplies AC power to the motor 42, and a switch 83 configured to be operable by a user.

  The control unit 81 is configured to be able to control the pump 41. When the self-priming operation is not completed, the control unit 81 controls the pump 41 to perform the self-priming operation. In addition, when the self-priming operation is completed, the control unit 81 controls the pump 41 so that the pump 41 is steadily operated based on the detection results of the flow rate detection unit 61 and the pressure detection unit 62. The steady operation is an operation in which the inverter circuit 82 is controlled so that the discharge pressure becomes a target pressure value by controlling the rotation speed of the pump 41. The rotational speed of the pump 41 is determined according to the frequency of the AC power output from the inverter circuit 82. The rotational speed of the pump 41 is the rotational speed of the impeller 44.

  In the case of performing steady operation, the controller 81 activates the pump 41 when the pressure detector 62 detects the activation pressure. Further, the control unit 81 stops the pump 41 when the flow rate detection unit 61 detects a stop flow rate. The control unit 81 controls the pump 41 in any one of the operation modes selected by operating the switch 83 among the standard operation mode, the high pressure operation mode, and the low pressure operation mode.

  The standard operation mode is an operation mode used for a standard operation of the water supply unit 10, and a predetermined standard pressure value is set as a target pressure value, and a predetermined rotation speed of the pump 41 is set as a maximum rotation speed. In this operation mode, the pump 41 is controlled by the constant discharge pressure control. In FIG. 2, the standard pressure value is indicated by a solid line. As shown in FIG. 2, the standard pressure value that is the target pressure value in the standard operation mode is, for example, 25 m. Moreover, the starting pressure in the standard operation mode is, for example, 21 m.

In FIG. 3, the rotational speed of the pump 41 in the standard operation mode is indicated by a solid line. As shown in FIG. 3, the maximum rotation speed of the pump 41 in the standard operation mode is set to 3390 min ⁻¹ , for example. The control unit 81 controls the pump 41 so that the rotation speed of the pump 41 does not exceed the maximum rotation speed so that the discharge pressure becomes the standard pressure value. In the standard operation mode, when the discharge flow rate is approximately 34 L / min, the rotational speed of the pump 41 reaches the maximum rotational speed. In FIG. 4, the power consumption in the standard operation mode is indicated by a solid line. As shown in FIG. 4, in the standard operation mode, the power consumption becomes maximum when the discharge flow rate is approximately 34 L / min. The maximum power consumption in the standard operation mode is 390W.

  In the high pressure operation mode, discharge pressure is controlled at a discharge pressure that is higher than the target pressure value in the standard operation mode in the flow rate range smaller than the maximum discharge flow rate that can maintain the target pressure value in the standard operation mode. In this operation mode, the maximum power consumption is approximately the same as the maximum power consumption in the standard operation mode or less than or equal to the maximum power consumption in the standard operation mode.

  In the present embodiment, in the high pressure operation mode, the maximum rotation speed of the pump 41 is set so that the maximum power consumption is substantially the same as the maximum power consumption in the standard operation mode. The maximum power consumption in the high-pressure operation mode is 395 W as indicated by a broken line in FIG.

  In FIG. 2, the target pressure value of the discharge pressure in the high pressure operation mode is indicated by a broken line. As shown in FIG. 2, in the present embodiment, in the high pressure operation mode, the discharge flow rate is maintained at the target pressure value, and a discharge flow rate of 23 L / min is ensured. The target pressure value in the high pressure operation mode is, for example, 31 m, and is set 6 m higher than the standard operation mode. Moreover, the starting pressure in the high pressure operation mode is 27 m, for example.

  The rotation speed of the pump 41 in the high pressure operation mode is set to a value higher than the rotation speed in the standard operation mode at the same discharge flow rate and the rotation speed in the low pressure operation mode at the same discharge flow rate until reaching the maximum rotation speed. Has been. The maximum rotation speed of the pump 41 in the high pressure operation mode is set to a value smaller than the maximum rotation speed in the standard operation mode and the maximum rotation speed in the low pressure operation mode.

Specifically, the rotational speed in the high pressure operation mode is set to 3150 min ^{−1 as} indicated by a broken line in FIG. This is because the maximum power consumption in the high pressure operation mode is 395 W and the target pressure value of the discharge pressure is set to 31 m.

In the high pressure operation mode, the controller 81 controls the pump 41 so that the rotational speed of the pump 41 does not exceed 3150 min ⁻¹ , which is the maximum rotational speed, so that the discharge pressure becomes the target pressure value.

