JP6427364B2 - Water supply device - Google Patents

Description

  The present invention relates to a water supply apparatus having a normal operation mode and a backup operation mode.

  For example, a water supply apparatus of the water supply direct connection type having a structure directly connected to a water supply pipe has a pump device, a flow sensor, and a pressure sensor provided in a flow path from the water supply pipe to an outlet such as a faucet. ing.

  The pump device has a pump that can pressurize water supplied from a water pipe, and a control panel that controls driving of the pump. The flow sensor is configured to be able to detect a predetermined flow rate. The flow sensor is turned on when the flow rate is equal to or more than a predetermined flow rate, and transmits a signal to the control board. The pressure sensor is configured to detect the pressure in the flow path and to transmit the detection result to the control panel.

  The control panel starts the pump based on the detection result of the pressure sensor. Specifically, the control panel starts the pump when the pressure in the flow is less than or equal to the start pressure of the pump. The control panel also controls the operation of the pump based on the detection result of the flow sensor.

  In this type of water supply apparatus, when the pressure sensor fails, the backup operation mode is set. Specifically, in the backup operation mode, when it is determined that the pressure sensor has failed, the control panel starts the pump at preset time intervals, for example, 5 minutes. Then, when it is determined that water is being used based on the detection result of the flow sensor during driving of the pump, the control panel increases driving of the pump. In the backup operation mode, when it is determined that water is not used based on the detection result of the flow sensor during driving of the pump, the control panel decreases driving of the pump.

JP, 2010-25119, A

  As described above, the water supply apparatus having the backup operation mode for starting the pump at predetermined time intervals has the following problems. That is, when the pump is started at predetermined time intervals, the pump may be started even when water is not actually used, and power may be consumed wastefully.

  An object of this invention is to provide the water supply apparatus which can suppress consumption of the electric power at the time of backup operation mode.

The water supply apparatus of the present invention includes a flow path unit, a pump, a flow sensor, a pressure sensor, and a control unit. The flow path unit guides the water supplied from the supply source to the discharge port at the end. The pump is provided in the flow path portion and discharges the water supplied from the supply source to the discharge port side. The flow sensor is provided downstream of the pump in the flow passage portion, can detect at least a predetermined flow rate of the water, and transmits a signal when the predetermined flow rate is detected. The pressure sensor is provided downstream of the pump in the flow passage portion to detect the pressure in the flow passage portion, and transmits a detection result. The control unit controls the start of the pump based on the detection result of the pressure sensor in a state where the pressure sensor is not broken, and the detection result of the flow sensor is detected when the pressure sensor is broken. Based on the control of the start of the pump.
The flow path portion includes a plurality of branch flow path portions which are parallel to each other, and a merging portion in which the branch flow path portions merge at a downstream side. The pump is provided in each of the plurality of branch flow channel portions. The pressure sensor is provided downstream of the junction in the branch flow channel portion. The flow sensor is provided in each of the plurality of branch flow channel portions. The control unit, when the pressure sensor breaks down, determines that the number of operating pumps is that the water is flowing in the branch flow passage portion based on the detection result of the flow sensor. If the number of driven pumps is increased, the number of operating pumps is greater than the number of branch flow path portions determined to be flowing water among the branch flow path portions, Reduce the number of pumps driven.

  ADVANTAGE OF THE INVENTION According to this invention, the water supply apparatus which can suppress consumption of the electric power at the time of backup operation mode can be provided.

BRIEF DESCRIPTION OF THE DRAWINGS Schematic which shows the water supply apparatus which concerns on the 1st Embodiment of this invention. Schematic which shows the water supply apparatus which concerns on the 2nd Embodiment of this invention.

  A water supply apparatus according to a first embodiment of the present invention will be described with reference to FIG. FIG. 1 is a schematic view showing a water supply device 10. The water supply apparatus 10 is formed so as to be able to lead water, which is an example of liquid, from the water pipe 20 to a faucet 30, which is an example of a discharge port.

