A firefighting monitor includes logic circuitry for determining the reaction force caused by the flow of firefighting fluid therethrough. The reaction force may be communicated to structures remote from the monitor for taking appropriate actions in response to the reaction forces exceeding one or mo
A firefighting monitor includes logic circuitry for determining the reaction force caused by the flow of firefighting fluid therethrough. The reaction force may be communicated to structures remote from the monitor for taking appropriate actions in response to the reaction forces exceeding one or more criteria. The monitor may also use flow and nozzle data for calculating a reach of the stream of the fluid, and may transmit this reach data to a remote location. The monitor may also utilize multiple pressure sensor transducers positioned inside the monitor for determining the rate of fluid flow, rather than a paddle wheel-type sensor.
대표청구항▼
1. A firefighting monitor comprising: a body having an inlet for receiving firefighting fluid and an outlet for discharging the firefighting fluid, said body including a tubular section rotatable about an axis; a rotation sensor for measuring an amount of rotation of said tubular section about said
1. A firefighting monitor comprising: a body having an inlet for receiving firefighting fluid and an outlet for discharging the firefighting fluid, said body including a tubular section rotatable about an axis; a rotation sensor for measuring an amount of rotation of said tubular section about said axis; a flow rate detector for determining a rate of flow of the firefighting fluid through the body from the inlet to the outlet; and a controller in communication with said rotation sensor and said flow rate detector, said controller configured to determine an amount of force exerted by the firefighting fluid onto the body in at least one direction based upon a rotational orientation of the body as measured by said rotation sensor and the rate of flow of the firefighting fluid as determined by said flow rate detector, compare the amount of force to a threshold to determine if the amount of force has exceeded the threshold, and take a corrective action if the amount of force has exceeded the threshold, wherein the corrective action taken by said controller comprises at least one of: moving a mobile boom to which said monitor is coupled; adjusting an orientation of said monitor; adjusting the flow rate of fluid flowing through said monitor; and providing a warning that the amount of force has exceeded the threshold. 2. The monitor of claim 1 further including a transmitter in communication with said controller, said controller adapted to use said transmitter to transmit to a remote receiver the amount of force exerted by the firefighting fluid. 3. The monitor of claim 1 wherein: said body includes a second tubular section rotatable about a second axis;said monitor includes a second rotation sensor for measuring an amount of rotation of said second tubular section about said second axis; andsaid controller is in communication with said second rotation sensor, and said controller uses information from said second rotation sensor to determine the amount of force exerted by the firefighting fluid onto the body. 4. The monitor of claim 1 wherein said flow rate detector comprises a first pressure sensor and a second pressure sensor spaced apart from said first pressure sensor, both said first and second pressure sensors positioned inside said body and in fluid communication with the firefighting fluid flowing therein. 5. The monitor of claim 4 wherein said controller calculates flow rate based upon outputs from both said first and second pressure sensors. 6. The monitor of claim 1 wherein said controller determines the amount of said force in at least two mutually perpendicular directions. 7. The monitor of claim 1 wherein said controller is housed within an enclosure in physical contact with said body. 8. The monitor of claim 1 wherein said controller is housed within an enclosure positioned remotely from said body. 9. The monitor of claim 1 further including a memory accessible by said controller, said memory containing data relating to one or more dimensions of said monitor, wherein said controller is adapted to use said data in determining said amount of force. 10. The monitor of claim 1 wherein said controller is adapted to determine said amount of force multiple times per second. 11. The monitor of claim 1 wherein said controller is further adapted to receive information pertaining to a nozzle orifice size and a nozzle position and to use said information to determine a reach of the firefighting fluid when exiting from a nozzle of the monitor. 12. The monitor of claim 11 wherein said controller is further adapted to receive information pertaining to wind speed and wind direction and to use said information to determine the reach of the firefighting fluid from the monitor nozzle. 13. The monitor of claim 1, wherein the information from said rotation sensor comprises a signal indicative of a multiplicity of rotational orientations of said tubular section. 