  In the high pressure operation mode, when the discharge flow rate is approximately 27 L / min, the rotation speed of the pump 41 becomes the maximum rotation speed and the power consumption becomes the maximum.

  The low-pressure operation mode is an operation mode in which the pump 41 is controlled by constant discharge pressure control that enables operation with lower power consumption than the standard operation mode in the entire flow region. Specifically, in the low pressure operation mode, a pressure value lower than the standard pressure value is set as the target pressure value, and a rotation speed smaller than the maximum rotation speed of the pump 41 in the standard operation mode is set as the maximum rotation speed. ing. As indicated by the one-dot chain line in FIG. 2, in the low pressure operation mode, the target pressure value of the discharge pressure is set to 21 m, for example, and 4 m lower than the standard operation mode. The starting pressure in the low pressure operation mode is, for example, 17 m.

As indicated by a one-dot chain line in FIG. 3, the maximum rotation speed of the pump 41 in the low pressure operation mode is specifically, the maximum power consumption in the low pressure operation mode is smaller than the maximum power consumption in the standard operation mode. Is set to Further, the rotational speed of the pump 41 in the low pressure operation mode is set to a value smaller than the rotational speed of the pump 41 in the standard operation mode in the entire flow rate range. As shown in FIG. 4, in this embodiment, the maximum power consumption in the low pressure operation mode is 310 W, and as shown in FIG. 3, the maximum rotation speed of the pump 41 in the low pressure operation mode is 3200 min ^−1. Is set to

In the low pressure operation mode, the control unit 81 controls the pump 41 in a range where the rotational speed of the pump 41 does not exceed the maximum rotational speed of 3200 min ⁻¹ so that the discharge pressure becomes the target pressure value. In the low-pressure operation mode, when the discharge flow rate is approximately 31 L / min, the rotation speed of the pump 41 becomes the maximum rotation speed and the power consumption becomes the maximum. The rotation speed in the low-pressure operation mode is a value smaller than the rotation speed in the standard operation mode until the maximum rotation speed is reached.

  The switch 83 is an operation unit that is operated when the user selects an operation mode. The switch 83 is, for example, a slide switch. The switch 83 has a movable knob, and the operation mode can be selected by moving the knob to a position where a desired operation mode is indicated. The switch 83 is connected to the control unit 81 and is configured to be able to transmit a signal corresponding to the operation mode selected by the user's operation to the control unit 81.

  Next, the steady operation of the water supply unit 10 will be described. First, the user operates the switch 83 to select an operation mode corresponding to the intended use. For example, when the user desires standard driving, the user operates the switch 83 to select the standard driving mode. When the user uses the water supply unit 10 for an operation requiring a high discharge pressure such as watering, the user operates the switch 83 to select the high pressure operation mode. When the user desires energy saving operation, the user selects the low pressure operation mode by operating the switch 83.

  The switch 83 transmits a signal corresponding to the operation mode selected by the user's operation to the control unit 81. The control unit 81 controls the pump 41 based on the operation mode selected by the user based on the signal from the switch 83.

Specifically, when the control unit 81 controls the pump 41 in the standard operation mode, when the starting pressure is detected by the pressure detection unit 62, the standard pressure value is set as the target pressure value, and the maximum rotation speed is set at 3390 min ^−1. The pump 41 is controlled by constant discharge pressure control. With this control, the maximum power consumption of the water supply unit 10 is 390 W. Further, when the flow rate detector 61 detects a stop flow rate, the control unit 81 stops driving the pump 41.

When the control unit 81 controls the pump 41 in the high pressure operation mode, the maximum rotation speed is set to 3150 min ⁻¹ so that the discharge pressure of the pump 41 becomes the target pressure value when the start pressure is detected by the pressure detection unit 62. The pump 41 is controlled by constant discharge pressure control. With this control, the maximum power consumption of the water supply unit 10 is 395 W. Further, when the flow rate detector 61 detects a stop flow rate, the control unit 81 stops driving the pump 41.

When the control unit 81 controls the pump 41 in the low pressure operation mode, the maximum rotation speed is set to 3200 min ⁻¹ so that the discharge pressure of the pump 41 becomes the target pressure value when the start pressure is detected by the pressure detection unit 62. The pump 41 is controlled by constant discharge pressure control. By this control, the maximum power consumption of the water supply unit 10 is 310W. Further, when the flow rate detector 61 detects a stop flow rate, the control unit 81 stops driving the pump 41.