  As shown in FIG. 1, the water supply apparatus 10 is a water supply apparatus of a water pipe direct connection type. The water supply apparatus 10 includes a water supply pipe 40 forming a flow passage from the water pipe 20 to the faucet 30, a pump apparatus 50 configured to be able to pressurize water supplied from the water pipe 20 and discharge it downstream, A pressure sensor 60 configured to detect the pressure in the pipe 40, a flow sensor 70 configured to detect whether the flow rate in the water supply pipe 40 is a predetermined flow rate or more, and the flow rate in the water supply pipe 40 And an accumulator 90 for equalizing the fluctuation of

  The water supply pipe 40 includes a first water supply pipe 41 connected to the water pipe 20, a second water supply pipe 42 and a third water supply pipe 43 branched from the first water supply pipe 41, and a faucet And a fourth water supply pipe portion 44 connected to 30. The second water supply pipe 42 and the third water supply pipe 43 are parallel to each other, and merge at the merging portion 45 downstream. The fourth water supply pipe portion 44 connects the merging portion 45 and the faucet 30. The first water supply pipe portion 41 is provided with a backflow prevention device 46. The backflow prevention device 46 is configured to be capable of preventing backflow of water from the first water supply pipe portion 41 to the water pipe 20.

  The pump device 50 includes a first pump 51 provided in the second water supply pipe 42, a second pump 52 provided in the second water supply pipe 42, a first pump 51, and a second pump 52. And a control panel 53 configured to be able to control the drive of the

  The first pump 51 and the second pump 52 have the same configuration, for example, a pump unit having an impeller that applies pressure to water by rotating, and a drive configured to be able to rotate the impeller. And an electric motor as an example of the unit.

  A first check valve 47 is provided downstream of the first pump 51 in the second water supply pipe portion 42. The first check valve 47 is formed so as to prevent the water discharged from the first pump 51 from flowing back to the first pump 51 side. A gate valve 48 is provided at a position upstream of the first pump 51 and a position downstream of the first check valve 47 in the second water supply pipe 42.

  A second check valve 49 is provided downstream of the second pump 52 in the third water supply pipe 43. The second check valve 49 is formed so as to prevent the water discharged from the second pump 52 from flowing back to the second pump 52 side. A gate valve 48 is provided at a position upstream of the second pump 52 and a position downstream of the second check valve 49 in the third water supply pipe 43.

  The accumulator 90 is provided to the fourth water supply pipe 44. The flow sensor 70 is provided to the fourth water supply pipe 44. The flow sensor 70 is a so-called paddle type flow sensor. The flow sensor 70 is turned on when the flow rate of water flowing through the fourth water supply pipe 44 is equal to or higher than a predetermined flow rate, and is configured to be able to transmit a signal to the control panel 53. The flow sensor 70 is off when the flow rate of the water flowing through the fourth water supply pipe 44 is less than the predetermined flow rate, and does not transmit a signal.

  The predetermined flow rate is determined in advance. In the present embodiment, the predetermined flow rate is, for example, a flow rate of water generated when the faucet 30 is opened in a state where all the pumps, that is, the pumps 51 and 52 are not driven. The degree of opening of the faucet 30 at this time is the degree of opening normally when water is used, and is determined in advance, and can be obtained from, for example, an experiment. That is, when the flow sensor 70 is turned on, water is used. Alternatively, the faucet 30 is opened to use water.

  Further, in the state where the flow sensor 70 is in the off state and the signal is not transmitted to the control board 53, it is determined that there is no flow, in other words, it is determined that no water flows from the faucet 30.

  The pressure sensor 60 is provided to the fourth water supply pipe 44. The pressure sensor 60 detects the pressure in the fourth water supply pipe portion 44, and the control panel 53 can detect the detection result. The control panel 53 controls the first pump 51 and the second pump 52 in the normal operation mode or the backup operation mode according to the detection result of the pressure sensor 60 and the presence or absence of the signal from the flow sensor 70. .

  Next, the operation of the water supply device 10 will be described. First, the normal operation mode will be described. The normal operation mode is an operation mode in a state where the pressure sensor 60 is not broken. The pressure sensor 60 always transmits the detection result to the control board 53. Alternatively, the pressure sensor 60 transmits the detection result to the control board 53 at predetermined intervals determined in advance. When the pressure sensor 60 normally receives a signal, the control panel 53 determines that the pressure sensor 60 is not broken and adopts the normal operation mode.

  The water in the water supply pipe 40 is discharged from the faucet 30 by opening the faucet 30. In addition, since the water supply apparatus 10 is a water supply apparatus of a water pipe direct connection type, even if the first pump 51 and the second pump 52 are not driven, the pressure in the water pipe 20 causes water to be reduced. Is discharged from the faucet 30.

