JP2009062927A - Variable speed water supply device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a variable speed water supply device capable of restraining a variation in water supply pressure, even when a large quantity of water is used in a short time. <P>SOLUTION: This variable speed water supply device has a pump 1A, a motor 2A for driving the pump 1A, a shift means 3 for changing a rotating speed of the motor 2A, and a control part 4 for controlling delivery side water pressure of the pump 1A by changing a rotating speed of the pump 1A via the shift means 3. The control part 4 is constituted so as to stop the pump 1A when a flow rate of delivery side water of the pump 1A reduces up to a predetermined value, start the pump 1A when delivery side water pressure of the pump 1A reduces up to preset starting pressure, and also rotate the pump 1A at a predetermined rotating speed when the pump 1A stops in the preset starting time. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a variable speed water supply apparatus, and more particularly to a variable speed water supply apparatus that can suppress fluctuations in water supply pressure.

  In a water supply system, in general, the water pressure in the discharge pipe (hereinafter referred to as discharge pressure) is detected by a pressure sensor installed on the discharge side of the pump, and the discharge pressure (water supply pressure) is made constant by changing the rotation speed of the pump. ing. Usually, the amount of water used varies greatly depending on the time of day. For example, the amount of water used is greatly reduced at night. Therefore, from the viewpoint of energy saving, the water supply device generally has a small water amount stop function for stopping the pump when the amount of water used decreases to some extent.

  A pressure tank that temporarily stores water is connected to the discharge pipe, and water is supplied from the pressure tank to the customer for a while without restarting the pump. . As the water is used, the water in the pressure tank decreases, and the water pressure (discharge pressure) in the discharge pipe decreases. And when this discharge pressure falls to the starting pressure of a pump, a pressure sensor will detect this and a pump will be restarted.

  Usually, in apartment buildings and office buildings, a large amount of water is rarely used in a short time, and therefore, fluctuations in discharge pressure (water supply pressure) due to the use of water after pump start-up are small. However, in schools, event buildings, etc., a large amount of water is used suddenly in restrooms, etc., so the supply of water by the pump cannot keep up with the use of the water, often causing problems such as insufficient pressure. was there. For this reason, a method of supplying water from a water tank installed on the roof is often adopted, but the cost for construction for installing the water tank on the roof and wiring for water level detection is high.

JP-A-6-299576 JP 2006-161613 A

  The present invention has been made in view of the above-described conventional problems, and an object of the present invention is to provide a variable speed water supply device that can suppress fluctuations in water supply pressure even when a large amount of water is used in a short time. And

  In order to achieve the above-described object, according to one aspect of the present invention, there is provided a pump, a motor that drives the pump, a transmission unit that changes a rotation speed of the motor, and a rotation speed of the pump via the transmission unit. A control unit that controls the water pressure on the discharge side of the pump by changing, the control unit stops the pump when the flow rate of water on the discharge side of the pump is reduced to a predetermined value, When the water pressure on the discharge side of the pump drops to a preset starting pressure, the pump is started, and when the pump is stopped at a preset starting time, the pump is A variable speed water supply apparatus configured to rotate at a rotational speed.

In a preferred aspect of the present invention, there are a plurality of start times, and the plurality of start times can be changed.
In a preferred aspect of the present invention, after a predetermined time has elapsed from the start time, the control unit controls the rotational speed of the pump so that the water pressure on the discharge side of the pump becomes a predetermined target pressure. Features.
A preferred aspect of the present invention further includes a relief pipe for escaping water discharged from the pump and a relief valve provided in the relief pipe, and the relief is provided when the pump is stopped at the start time. It is configured to start the pump after opening the valve.
In a preferred aspect of the present invention, the predetermined rotational speed is a rotational speed at which the water pressure on the discharge side is higher than the starting pressure in a shut-off state where water is not used at a water supply end.
In a preferred aspect of the present invention, the predetermined rotation speed is a rotation speed at which the water pressure on the discharge side is higher than a minimum pressure required for water supply to the water supply end in a shut-off state where water is not used at the water supply end. It is characterized by being.