  In the water supply unit 10 configured as described above, in the operation in the low pressure operation mode, the maximum rotation speed of the pump 41 is set to a value smaller than the maximum rotation speed of the pump 41 in the standard operation mode. As shown, the power consumption can be kept smaller than the power consumption in the standard operation mode at all the discharge flow rates.

  Further, in the low pressure operation mode, the maximum rotation speed of the pump 41 is set to a value smaller than the maximum rotation speed in the standard operation mode. For this reason, since the noise of the fan of the motor 42 etc. is reduced, the level of the noise which the water supply unit 10 emits can be reduced with respect to the standard operation mode.

  Further, in the high pressure operation mode, the maximum power consumption is substantially the same as the maximum power consumption in the standard operation mode by suppressing the maximum rotation speed of the pump 41 smaller than the maximum rotation speed of the pump 41 in the standard operation mode. Or, it is below the maximum power consumption in the standard operation mode. For this reason, an increase in power consumption can be prevented in the high pressure operation mode.

  In addition, since it is possible to prevent an increase in power consumption in the high-pressure operation mode, it is possible to prevent the amount of heat generated in the motor 42 and the electrical unit 80 from increasing with respect to the amount of heat generated in the standard operation mode.

  For this reason, it becomes possible to cope with the temperature rise in the high-pressure operation mode by designing the water supply unit 10 in consideration of the temperature rise in the standard operation mode.

  In the high-pressure operation mode, the flow rate from the pump 41 that can be secured while maintaining the target pressure value by making the maximum rotation speed of the pump 41 smaller than the maximum rotation speed of the pump 41 in the standard operation mode is standard. Although the flow rate is smaller than the flow rate from the pump 41 that can be secured while maintaining the target pressure value in the operation mode, the target pressure value can be made larger than the target pressure value in the standard operation mode. A sufficient pressure increasing effect can be obtained.

  In the present embodiment, the water supply unit 10 has a configuration in which a user can select a desired operation mode by operating the switch 83, but is not limited thereto. As another example, the water supply unit 10 may be configured such that an operation mode can be selected by a remote controller that wirelessly transmits a signal. In this case, the water supply unit 10 includes a remote controller operated by the user, and the electrical unit 80 may include a receiving unit that receives a signal oscillated by the remote controller and transmits a reception result to the control unit 81. .

The present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the above-described embodiments. For example, you may delete some components from all the components shown by embodiment mentioned above. The invention described in the initial claims of the present application will be appended below.
[1]
A pump that boosts and discharges water,
A motor for driving the pump;
An inverter circuit for supplying AC power to the motor;
A pressure detector for detecting the discharge pressure of the pump;
A predetermined standard pressure value is set as a target pressure value, a standard operation mode in which the discharge pressure is constantly controlled within the set maximum rotation speed, the target pressure value is set to a pressure value higher than the standard pressure value, and A high-pressure operation mode in which the discharge pressure is constantly controlled, wherein the maximum rotation speed of the pump is set to be smaller than the maximum rotation speed of the pump in the standard operation mode; and the target pressure value is greater than the standard pressure value. Any one of the low pressure operation modes in which the discharge pressure constant control is performed in which the pump is set to a low pressure value and the maximum rotation speed of the pump is set to be smaller than the maximum rotation speed of the pump in the standard operation mode. An operation section for selecting
The inverter circuit controls the pump based on the detection result of the pressure detection unit according to an operation mode selected by operating the operation unit among the standard operation mode, the high pressure operation mode, and the low pressure operation mode. A control unit for controlling
A water supply unit comprising:
[2]
In the high pressure operation mode, the rotation speed of the pump in the standard operation mode at the same flow rate and the pump in the low pressure operation mode at the same flow rate until the rotation speed of the pump reaches the maximum rotation speed. It is set to a value higher than the rotation speed of
[1] The water supply unit according to [1].
[3]
In the low pressure operation mode, the rotation speed of the pump is set to a value smaller than the rotation speed of the pump in the standard operation mode in the entire flow rate region.
The water supply unit according to [1] or [2].
[4]
A standard operation mode in which a predetermined standard pressure value is set as the target pressure value of the pump discharge pressure, and the discharge pressure is constantly controlled within the set maximum rotation speed. The target pressure value is set to a pressure value higher than the standard pressure value. A high pressure operation mode in which the discharge pressure constant control is performed, and the discharge pressure constant control is set, wherein the maximum rotation speed of the pump is set to be smaller than the maximum rotation speed of the pump in the standard operation mode; A discharge pressure constant control is performed in which the pressure value is set lower than the standard pressure value and the maximum rotation speed of the pump is set lower than the maximum rotation speed of the pump in the standard operation mode. Select one of the low pressure operation modes,
The pump is controlled according to an operation mode selected from the standard operation mode, the high pressure operation mode, and the low pressure operation mode.
A method for controlling a water supply unit.
[5]
In the high pressure operation mode, the rotation speed of the pump in the standard operation mode at the same flow rate and the pump in the low pressure operation mode at the same flow rate until the rotation speed of the pump reaches the maximum rotation speed. It is set to a value higher than the rotation speed of
[4] The method for controlling a water supply unit according to [4].
[6]
In the low pressure operation mode, the rotation speed of the pump is set to a value smaller than the rotation speed of the pump in the standard operation mode in the entire flow rate range.
The method for controlling a water supply unit according to [4] or [5].