14. The monitor of claim 1, wherein the information from said rotation sensor comprises a signal indicative of a plurality of rotational orientations of said tubular section, each rotational orientation being between respective limits of rotational travel of said tubular section. 15. The monitor of claim 1, wherein: the controller is programmed to allow a discharge of the firefighting liquid from the outlet at a first discharge rate when the rotation sensor is in a first rotational range; andthe controller is programmed to automatically reduce the discharge of the firefighting liquid from the outlet to a second discharge rate less than the first discharge rate when the rotation sensor is in a second rotational range outside the first rotational range. 16. The monitor of claim 15, wherein the controller is programmed to automatically prevent discharge of the firefighting fluid from the outlet when the rotation sensor is in a third rotational range outside the first and second rotational ranges. 17. The monitor of claim 1, wherein: the body is mounted to a structure defining a structural force threshold; andthe threshold of the controller corresponds to the structural force threshold. 18. The monitor of claim 17, wherein: the controller is programmed with a blackout condition corresponding to a rotational orientation of the body at which the structural force threshold is zero; andthe controller sets the rate of flow of the firefighting fluid to zero in the blackout condition, such that the controller prevents force from being exerted by the monitor on the structure in the blackout condition. 19. The monitor of claim 1, wherein the corrective action comprises a real-time adjustment that occurs concurrently with the determination of the amount of force on the body. 20. The monitor of claim 1, wherein the flow rate detector comprises: a first pressure sensor which detects an inlet pressure at the inlet of the base; anda second pressure sensor which detects an outlet pressure at the outlet from which the firefighting fluid may be discharged. 21. The monitor of claim 3, wherein the first rotation sensor is coupled to a first motor and the second rotation sensor is coupled to a second motor. 22. A firefighting monitor comprising: a body having an inlet for receiving firefighting fluid and an outlet for discharging the firefighting fluid, said body including a tubular section rotatable about an axis;a rotation sensor for measuring an amount of rotation of said tubular section about said axis;a flow rate detector for determining a rate of flow of the firefighting fluid through the body from the inlet to the outlet; anda controller in communication with said rotation sensor and said flow rate detector, said controller configured to determine an amount of force exerted by the firefighting fluid onto the body in at least one direction based upon information from said rotation sensor and said flow rate detector, compare the amount of force to a threshold to determine if the amount of force has exceeded the threshold, and take a corrective action if the amount of force has exceeded the threshold;the controller is programmed to allow a discharge of the firefighting liquid from the outlet at a first discharge rate when the rotation sensor is in a first rotational range; andthe controller is programmed to automatically reduce the discharge of the firefighting liquid from the outlet to a second discharge rate less than the first discharge rate when the rotation sensor is in a second rotational range outside the first rotational range. 23. The monitor of claim 22 further including a transmitter in communication with said controller, said controller adapted to use said transmitter to transmit to a remote receiver the amount of force exerted by the firefighting fluid. 24. The monitor of claim 22 wherein: said body includes a second tubular section rotatable about a second axis;said monitor includes a second rotation sensor for measuring an amount of rotation of said second tubular section about said second axis; andsaid controller is in communication with said second rotation sensor, and said controller uses information from said second rotation sensor to determine the amount of force exerted by the firefighting fluid onto the body. 25. The monitor of claim 24, wherein the first rotation sensor is coupled to a first motor and the second rotation sensor is coupled to a second motor. 26. The monitor of claim 22 wherein said flow rate detector comprises a first pressure sensor and a second pressure sensor spaced apart from said first pressure sensor, both said first and second pressure sensors positioned inside said body and in fluid communication with the firefighting fluid flowing therein. 27. The monitor of claim 26, wherein said controller calculates flow rate based upon outputs from both said first and second pressure sensors. 28. The monitor of claim 22 wherein said controller determines the amount of said force in at least two mutually perpendicular directions. 29. The monitor of claim 22 wherein said controller is housed within an enclosure in physical contact with said body. 30. The monitor of claim 22 wherein said controller is housed within an enclosure positioned remotely from said body. 31. The monitor of claim 22 wherein the corrective action taken by said controller is to move a mobile boom to which said monitor is coupled. 