초록 ▼

A water booster control system designed with a controller having an algorithm that determines optimum starting parameters for one or more pumps is disclosed. The water booster control system supplies water to a location at specified operating parameters. Water enters a suction manifold, travels thro

A water booster control system designed with a controller having an algorithm that determines optimum starting parameters for one or more pumps is disclosed. The water booster control system supplies water to a location at specified operating parameters. Water enters a suction manifold, travels through pipes, and into the pumps. The pumps accelerate the water to the desired pressure and/or flow rate and discharge the water through pipes and out of a discharge manifold. One or more of the components of the water booster control system are monitored during use, and data regarding the parameters is displayed locally and/or remotely. Alarms are specified relating to one or more of the operating parameters and the alarm conditions may be displayed locally and/or remotely. A user may make modifications to the system locally and/or remotely through a screen and/or through a remote device using a smart phone application.

대표청구항 ▼

1. A water control booster system, comprising: a pump in communication with a drive unit;a user interface; anda controller in communication with the pump and the drive unit, the controller designed to control at least one operating parameter of the pump, wherein the controller further includes a pro

1. A water control booster system, comprising: a pump in communication with a drive unit;a user interface; anda controller in communication with the pump and the drive unit, the controller designed to control at least one operating parameter of the pump, wherein the controller further includes a processor and memory storing an algorithm stored thereon that is designed to determine the at least one operating parameter of the pump, wherein the at least one operating parameter is one of a pump sequence mode, a pump rotation, a lead pump, and a lag pump, andthe water booster control system is further designed to allow a user to enter at least one customizable alarm threshold through the user interface the processor comparing the at least one operating parameter with the alarm threshold and transmitting a notification to the user remotely when the threshold is breached;wherein the algorithm is configured to carry out the steps of: determining a set point defined by at least one of a system pressure and a system flow for which the water control booster system demands;capturing at least one of a minimum speed and a maximum speed of the pump;storing the at least one minimum speed and maximum speed of the pump on the controller;initiating the one or more additional pumps at a pre-determined time/frequency rate to meet the set point; andautomatically adjusting the at least one operating parameter when the set point is not met. 2. The water control booster system of claim 1, wherein the minimum speed is the speed at which the pump produces flow and increases pressure above an incoming pressure of the water control booster system. 3. The water control booster system of claim 1, wherein the maximum speed is the speed at which the pump can operate without allowing the drive unit to experience an overcurrent. 4. The water control booster system of claim 1, wherein the at least one customizable alarm threshold includes one of an alarm indicating a discharge pressure of water exiting the water booster control system, an alarm indicating a suction pressure, an alarm indicating a status of the one or more drive units, and an alarm indicating a fault condition has been triggered by at least one of a discharge pressure, the suction pressure, and a flow rate. 5. The water control booster system of claim 1, further comprising a network in communication with the controller and a remote device, wherein the remote device is configured to receive the breached alarm threshold. 6. The water control booster system of claim 5, wherein the remote device includes at least one of a networked workstation, a laptop, a smart phone, and a handheld tablet. 7. The water control booster system of claim 1, wherein the controller is a programmable logic controller (PLC) that includes a processor configured to facilitate operation of the water booster control system, the PLC having stored thereon a proportional integral derivative (PID) loop configured to control the at least one operating parameter of the pump. 8. The water control booster system of claim 7, wherein the PID is further configured to calculate a difference between a set process variable and a desired set point, and calculate an error value, based on the calculated difference, to adjust at least one input parameter and operational parameters to minimize the error value. 9. The water control booster system of claim 1, wherein the user interface is a computer implemented user interface that includes a touch-screen display configured for the user to manipulate. 10. A method of operating one of more pumps in a water booster system while in operation, comprising the steps of: receiving a first pump parameter input through a computer implemented user interface, the first pump parameter defined by at least one of a pump sequence mode selection, a pump rotation selection, and a lead pump selection;receiving an alarm indicating a fault condition, wherein the alarm is transmitted to an offsite location;reviewing the alarm and transmitting a response to the one or more pumps; andadjusting the first pump parameter in response to the alarm;wherein selecting the first pump parameter on the computer implemented user interface includes selecting at least one of a first lead pump and a first lag pump, wherein the first lead pump is configured to rotate during a startup cycle and rotate to the first lag pump in the pump sequence when only one pump is started during the startup cycle;wherein the first lag pump becomes a new lead pump, and the first lead pump because the first pump to be turned off and the new lead pump is the last pump on in a new start cycle, and wherein the new lead pump is the next pump in the sequence when more than one pump has been started. 11. The method of claim 10 further comprising the step of at least one of viewing and editing the first pump parameter on the computer implemented user interface while the one or more pumps are in operation. 12. The method of claim 10, wherein the pump rotation selection defined by changing a lead pump to another pump when an hours parameter times out when selecting the first pump parameter on the computer implemented user interface includes the pump rotation selection. 13. A method of operating one or more pumps in a water booster system while in operation, comprising the steps of: receiving a first pump parameter input through a computer implemented user interface, the first pump parameter defined by at least one of a pump sequence mode selection, a pump rotation selection, a lead pump selection, and a lag pump selection; andupon selection of the first pump parameter, operating the one or more pumps according to the at least one of the pump sequence mode selection, the pump rotation selection, the lead pump selection, and the lag pump selection;wherein selecting the first pump parameter on the computer implemented user interface includes selecting at least one of a first lead pump and a first lag pump, wherein the first lead pump is configured to rotate during a startup cycle and rotate to the first lag pump in the pump sequence when only one pump is started during the startup cycle;wherein the first lag pump becomes a new lead pump, and the first lead pump because the first pump to be turned off and the new lead pump is the last pump on in a new start cycle, and wherein the new lead pump is the next pump in the sequence when more than one pump has been started. 14. The method of claim 13 further comprising the step of at least one of viewing and editing the first pump parameter on the computer implemented user interface while the one or more pumps are in operation. 15. The method of claim 13, wherein the pump rotation selection defined by changing a lead pump to another pump when an hours parameter times out when selecting the first pump parameter on the computer implemented user interface includes the pump rotation selection.