  According to the present invention, the start time of the pump is set to 1 minute before the rest time, and the rotation speed of the pump can be increased in advance before the rest time, so that when the water starts to be used, The response is fast and fluctuations in water supply pressure (discharge pressure) can be minimized. Also, at event venues, etc., it is possible to change the set time according to the event so that the lack of water supply pressure does not occur during the break time. The present invention is effective not only in schools and event venues, but also in buildings such as movie theaters and theaters where rest times are easily concentrated, such as toilets.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a schematic diagram showing a variable speed water supply apparatus according to the first embodiment of the present invention. This water supply device includes two pumps 1A and 1B for pressurizing water, two motors 2A and 2B for driving the pumps 1A and 1B, respectively, and two units for changing the rotational speed of the motors 2A and 2B. Inverters (transmission means) 3, 3, and a control unit 4 that controls the motors 2 A, 2 B via these inverters 3, 3 to change the rotational speed of the pumps 1 A, 1 B. In addition, although the water supply apparatus which concerns on this embodiment is provided with 2 units | sets of pumps, this invention is not limited to this structure. That is, the water supply apparatus according to the present invention may include only one pump, or may include three or more pumps.

  As shown in FIG. 1, the pumps 1 </ b> A and 1 </ b> B are each connected to a single discharge pipe 10 via a check valve 7. The discharge pipe 10 is connected to a water supply terminal such as a building faucet or a flush toilet. A pressure tank 11 that holds the water pressure (discharge pressure) in the discharge pipe 10 is connected to the discharge pipe 10. Further, the discharge pipe 10 is provided with a pressure sensor 8 for detecting the discharge pressure. The suction ports of the pumps 1 </ b> A and 1 </ b> B are connected to a water receiving tank 12, and an electrode rod (water level detector) 13 for detecting the water level in the water receiving tank 12 is installed in the water receiving tank 12. The electrode rod 13 is electrically connected to the control unit 4, and the control unit 4 monitors the water level of the water receiving tank 12. When the water level of the water receiving tank 12 falls to a predetermined level, the control unit 4 issues a drought warning so that the pumps 1A and 1B are not idling, and stops the pumps 1A and 1B.

  In the vicinity of the discharge ports of the respective pumps 1A and 1B, a flow switch 15 is installed as a flow rate detecting means for detecting that the flow rate of water has decreased. The flow switch 15 sends a signal to the control unit 4 when the flow rate of water discharged from the respective pumps 1A and 1B decreases and reaches a predetermined value. Inverters 3 and 3 are connected to a power source via leakage circuit breakers 16 and 16. A display operation unit 18 is connected to the control unit 4, and the worker performs various settings such as a target pressure and a starting pressure from the display operation unit 18. Further, a timer unit 20 having a clock function is connected to the control unit 4.

  FIG. 2 is a flow diagram showing a normal operation control (constant discharge pressure control) sequence of the water supply apparatus according to this embodiment. A starting pressure for starting the pump 1 </ b> A is preset in the control unit 4 via the display operation unit 18. The control unit 4 determines whether or not the discharge pressure P sent from the pressure sensor 8 is lower than the start pressure Pstart, and when the discharge pressure P becomes lower than the start pressure Pstart (P <Pstart). The pump 1A is started.

  The discharge pressure is compared with the target pressure input from the display operation unit 18 by the control unit 4. When the discharge pressure is lower than the target pressure, the control unit 4 sends a speed increase command to the inverter 3. When the discharge pressure is higher than the target pressure, the control unit 4 sends a deceleration command to the inverter 3. More specifically, the control unit 4 calculates (pressure calculation) the rotational speed N of the pump 1A for making the target pressure Pt and the discharge pressure P coincide with each other. Then, the control unit 4 sends the calculated rotational speed N to the inverter 3 as a command value, and rotates the pump 1A at the rotational speed N. In this way, the control unit 4 controls the motor 2A via the inverter 3 so as to keep the discharge pressure constant. The motor 2B is similarly controlled by the control unit 4.

  Generally, as in this embodiment, the water supply apparatus has a plurality of pumps, and is configured such that a standby pump is automatically started when a failure occurs. The more the faucet is opened and the more water is used, the more it is necessary to increase the speed of the pump. However, when the amount of water used increases in a short time, the pump speed cannot keep up with the demand for water, and the discharge pressure decreases.

  Therefore, in the present embodiment, when the rotational speed of the operating pump 1A increases to its maximum speed and the discharge pressure P is lower than the target pressure Pt (P <Pt) for a predetermined time, the pump 1A is stopped. The middle pump 1B is started (pump addition). At this time, the rotational speed of the pump (first pump) 1A that has been operated in advance is fixed at the maximum speed or a speed near the maximum speed, and the added pump (secondary pump) 1B is operated at the rotational speed N. In addition, since the rotational speed N calculated by the control unit 4 varies according to the amount of water used, the subsequent pump 1B is operated at a variable speed.