32. The monitor of claim 22 wherein the corrective action taken by said controller is to adjust at least one of an orientation of said monitor and the flow rate of fluid flowing through said monitor. 33. The monitor of claim 22 further including a memory accessible by said controller, said memory containing data relating to one or more dimensions of said monitor, wherein said controller is adapted to use said data in determining said amount of force. 34. The monitor of claim 22 wherein said controller is adapted to determine said amount of force multiple times per second. 35. The monitor of claim 22 wherein said controller is further adapted to receive information pertaining to a nozzle orifice size and a nozzle position and to use said information to determine a reach of the firefighting fluid when exiting from a nozzle of the monitor. 36. The monitor of claim 35 wherein said controller is further adapted to receive information pertaining to wind speed and wind direction and to use said information to determine the reach of the firefighting fluid from the monitor nozzle. 37. The monitor of claim 22 wherein the corrective action taken by said controller is to provide a warning that the amount of force has exceeded the threshold. 38. The monitor of claim 22, wherein the information from said rotation sensor comprises a signal indicative of a multiplicity of rotational orientations of said tubular section. 39. The monitor of claim 22, wherein the information from said rotation sensor comprises a signal indicative of a plurality of rotational orientations of said tubular section, each rotational orientation being between respective limits of rotational travel of said tubular section. 40. The monitor of claim 22, wherein the controller is programmed to calculate the amount of force exerted by the firefighting fluid onto the body in at least one direction based upon a rotational orientation of the body as measured by the rotation sensor and the rate of flow of the firefighting fluid as determined by the flow rate detector. 41. The monitor of claim 22, wherein the controller is programmed to automatically prevent discharge of the firefighting fluid from the outlet when the rotation sensor is in a third rotational range outside the first and second rotational ranges. 42. The monitor of claim 22, wherein: the body is mounted to a structure defining a structural force threshold; andthe threshold of the controller corresponds to the structural force threshold. 43. The monitor of claim 42, wherein: the controller is programmed with a blackout condition corresponding to a rotational orientation of the body at which the structural force threshold is zero; andthe controller sets the rate of flow of the firefighting fluid to zero in the blackout condition, such that the controller prevents force from being exerted by the monitor on the structure in the blackout condition. 44. The monitor of claim 22, wherein the corrective action comprises a real-time adjustment that occurs concurrently with the determination of the amount of force on the body. 45. The monitor of claim 22, wherein the flow rate detector comprises: a first pressure sensor which detects an inlet pressure at the inlet of the base; and a second pressure sensor which detects an outlet pressure at the outlet from which the firefighting fluid may be discharged.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (84)
Yakes, Christopher K.; Morrow, Jon J., A/C bus assembly for electronic traction vehicle.
Rowe, Ryan F.; Pillar, Duane R.; Bjornstad, Neil; Woolman, William M.; Squires, Bradley C., Control system and method for an equipment service vehicle.
Doyle, Kevin; Schulte, Keith; Johnson, Bruce, Electronically controlled valve actuator in a plumbed water line within a water conditioning management system.
Klein, Andrew P.; High, Thomas A.; Bolen, Jr., Kenneth A.; Piller, Brian D.; Grady, Clarence A., Foam additive supply system for rescue and fire fighting vehicles.
Nelson ; Jr. George R. (New York NY) Kaplan Herman (Great Neck NY), Method and apparatus for delivering constant water flow rates to a fire hose at each of a plurality of selectable flow r.
Gary M. Kempen ; Bradley C. Squires ; Michael E. Lorrig ; Duane R. Pillar ; David L. M. Gauerke, Military vehicle having cooperative control network with distributed I/O interfacing.
Petit Kevin J. (Wooster OH) Dettra Eugene E. (Wooster OH) Beery Richard L. (Shreve OH) Orin Jeffrey T. (Canton OH), Remotely controlled firefighting apparatus and control means.
Pillar,Duane R.; Bjornstad,Neil; Woolman,William M.; Linsmeier,Catherine R.; Magners,Kevin W., Turret control system based on stored position for a fire fighting vehicle.
Rowe,Ryan F.; Pillar,Duane R.; Bjornstad,Neil; Woolman,William M.; Squires,Bradley C., Turret positioning system and method for a fire fighting vehicle.
Stommes Wallace F. (Fergus Falls MN) Nelson Gerald J. (Fergus Falls MN) Cuhel Gerald A. (Richville MN) Kunz Ross S. (Callaway MN), Valve position indicator.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.