  However, since the pressure in the water pipe 20 is insufficient for discharging sufficient water from the faucet 30, the pressure in the water supply pipe 40 decreases. The control panel 53 starts the first pump 51 or the second pump 52 if it is determined that the pressure in the water supply pipe 40 has become equal to or lower than the start pressure based on the detection result of the pressure sensor 60. The pump to be started out of the first pump 51 or the second pump 52 is determined in advance. Further, the control panel 53 periodically switches the operation of the first pump 51 and the operation of the second pump 52.

  The control panel 53 stops the driving pump when it receives no signal from the flow sensor 70 while the pump is being driven.

  Next, the backup operation mode will be described. The backup operation mode is an operation mode when the pressure sensor 60 breaks down. In the present embodiment, as an example, when the control panel 53 does not receive a signal from the pressure sensor 60, the control panel 53 determines that the pressure sensor 60 is broken, and shifts from the normal operation mode to the backup operation mode.

  The water in the water supply pipe 40 is discharged from the faucet 30 by opening the faucet 30. Further, even if the first pump 51 and the second pump 52 are not driven, water is discharged from the faucet 30 by the pressure in the water pipe 20. For this reason, even when the first pump 51 and the second pump 52 are not driven, a flow of water occurs in the water supply pipe 40. Therefore, the flow sensor 70 is turned on by the flow of water, and transmits a signal to the control panel 53.

  As described above, the predetermined flow rate at which the flow sensor 70 is in the on state is the flow rate of water generated when the faucet 30 is opened when all the pumps, that is, the pumps 51 and 52 are not driven. The degree of opening of the faucet 30 at this time is usually the degree of opening when water is used, and is determined in advance.

  Therefore, the flow sensor 70 can detect the flow of water caused by the faucet 30 being opened in a state where the first pump 51 and the second pump 52 are stopped.

  When the control board 53 receives a signal from the flow sensor 70 in the backup operation mode and the first pump 51 and the second pump 52 are not driven, the first pump 51 and the second pump 52 Start one of the predetermined ones.

  By receiving a signal from the flow sensor 70, the control panel 53 determines that water is flowing from the faucet 30, that is, water is used. The pump driven in the backup operation mode is determined in advance.

  For example, only one of the first pump 51 and the second pump 52 may be operated. Alternatively, the first pump 51 and the second pump 52 may be operated alternately. Also, the operation of the driven pump is preset. In the present embodiment, as an example, operation is performed at a constant frequency. The frequency referred to here is the rotational speed of the impeller provided in the pump. The control panel 53 supplies power to the driven pump such that the rotational speed of the impeller becomes constant.

  When the control panel 53 receives no signal from the flow sensor 70, it stops driving the pump in operation. The state where the signal from the flow sensor 70 is not received means that there is no flow of water in the water supply pipe 40, that is, the faucet 30 is closed and water is not used.

  In the water supply device 10 configured as described above, consumption of power in the backup operation mode can be suppressed. This point is explained concretely. For example, when the pressure sensor 60 breaks down, it is conceivable to start the pump periodically as a backup operation mode.

  In such a backup operation mode, the pump is started even when water is not actually used. For this reason, since the pump is started even when it is not necessary to drive the pump, the power for driving the pump is wasted.

  However, in the present embodiment, during the backup operation, the pump is started based on a signal from the flow sensor 70 indicating that water has actually been used. For this reason, since the pump is not unnecessarily driven, it is possible to suppress the consumption of the power in the backup operation mode.

  In the present embodiment, the flow sensor 70 is turned on when the flow rate of water flowing in the water supply pipe 40 is equal to or more than a predetermined flow rate, and has a configuration capable of transmitting a signal.

  As another example, instead of the flow sensor 70, a flow sensor capable of detecting the flow rate flowing through the water supply pipe 40 may be used. The flow sensor transmits a signal corresponding to the flow rate of water flowing in the water supply pipe 40 to the control panel 53. When the flow sensor is used, the control panel 53 starts the pump if it is determined that the flow of water is generated based on the detection result of the flow sensor, that is, when the flow rate becomes zero or more. Alternatively, if it is determined that the flow rate is equal to or more than the predetermined flow rate described above, the pump may be started.

  Next, a water supply apparatus according to a second embodiment of the present invention will be described with reference to FIG. In the present embodiment, the water supply device 10A will be described. In addition, the structure which has a function similar to 1st Embodiment attaches | subjects the code | symbol same as 1st Embodiment, and abbreviate | omits description.