  When the amount of water used is reduced and the target pressure can be obtained with one pump, that is, the rotational speed of the subsequent pump 1B during the shift operation is reduced to the minimum rotational speed, and the flow rate of the subsequent pump 1B becomes zero. When the state continues for a predetermined time, the subsequent pump 1B is stopped (pump disconnection), and the first pump 1A is operated again at the rotational speed N.

  The controller 4 stops the pump 1A when water is no longer used. Specifically, when the flow switch 15 is activated and a predetermined time has elapsed, the control unit 4 determines that water is no longer used. When it is determined that water is no longer used, the control unit 4 causes the pump 1A to perform a small water amount stop operation to stop the operation of the pump 1A.

  The small water amount stop operation is an operation of temporarily stopping the pump 1A after increasing the rotational speed of the pump 1A and increasing the discharge pressure. When the pump 1A is stopped, water is held in the discharge pipe 10 by the check valve 7 on the discharge side of the pump 1A. Further, water is sent to the pressure tank 11 communicating with the discharge pipe 10, and the water pressure in the discharge pipe 10, that is, the discharge pressure is held by the pressure tank 11. After the pump 1A is stopped, when the water is used and the discharge pressure falls to the starting pressure (P <Pstart), the pump 1A starts again.

  The reason why the discharge pressure is increased before the stop in the small water amount stop operation is to provide a difference between the start pressure and the discharge pressure so that the pump 1A does not start immediately after the pump 1A stops. The small water amount stopping operation may be a small water amount stopping operation in which the pump 1A is stopped at the target pressure and the starting pressure is set to a value slightly lower than the target pressure, as long as a pressure difference is provided.

  The control unit 4 determines that the discharge pressure has become equal to or lower than the starting pressure, and starts the pump 1A. At this time, since the pump 1A is started from a stopped state, a slight decrease in the discharge pressure (feed water pressure) occurs at the start. Under normal circumstances, since the initial amount of water used is small, the drop in the discharge pressure is within a range that does not hinder. However, when the use of the toilet is concentrated and a large amount of water is used at one time, such as during school holidays, if the pump 1A is started from a stopped state, the pressure increase due to the pump operation will increase the pressure due to the use of water. In some cases, it cannot keep up with the decline. In such a case, complete water shut-off does not occur, but there is a concern that uncomfortable feelings may occur at the beginning of use due to pressure drop.

  Therefore, the water supply apparatus according to the present embodiment performs a standby operation for starting the pump 1A in advance and rotating the pump 1A at a predetermined rotational speed before the time when a large amount of water is expected to be used. . Specifically, when a preset start time is reached, a signal is input from the timer unit 20 to the control unit 4, and the control unit 4 starts the pump 1A to perform a standby operation. The timer unit 20 may be configured separately from the control unit 4 or may be integrated with the control unit 4. When the timer unit 20 is provided separately from the control unit 4, various timers can be used. When the timer unit 20 is integrated with the control unit 4, the time can be set from the display operation unit 18 connected to the control unit 4.

  In the present embodiment, the timer unit 20, the control unit 4, the display operation unit 18, and the inverters 3 and 3 are housed in a single casing as a control panel. The control panel is disposed on a base on which pumps 1A and 1B, motors 2A and 2B, a flow switch 15, a check valve 7, a discharge pipe 10, a pressure sensor 8, and a pressure tank 11 are installed.

  Next, a time setting method and a control operation will be described. The setting of the start time for causing the pump 1A to perform standby operation is manually performed via the timer unit 20. The timer unit 20 of the present embodiment is composed of a 24-hour timer or a calendar timer. The timer unit 20 can set the start time of the pump 1A to a desired date and time. For example, it is possible to set the pump to start at a plurality of times on a specific date, or to start the pump at a predetermined time from Monday to Friday.

  For school holidays, a forced start time of about 6 times a day is set. In this case, the setting items include a time A (6 points) at which the rest time starts, a standby operation time B for continuing the standby operation of the pump 1A at a preset rotation speed after the forced start (initial value: 2 minutes) And C minutes (initial value 30 seconds) for specifying how many minutes before time A the pump 1A is forcibly started. The time C is provided because the start time of the pump 1A can be set more intuitively by setting the time A to the actual rest time. Time B and time C may be set from the display operation unit 18 as set values of the control unit 4. Then, even when the time B and C cannot be set with the commercially available timer unit 20, these times can be set from the display operation unit 18.

