A control system for a fire fighting device is provided. The control system may include a controller configured to operably connect over a network to a first valve controller controlling a status of a first valve in response to an input from the controller, a second valve controlling a status of a s
A control system for a fire fighting device is provided. The control system may include a controller configured to operably connect over a network to a first valve controller controlling a status of a first valve in response to an input from the controller, a second valve controlling a status of a second valve in response to an input from the controller, and a governor operably controlling a power source in response to an input from the controller. The control system may further comprise a touchscreen display operably connected to the controller, the display configured to display the status of the first and second valves and configured to receive an input from a user, wherein controller generates a manipulatable icon displayed on the touchscreen display, a manipulation of the icon generating the input from the controller to the first valve controller.
대표청구항▼
1. A method of determining whether to execute a command in a control system for a pump module for a fluid delivery system operating a plurality of modules, the fluid delivery system including a frame; a plurality of ground engaging members supporting the frame; a pump supported by the ground engagin
1. A method of determining whether to execute a command in a control system for a pump module for a fluid delivery system operating a plurality of modules, the fluid delivery system including a frame; a plurality of ground engaging members supporting the frame; a pump supported by the ground engaging members; a plurality of fluid valves supported by the ground engaging members and in fluid communication with the pump, the method comprising: providing a boundary condition;providing a priority ranking for each module of the plurality of modules, wherein modules associated with manned systems are given higher priority than modules associated with unmanned systems;receiving a command to execute;determining if executing the command will violate the boundary condition;executing the command if determined that executing the command will not violate the boundary condition; andif determined that executing the command will violate the boundary condition, determining if the command is directed to a higher priority module than a priority of an operating module;determining not to execute the command when the command is directed to a lower priority module than the operating module; andreducing an output of the operating module prior to executing the command when the command is directed to the higher priority module than the operating module. 2. The method of claim 1, wherein the boundary condition is selected from one of a discharge pressure, an intake pressure, a flow rate, an engine RPM, an engine oil pressure, and a fluid tank level. 3. The method of claim 1, further comprising the steps of: controlling a pressure generated by the pump and a position of the plurality of valves; andmaintaining a first flow rate through a first valve of the fluid delivery system. 4. The method of claim 1, wherein the fluid delivery device is a fire truck. 5. A method of determining whether to execute a command in a control system for a pump module for a fluid delivery system operating a plurality of modules, the fluid delivery system including a frame; a plurality of ground engaging members supporting the frame; a pump supported by the ground engaging members; a plurality of fluid valves supported by the ground engaging members and in fluid communication with the pump, the method comprising: providing a boundary condition;providing a priority ranking for each module;receiving a command to execute;determining if executing the command will violate the boundary condition;executing the command if determined that executing the command will not violate the boundary condition; andif determined that executing the command will violate the boundary condition, determining if the command is directed to a higher priority module than a priority of a first operating module;determining not to execute the command when the command is directed to a lower priority module than the first operating module;reducing an output of the first operating module prior to executing the command when the command is directed to the higher priority module than the first operating module:determining if executing the command is directed to a higher priority module than a priority of a second operating module; andreducing an output of the second operating module prior to executing the command when the command is directed to the higher priority module than the second operating module. 6. The method of claim 5, wherein modules associated with manned systems are given higher priority than modules associated with unmanned systems. 7. The method of claim 5, wherein already operating modules are given higher priority than newly started modules. 8. A method of determining whether to execute a command in a control system for a pump module for a fluid delivery system operating a plurality of modules, the fluid delivery system including a frame; a plurality of ground engaging members supporting the frame; a pump supported by the ground engaging members; a plurality of fluid valves supported by the ground engaging members and in fluid communication with the pump, the method comprising: providing a boundary condition;providing a priority ranking for each module;receiving a command to execute;determining if executing the command will violate the boundary condition;executing the command if determined that executing the command will not violate the boundary condition; andif determined that executing the command will violate the boundary condition, determining if the command is directed to a higher priority module than a priority of a first operating module;determining not to execute the command when the command is directed to a lower priority module than the first operating module;reducing an output of the first operating module prior to executing the command when the command is directed to the higher priority module than the first operating module;determining if executing the command is directed to a higher priority module thana priority of a second operating module; andreducing an output of the second operating module prior to executing the command when the command is directed to the higher priority module than the second operating module wherein the output of the first operating module and second operating module are equally reduced when the command is directed to the higher priority module than the first and second operating modules. 