  In the present embodiment, the water supply apparatus 10A differs from the first embodiment in the water supply pipe 40 and the pump device 50, and instead of the flow sensor 70, the first flow sensor 101 and the second flow sensor The point which is provided with 102 and the 3rd flow sensor 103 differs from a 1st embodiment. The other points are the same as the first embodiment. The differences will be specifically described.

  FIG. 2 is a schematic view showing a water supply apparatus 10A of the present embodiment. As shown in FIG. 2, the water supply pipe 40 further includes a fifth water supply pipe portion 110. The fifth water supply pipe portion 110 branches from the first water supply pipe portion 41, and merges with the merging portion 45 downstream. The 2nd water supply pipe part 42, the 3rd water supply pipe part 43, and the 5th water supply pipe part 110 are mutually parallel.

  The pump device 50 further includes a third pump 111. The third pump 111 is provided to the fifth water supply pipe 110. The third pump 111 has the same configuration as the first pump 51, and the drive is controlled by the control panel 53.

  A third check valve 112 is provided downstream of the third pump 111 in the fifth water supply pipe portion 110. The third check valve 112 is formed so as to prevent the water discharged from the third pump 111 from flowing back to the third pump 111 side.

  The first flow sensor 101 is provided downstream of the first check valve 47 in the second water supply pipe 42. The first flow sensor 101 is turned on when the flow rate of water flowing through the second water supply pipe 42 is equal to or more than a predetermined flow rate, and transmits a signal to the control panel 53. The first flow sensor 101 is in the OFF state when the flow rate of water flowing through the second water supply pipe portion 42 is less than the predetermined flow rate described above, and does not transmit a signal.

  The predetermined flow rate at which the first flow sensor 101 is in the on state is the flow rate of water generated when the faucet 30 is opened when all the pumps, that is, the pumps 51, 52, and 111 are not driven. It is a value divided by the number of water supply pipes formed in parallel with each other on the upstream side of the part 54. In the present embodiment, the water supply pipe portions formed in parallel with each other on the upstream side of the merging portion 54 are the water supply pipe portions 42, 43, 110, and there are three. The degree of opening of the faucet 30 at this time is the degree of opening normally when water is used, and is determined in advance, and can be obtained from, for example, an experiment. In other words, in the present embodiment, the predetermined flow rate at which the first flow sensor 101 is in the on state is one-third of the predetermined flow rate at which the flow sensor 70 is in the on state described in the first embodiment. Become.

  As described above, in the case where there are flow path portions parallel to each other in the upstream of the faucet 30, and the flow sensors are provided in all the flow path portions parallel to one another, these flow sensors are turned on in a predetermined state The flow rate is the flow rate of water flowing to at least one of the parallel flow path portions when the faucet 30 is opened with the opening degree open when using normal water when all the pumps are not driven. It becomes.

  In other words, the predetermined flow rate is Q1, and the flow rate discharged from the faucet 30 when the faucet 30 is opened is Q2 when the faucet 30 is opened with an open degree when using normal water when all the pumps are not driven. Assuming that the number of flow path parts to be D is D, then Q1 = Q2 / D.

  The second flow sensor 102 is provided downstream of the second check valve 49 in the third water supply pipe 43. The second flow sensor 102 is the same as the first flow sensor 101. The second flow sensor 102 is turned on when the flow rate of water flowing through the third water supply pipe 43 is equal to or greater than a predetermined flow rate, and transmits a signal to the control panel 53. The second flow sensor 102 is in the OFF state when the flow rate of water flowing through the third water supply pipe 43 is less than the above-described predetermined flow rate, and does not transmit a signal.

  The third flow sensor 103 is provided downstream of the third check valve 112 in the fifth water supply pipe portion 110. The third flow sensor 103 is the same as the first flow sensor 101. The third flow sensor 103 is turned on when the flow rate of water flowing through the fifth water supply pipe portion 110 is equal to or more than a predetermined flow rate, and transmits a signal to the control panel 53. The third flow sensor 103 is in the off state when the flow rate of water flowing through the fifth water supply pipe portion 110 is less than the above-described predetermined flow rate, and does not transmit a signal.

  Next, the operation of the water supply device 10A will be described. First, the normal operation mode of the water supply device 10A will be described. The water in the water supply pipe 40 is discharged from the faucet 30 by opening the faucet 30. In addition, since the water supply apparatus 10A is a water supply apparatus of a water pipe direct connection system, even if the pumps 51, 52, 111 are not driven, water is supplied from the water supply pipe 41 by the pressure in the water pipe 20. , 42, 110 and is discharged from the faucet 30.