  When water is used during the standby operation time B and the target pressure cannot be maintained unless the rotational speed of the pump 1A is set higher than the set speed, the operation mode is changed from the standby operation mode to the normal operation mode (that is, , The discharge pressure constant control operation mode). If water is not used during the standby operation time B, after the elapse of the time B, the rotation speed of the pump 1A is decreased, the normal small water amount stop operation is performed, and the pump 1A is stopped.

  A specific standby operation control sequence is shown in FIG. When the time reaches the start time (time C before time A), standby operation is started. That is, the pump 1A is started at the set speed Ns. The control unit 4 performs a pressure calculation, and calculates the rotational speed N of the pump 1A required to increase the discharge pressure (pressure in the discharge pipe 10) to the target pressure. If N is smaller than Ns, the rotation speed remains Ns, but if N is equal to or greater than Ns, the target pressure cannot be maintained unless the rotation speed of the pump 1A exceeds the set speed Ns. The pump 1A is controlled so as to return to a normal operation (a discharge pressure constant control operation) and to generate a necessary pressure. Even when N is smaller than Ns, the pump 1A is returned to the normal operation when the time TB after the time B has elapsed from the time A. At this time, if the flow rate of water is low, a small amount of water stop operation is performed. If the pump 1A is operated at the start time (time C before the time A), the standby operation is not performed.

  The set speed Ns is set to a rotation speed at which the discharge pressure when the pump 1A rotates at Ns is higher than the starting pressure when water is not used at the water supply end, ie, in a so-called shut-off state. Preferably, the set speed Ns is a rotation speed at which the discharge pressure becomes higher than the minimum pressure required for water supply to the water supply end in the closed state.

  FIG. 4 is a flow diagram showing another control sequence of the standby operation. In this example, the upper limit value of the pump 1A is set as the set speed Ns. At the start time, the pump 1A is started, and a pressure Ps slightly higher than the pressure P at that time (for example, a pressure obtained by adding a predetermined pressure α to the pressure P) is set as a target pressure. The controller 4 calculates the rotational speed N of the pump for reaching the target pressure Ps. If the calculated rotational speed N is lower than the set speed Ns, the control unit 4 transmits the rotational speed N as a command value to the inverter 3 to rotate the pump 1A. On the other hand, if the calculated rotation speed N is equal to or higher than the set speed Ns, the control unit 4 transmits the set speed Ns as a command value to the inverter 3 and limits the rotation speed of the pump 1A to Ns. When the current pressure P is lower than the target pressure Pt in normal operation, the pump 1A returns to normal operation. On the other hand, if the current pressure P is equal to or higher than the target pressure Pt, the pump 1A returns to normal operation at time TB.

  FIG. 5 is a schematic view showing a water supply apparatus according to the second embodiment of the present invention. The water supply apparatus according to the present embodiment includes a relief pipe 22 that communicates between the discharge pipe 10 and the water receiving tank 12 and a relief valve 23 that opens and closes the relief pipe 22. It differs from the water supply apparatus which concerns on embodiment. The other configuration is the same as that of the first embodiment, and thus redundant description thereof is omitted.

  In this embodiment, during the waiting time B, the relief valve 23 is opened and a small amount of water is returned from the discharge pipe 10 to the water receiving tank 12 through the relief pipe 22. After time B has elapsed, the relief valve 23 is closed. If water is not used at that time, a small water amount stop operation is performed and the pump 1A stops. On the other hand, if water is used, the discharge pressure constant control operation which is a normal operation is continued. As shown in FIG. 6, the relief valve 23 is opened when the standby operation is started, and is closed before returning to the normal operation. Since various forms described in this specification can be applied to the operation control while the relief valve 23 is opened, a duplicate description is omitted.

  Also in the present embodiment, the set speed Ns is set to a rotational speed at which the discharge pressure when the pump 1A rotates at Ns is higher than the starting pressure in the shut-off state. Preferably, the set speed Ns is a rotation speed at which the discharge pressure becomes higher than the minimum pressure required for water supply to the water supply end in the closed state. In the present embodiment, during the standby operation, the relief valve 23 is opened, so that unlike the first embodiment, water flows slightly in the closed state.

  If the timer unit 20 is configured by using a calendar timer that can set the start time throughout the year, it is possible to set the forced operation not to be performed during summer vacation or winter vacation. However, since such a calendar timer is generally expensive, the timer unit 20 may be a 24-hour timer. In this case, only a forced start of six times a day occurs, and a wasteful driving operation occurs, but there is no hindrance to the normal water supply operation.