9. The method of claim 8, wherein already operating modules are given higher priority than newly started modules. 10. The method of claim 8, wherein the priority ranking is provided by an operator. 11. A method of determining whether to execute a command in a control system for a pump module for a fluid delivery system operating a plurality of modules, the fluid delivery system including a frame; a plurality of ground engaging members supporting the frame; a pump supported by the ground engaging members; a plurality of fluid valves supported by the ground engaging members and in fluid communication with the pump, the method comprising: providing a boundary condition;providing a priority ranking for each module;receiving a command to execute;determining if executing the command will violate the boundary condition;executing the command if determined that executing the command will not violate the boundary condition;if determined that executing the command will violate the boundary condition, determining if the command is directed to a higher priority module than a priority of an operating module;determining not to execute the command when the command is directed to a lower priority module than the operating module; andreducing an output of the operating module prior to executing the command when the command is directed to the higher priority module than the operating module;controlling a pressure generated by the pump and a position of the plurality of valves; andmaintaining a first flow rate through a first valve of the fluid delivery system wherein maintaining the first flow rate through the first valve of the fluid delivery system includes the steps of: providing a first flow rate of a fluid pressurized by the pump through the first valve;receiving at a controller a request for a second flow rate of the fluid through a second valve;determining with the controller a predicted effect on the first flow rate based on request;adjusting at least one of the position of the first valve and the pressure generated by the pump to maintain the first flow rate based on the predicted effect; andadjusting the position of the second valve to provide the second flow rate of the fluid through the second valve. 12. The method of claim 11, further comprising the steps of: displaying on a touchscreen display a status of the first valve;displaying on the touchscreen display a manipulatable icon;receiving a manipulation of the icon; andcontrolling the status of the first valve based on the manipulation. 13. The method of claim 12, further comprising the steps of: displaying on the touchscreen display a second manipulatable icon;receiving a second manipulation of the second icon; andcontrolling a status of the second valve based on the second manipulation. 14. The method of claim 13, further comprising the steps of: controlling a power source of the fluid delivery system; andadjusting at least one of the group consisting of the first valve and the power source to maintain one of a pressure and a flow rate through the first valve in response to the second manipulation of the second icon. 15. The method of claim 12, further comprising the steps of: displaying a list of outputs on a single display screen of the touchscreen display from a plurality of systems including a first valve controller, a second valve controller, a monitor, a water cannon, an engine, a governor, a water tank, a foam tank, a generator, a ladder, an aerial, and a scene lighting system;selecting a portion of outputs from the list of outputs displayed on the touchscreen display; andautomatically configuring a size of the portion of outputs to fit on the single display screen. 16. The method of claim 12, further comprising the steps of: detecting a current status of the first valve; anddisplaying a second icon indicating the current status of the first valve. 17. The method of claim 12, wherein the manipulatable icon is graphical representation of the first valve. 18. The method of claim 12, further comprising the steps of: displaying a power source manipulatable icon on the touchscreen display; andcontrolling a governor associated with a power source based on a manipulation of the power source manipulatable icon. 19. The method of claim 12, further comprising the steps of: determining a fluid volume in a fluid tank; anddisplaying a fluid tank icon on the touchscreen display which indicates the fluid volume in the fluid tank. 20. The method of claim 19, wherein the fluid tank icon is a manipulatable fluid tank icon, the method further comprising the steps of: receiving a manipulation of the fluid tank icon; andcontrolling a valve in fluid communication with a fluid source and with the fluid tank to fill the fluid tank with fluid based on the manipulation of the fluid tank icon. 21. The method of claim 12, further comprising the steps of: displaying a current value of a parameter of the fluid delivery system;displaying a manipulatable first threshold icon corresponding to a first threshold value associated with the parameter; andreceiving a manipulation of the first threshold icon to adjust the first threshold value. 22. The method of claim 21, further comprising the steps of: displaying an alert when the current value of the parameter crosses the first threshold value.
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