  However, since the pressure in the water pipe 20 is insufficient for discharging sufficient water from the faucet 30, the pressure in the water supply pipe 40 decreases. When the control panel 53 determines that the pressure in the water supply pipe 40 has become equal to or lower than the start pressure based on the detection result of the pressure sensor 60, the control board 53 starts one of the pumps 51, 52, 112 which has been determined in advance. Let

  Further, the control panel 53 determines the number of pumps to be driven based on the detection results of the flow sensors 101, 102, 103. Assuming that the number of flow sensors receiving signals is N1 and the number of pumps being driven is N2 in this embodiment, the control panel 53 increases the number of pumps to be driven if N2 ≦ N1. Set up. When N2> N1, the number of driven pumps is decreased. The order in which the pumps 51, 52, 112 start up and the order in which they decrease are predetermined.

  Next, the backup operation mode will be described. In the present embodiment, even if the driving of the pumps 51, 52, 111 is stopped, the water in the water supply pipe 40 is discharged by opening the faucet 30, and the pressure in the water pipe 20. As the water flows in the water supply pipe 40, the water flows in at least one of the water supply pipe portions 42, 43, 112.

  Among the water supply pipe sections 42, 43, 112, the flow sensor provided in the water supply pipe section through which water of a predetermined flow rate or more flows is turned on, and transmits a signal to the control panel 53. When the control panel 53 receives a signal from at least one of the flow sensors 101, 102, 103, it is determined that water of a predetermined flow rate is flowing in at least one of the water supply pipe portions 41, 42, 110. Of the pumps 51, 52, 112, one of the pumps determined in advance is driven.

  Further, assuming that the number of flow sensors receiving signals is N1 and the number of driven pumps is N2, the control board 53 increases the number of driven pumps when N2 ≦ N1. When N2> N1, the number of driven pumps is decreased. The order in which the pumps 51, 52, 112 start up and the order in which they decrease are predetermined.

  Alternatively, when the control panel 53 receives a signal from at least one of the flow sensors 101, 102, and 103, it determines that water is flowing in the water supply pipe portion provided with the flow sensor that has transmitted the signal, The pump provided in the water supply pipe may be started.

  In the present embodiment, the same effects as in the first embodiment can be obtained. In the present embodiment, the pump can be driven according to the amount of water used even in the backup operation mode. This point will be specifically described.

  The flow rate of water flowing through the water supply pipe 40 changes according to the degree of opening of the faucet 30. More specifically, when the amount of water required by the user is large, the user opens the faucet widely. Alternatively, in the case where there are a plurality of faucets 30, if a plurality of faucets are opened at the same time, the amount of water required is increased.

  Thus, when the amount of water required is large, the water will flow through the water supply pipe other than the water supply pipe provided with the driving pump. Thus, the number N2 of pumps becomes equal to or less than the number N1 of flow sensors transmitting signals by the flow of water through the water supply pipe portion where the pumps are not driven.

  Therefore, when N2 is equal to or less than N1, the control panel 53 determines that the amount of water required is large, and increases the number of pumps to be driven.

  If the number N1 of flow sensors transmitting signals is less than the number N2 of pumps being driven, it is determined that the amount of water required is small, and the number of pumps being driven is reduced. Set up.

  By operating the pump in this manner, it is possible to perform an operation suitable for the amount of water actually required even in the backup operation mode.

  Also in the present embodiment, as described in the first embodiment, the flow sensors 101, 102, and 103 may be configured to detect the flow rate in the water supply pipe and transmit a signal according to the flow rate. . In this case, if it is determined that the flow of water is generated based on the detection results of the flow sensors 101, 102, and 103, that is, if the flow rate of water becomes larger than zero, the control panel 53 starts the pump. Alternatively, the pump may be started if it is determined that the flow rate is equal to or more than the predetermined flow rate described above.

  In the first embodiment and the second embodiment, the water supply devices 10 and 10A are water supply devices of the water pipe direct connection type directly connected to the water pipe 20. As another example, the water supply apparatus 10, 10A may not be a structure in which water is supplied from the water pipe 20, but may be a water supply apparatus in which water is supplied from a water receiving tank. Even in this case, when the faucet 30 is opened in a state where all the pumps are not driven, water flows in the water supply pipe 40 and is discharged from the faucet 30 by the pressure in the water receiving tank. And by detecting the flow by the pressure in the water receiving tank which is not caused by the drive of the pump, the start of the pump can be controlled in the backup operation mode.