  The gist of the present invention is that when a time when a large amount of water is used can be predicted in advance, a control operation (standby control operation) different from a normal control operation (a constant discharge pressure control operation) is performed before that time, The purpose is to prevent a drop in discharge pressure due to a large amount of water used. In addition to the operation described above, the following operation may be performed as an operation for more effectively preventing the discharge pressure from decreasing.

  In the sequence shown in FIG. 2 and FIG. 3 described above, when water is used during the standby operation and the required amount of water cannot be supplied at the set speed Ns, the pump 1A returns to normal operation and supplies water. To do. Therefore, depending on the setting of the time B and the small water amount stop condition, even if the time TB is not reached, the small water amount stop operation may be performed and the pump may stop. Therefore, during the time B, the sequence shown in FIG. 7 is controlled so that at least one of the pumps 1A and 1B does not fall below the set speed Ns.

  As shown in FIG. 7, when the start time comes, the pump is started and rotated at the set speed Ns. The control unit 4 compares the current discharge pressure with a preset target pressure, and calculates the rotational speed N required to reach the target pressure (pressure calculation). Thereafter, the control unit 4 determines whether or not there is one operating pump. When the number of operating pumps is one and the calculated rotation speed N is lower than the set speed Ns, the control unit 4 rotates the pump using the set speed Ns as a command value. On the other hand, when there is a pump (first pump) that is operated in advance and / or the rotational speed N is equal to or higher than the set speed Ns, the control unit 4 uses the calculated value N as a command value to switch the pump (late pump). Rotate. Thereafter, the pump is added or disconnected in accordance with the additional disconnection control shown in FIG. When time TB is reached, the operation of the water supply apparatus is switched to normal operation.

  When there are a plurality of pumps, the standby operation may be performed with two or more pumps. FIG. 8 is a flowchart showing a control sequence when a plurality of pumps are in standby operation. As shown in FIG. 8, when the standby operation starts, a plurality of pumps are started at a uniform speed and operated at a set speed Ns. During the standby operation, a plurality of pumps are operated so that the rotational speed does not fall below Ns. When time B elapses from the start time and reaches time TB, one pump is left and the other pumps are stopped to return to normal operation. The pump does not stop instantaneously, but if it is slowly stopped while controlling the pressure with a single operating pump, the fluctuation of the pressure can be reduced. If the target pressure cannot be maintained when the pumps are stopped, the plurality of pumps may be returned to the normal operation while being operated in parallel.

  9 and 10 are flowcharts showing another control sequence when a plurality of pumps are in standby operation. In the control sequences shown in FIGS. 9 and 10, when one pump is operating at the start time (time C before time A), the stopped pump is caused to perform a standby operation. The control unit 4 determines whether or not pump addition is necessary. If it is determined that pump addition is necessary, the control unit 4 quickly adds the pump to suppress the pressure drop.

  More specifically, at the start time, the control unit 4 determines whether there is an operating pump. If there is no pump in operation, the first pump is started and standby operation is performed. On the other hand, if there is a pump in operation, the additional pump is started. In the control sequence shown in FIGS. 9 and 10, when there is no pump in operation at the start time, the standby operation is executed according to the control sequence of FIG. However, the present invention is not limited to this, and may be combined with other control sequences described above.

  In FIG. 9, during the standby operation, at least one pump is operated without falling below the set speed Ns. That is, both the additional pump (see the flow diagram on the left side of FIG. 9) and the first pump (see the flow diagram on the right side of FIG. 9) rotate at a rotational speed that is equal to or higher than the set speed Ns during standby operation. Is done.

  Here, the flow diagram on the left side of FIG. 9 will be described. As described above, when there is an operating pump, an additional pump (later pump) is started and operated at the set speed Ns. The control unit 4 compares the current discharge pressure with a preset target pressure, and calculates a rotation speed N for reaching the target pressure (pressure calculation). Then, the control unit 4 rotates the starting pump at the rotation speed N using the calculated rotation speed N as a command value. If an additional determination is made and the target pressure cannot be reached even when the rotational speed of the starting pump increases to the maximum speed, the starting pump is operated at a fixed speed at the maximum speed, and the command destination of the rotational speed N is set as the subsequent pump. And the subsequent pump is shifted.