  DESCRIPTION OF SYMBOLS 10 ... Water supply unit, 20 ... Base, 30 ... Suction pipe, 40 ... Pump device, 41 ... Pump, 42 ... Motor, 43 ... Pump chamber, 44 ... Impeller, 50 ... Self-priming chamber, 60 ... Detection device, 61 ... Flow rate detection unit, 62 ... pressure detection unit, 70 ... discharge pipe, 80 ... electrical equipment unit, 81 ... control unit, 82 ... inverter circuit, 83 ... switch (operation unit).

Claims (6)

A pump that boosts and discharges water,
A motor for driving the pump;
An inverter circuit for supplying AC power to the motor;
A pressure detector for detecting the discharge pressure of the pump;
A standard operation mode in which a predetermined standard pressure value is set as a target pressure value and discharge pressure is constantly controlled within the set maximum rotation speed, and the maximum discharge flow rate in the standard operation mode in which the predetermined standard pressure value can be maintained The target pressure value is set to a pressure value higher than the standard pressure value in a flow rate range smaller than the value , and the maximum rotation speed of the pump is smaller than the maximum rotation speed of the pump in the standard operation mode. A high pressure operation mode in which the discharge pressure constant control set to the rotation speed is performed, a target pressure value is set to a pressure value lower than the standard pressure value, and the maximum rotation speed of the pump is set to the standard operation mode. An operation unit for selecting any one of the low pressure operation modes for performing the discharge pressure constant control set to a rotation speed smaller than the maximum rotation speed of the pump;
The inverter circuit controls the pump based on the detection result of the pressure detection unit according to an operation mode selected by operating the operation unit among the standard operation mode, the high pressure operation mode, and the low pressure operation mode. A control unit for controlling
A water supply unit comprising: In the high pressure operation mode, the rotation speed of the pump in the standard operation mode at the same flow rate and the pump in the low pressure operation mode at the same flow rate until the rotation speed of the pump reaches the maximum rotation speed. The water supply unit according to claim 1, wherein the water supply unit is set to a value higher than the rotation speed of the water supply unit. The rotation speed of the pump in the low-pressure operation mode is set to a value smaller than the rotation speed of the pump in the standard operation mode in the entire flow rate range . Water supply unit. A standard operation mode in which a predetermined standard pressure value is set as a target pressure value of the discharge pressure of the pump and the discharge pressure is constantly controlled within the set maximum rotation speed, and the standard operation mode in which the predetermined standard pressure value can be maintained. The target pressure value is set to a pressure value higher than the standard pressure value in a flow rate range smaller than the maximum value of the discharge flow rate of the pump, and the maximum rotational speed of the pump is the highest speed of the pump in the standard operation mode. A high-pressure operation mode in which discharge pressure constant control is set to a rotational speed smaller than the rotational speed, a target pressure value is set to a pressure value lower than the standard pressure value, and the maximum rotational speed of the pump is Select one of the low-pressure operation modes for performing discharge pressure constant control set to a rotation speed smaller than the maximum rotation speed of the pump in the standard operation mode,
The method for controlling a water supply unit, wherein the pump is controlled by an operation mode selected from the standard operation mode, the high-pressure operation mode, and the low-pressure operation mode. In the high pressure operation mode, the rotation speed of the pump in the standard operation mode at the same flow rate and the pump in the low pressure operation mode at the same flow rate until the rotation speed of the pump reaches the maximum rotation speed. The method for controlling the water supply unit according to claim 4, wherein the value is set to a value higher than the rotation speed of the water supply unit. The rotation speed of the pump in the low-pressure operation mode is set to a value smaller than the rotation speed of the pump in the standard operation mode in the entire flow rate range. Control method of water supply unit.