  As described above, the present invention is effective for a water supply apparatus connected to a supply source capable of supplying water having a certain pressure, such as a water pipe or a water storage tank.

  However, even if there is no flow due to the pressure of the water supplied from the supply source, the water is discharged from the discharge port in a state in which the drive of all the pumps is stopped, and a flow occurs in the flow path portion, By detecting this flow, the pump may be started in the backup operation mode.

The present invention is not limited to the above-described embodiment as it is, and at the implementation stage, the constituent elements can be modified and embodied without departing from the scope of the invention. In addition, various inventions can be formed by appropriate combinations of a plurality of components disclosed in the above-described embodiment. For example, some components may be deleted from all the components shown in the above-described embodiment. Furthermore, the configurations of different embodiments may be combined.
In the following, the invention described in the original claims of the present application is appended.
[1]
A flow passage for guiding water supplied from the supply source to the outlet of the end;
A pump provided in the flow path portion and discharging the water supplied from the supply source to the discharge port side;
A flow sensor which is provided downstream of the pump in the flow path portion, is capable of detecting at least a predetermined flow rate of the water, and transmits a signal when the predetermined flow rate is detected;
A pressure sensor which is provided downstream of the pump in the flow path portion to detect the pressure in the flow path portion and transmit the detection result;
In a state where the pressure sensor is not broken, the start of the pump is controlled based on the detection result of the pressure sensor, and when the pressure sensor fails, the pump is controlled based on the detection result of the flow sensor. Control unit to control start-up
A water supply apparatus comprising:
[2]
The flow path portion includes a plurality of branch flow path portions that are parallel to one another, and a merging portion in which the branch flow path portions merge downstream.
The pump is provided in each of the plurality of branch flow path portions,
The pressure sensor is provided downstream of the merging portion in the branch flow path portion,
The flow sensor is provided in each of the plurality of branch flow channel portions,
The control unit, when the pressure sensor breaks down, determines that the number of operating pumps is that the water is flowing in the branch flow passage portion based on the detection result of the flow sensor. If the number of driven pumps is increased, the number of operating pumps is greater than the number of branch flow path portions determined to be flowing water among the branch flow path portions, Reduce the number of pumps driven
The water supply apparatus according to [1], characterized in that

  DESCRIPTION OF SYMBOLS 10 ... Water supply apparatus, 20 ... Water pipe (supply source) 40 ... Water supply pipe (flow path part) 42 ... 2nd water supply pipe part (branch flow-path part) 43 ... 3rd water supply pipe part (branch flow) Road portion) 45: Merge portion 51: first pump 52: second pump 53: control panel (control portion) 60: pressure sensor 70: flow sensor 101: first flow sensor 102: second flow sensor, 103: third flow sensor, 110: fifth water supply pipe portion (branch flow path portion) 111: third pump.

Claims (1)

A flow passage for guiding water supplied from the supply source to the outlet of the end;
A pump provided in the flow path portion and discharging the water supplied from the supply source to the discharge port side;
A flow sensor which is provided downstream of the pump in the flow path portion, is capable of detecting at least a predetermined flow rate of the water, and transmits a signal when the predetermined flow rate is detected;
A pressure sensor which is provided downstream of the pump in the flow path portion to detect the pressure in the flow path portion and transmit the detection result;
In a state where the pressure sensor is not broken, the start of the pump is controlled based on the detection result of the pressure sensor, and when the pressure sensor fails, the pump is controlled based on the detection result of the flow sensor. A control unit that controls startup ;
Equipped with
The flow path portion includes a plurality of branch flow path portions that are parallel to one another, and a merging portion in which the branch flow path portions merge downstream.
The pump is provided in each of the plurality of branch flow path portions,
The pressure sensor is provided downstream of the merging portion in the branch flow path portion,
The flow sensor is provided in each of the plurality of branch flow channel portions,
The control unit, when the pressure sensor breaks down, determines that the number of operating pumps is that the water is flowing in the branch flow passage portion based on the detection result of the flow sensor. If the number of driven pumps is increased, the number of operating pumps is greater than the number of branch flow path portions determined to be flowing water among the branch flow path portions, A water supply apparatus characterized by reducing the number of driven pumps .

Images