  Further, when it is determined that the command value N for the pump (the first pump or the second pump) is the minimum speed and there is no flow rate of the pump, the pump is disconnected. If the pump that has been operated at a variable speed N at the time of disengagement is a subsequent pump, since the first pump is operating at the maximum speed, the subsequent pump is fixed at the rotational speed Ns, The command destination of the rotational speed N is returned to the starting pump. On the other hand, if the pump that has been operated at a variable speed N at the time of disconnection is a starter pump, the starter pump can provide the necessary pressure just by operating the subsequent pump at the speed Ns. To stop. Since this situation is the same as when the pump was started in the right flow diagram of FIG. 9, the subsequent control shifts to the right flow diagram of FIG. When time TB is reached in the left flow diagram, the subsequent pump is stopped and the normal operation is resumed. At this time, if the command destination of the rotational speed N is the late pump, it is sufficient to return to the normal operation while shifting the late pump.

  The control sequence shown in FIG. 10 is a combination of the control sequence shown in FIG. 7 and the control sequence shown in FIG. In this control sequence, when the start time comes when the starting pump is operating, the additional pumps are started, and then these pumps are shifted to the uniform speed operation. After the uniform speed operation, the pump is operated according to the control sequence shown in FIG.

  FIG. 11 is a flow diagram showing a modification of the control sequence shown in FIGS. 9 and 10. In this example, it is added when the rotational speed of the starting pump is equal to or higher than the predetermined rotational speed close to the maximum speed Nmax, and there is a high possibility that the pump must be added if the amount of water used increases rapidly due to the use of the toilet, etc. The pump is started. That is, when the rotational speed N of the starting pump exceeds 85% of Nmax, the additional pump is started and operated at the rotational speed Ns. Since each control sequence shown in FIG. 9 and FIG. 10 can be applied to the control sequence after the pump is started, redundant description is omitted.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the technical idea described in the claims and the specification and drawings. Is possible.

It is a schematic diagram which shows the variable speed water supply apparatus which concerns on the 1st Embodiment of this invention. It is a flow diagram which shows the normal driving | operation control (discharge pressure constant control) sequence of the water supply apparatus which concerns on the 1st Embodiment of this invention. It is a flow diagram which shows the control sequence of standby operation. It is a flow diagram which shows the other control sequence of standby operation. It is a schematic diagram which shows the variable speed water supply apparatus which concerns on the 2nd Embodiment of this invention. It is a flow diagram which shows the control sequence of the standby driving | operation in 2nd Embodiment. It is a flow diagram which shows the other control sequence of standby operation. It is a flowchart which shows a control sequence when carrying out standby operation of a some pump. It is a flowchart which shows the other control sequence when carrying out standby operation of a some pump. It is a flowchart which shows the other control sequence when carrying out standby operation of a some pump. It is a flowchart which shows the other control sequence when carrying out standby operation of a some pump.

Explanation of symbols

1A, 1B Pump 2A, 2B Motor 3 Inverter (transmission means)
4 Control Unit 7 Check Valve 8 Pressure Sensor 10 Discharge Pipe 11 Pressure Tank 12 Receiving Tank 13 Electrode Bar (Water Level Detector)
15 Flow switch 16 Leakage circuit breaker 18 Display operation unit 20 Timer unit 22 Relief pipe 23 Relief valve

Claims (6)

A pump,
A motor for driving the pump;
Transmission means for changing the rotational speed of the motor;
A controller that controls the water pressure on the discharge side of the pump by changing the rotational speed of the pump via the speed change means;
The controller is
Stopping the pump when the flow rate of water on the discharge side of the pump drops to a predetermined value,
When the water pressure on the discharge side of the pump has dropped to a preset starting pressure, the pump is started,
A variable speed water supply apparatus configured to rotate the pump at a predetermined rotational speed when the pump is stopped at a preset start time.   The variable speed water supply apparatus according to claim 1, wherein there are a plurality of start times, and the plurality of start times are configured to be changeable.   The control unit controls the rotation speed of the pump so that the water pressure on the discharge side of the pump becomes a predetermined target pressure after a predetermined time has elapsed from the start time. 2. The variable speed water supply apparatus according to 2. An escape pipe for escaping water discharged from the pump;
A relief valve provided on the relief pipe;
4. The apparatus according to claim 1, wherein when the pump is stopped at the start time, the pump is started after opening the relief valve. 5. Variable speed water supply device.   The predetermined rotation speed is a rotation speed at which the water pressure on the discharge side is higher than the starting pressure in a deadline state where water is not used at a water supply end. The variable speed water supply apparatus according to one item.   The predetermined rotation speed is a rotation speed at which the water pressure on the discharge side is higher than the minimum pressure required for water supply to the water supply end in a shut-off state where water is not used at the water supply end. The variable speed water supply apparatus as described in any one of Claims 1 thru | or 4.

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