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1. A porting system for a ventilator, the ventilator including a housing having an exterior surface including a recess, an inlet port, a flow generator structured to generate a flow of gas, and an outlet port structured to discharge the flow of gas from the housing, the ventilator being operable among a plurality of different operating modes, the porting system comprising: (a) a plurality of sensors structured to monitor a number of parameters with respect to the flow of gas; and(b) a number of interchangeable porting blocks structured to be selectively ...
1. A porting system for a ventilator, the ventilator including a housing having an exterior surface including a recess, an inlet port, a flow generator structured to generate a flow of gas, and an outlet port structured to discharge the flow of gas from the housing, the ventilator being operable among a plurality of different operating modes, the porting system comprising: (a) a plurality of sensors structured to monitor a number of parameters with respect to the flow of gas; and(b) a number of interchangeable porting blocks structured to be selectively coupled to the housing of the ventilator to facilitate operation of the ventilator in a desired one of the plurality of different operating modes, wherein the number of interchangeable porting blocks is a plurality of porting blocks, and wherein each porting block establishes a corresponding configuration of at least one of the plurality of sensors and passageways to facilitate the desired one of the operating modes of the ventilator. 2. A porting system for a ventilator, the ventilator including a housing having an exterior surface including a recess, an inlet port, a flow generator structured to generate a flow of gas, and an outlet port structured to discharge the flow of gas from the housing, the ventilator being operable among a plurality of different modes of operation, the porting system comprising: (a) a plurality of sensors structured to monitor a number of parameters with respect to the flow of gas; and(b) a number of porting blocks, wherein the modes of operation of the ventilator comprise a first mode, a second mode, and a third mode, wherein the predetermined configurations of the sensors comprise a first configuration corresponding to the first mode, a second configuration corresponding to the second mode, and a third configuration corresponding to the third mode, wherein the interchangeable porting blocks comprise a first porting block having a first removable routing element, a second porting block having a second removable routing element, and a third porting block having a third removable routing element, wherein, when the ventilator is operated in the first mode, the first removable routing element is structured to be coupled to the housing of the ventilator, wherein, when the ventilator is operated in the second mode, the second removable routing element is structured to be coupled to the housing of the ventilator, and wherein, when the ventilator is operated in the third mode, the third removable routing element is structured to be coupled to the housing of the ventilator. 3. The porting system of claim 2, wherein associate passageways are different for each of the first removable routing element, the second removable routing element, and the third removable routing element, wherein, when the first removable routing element is coupled to the housing of the ventilator, the passageways of the first removable routing element cooperate with a corresponding number of the probes in order to establish the first configuration of the sensors, wherein, when the second removable routing element is coupled to the housing of the ventilator, the passageways of the second removable routing element cooperate with a corresponding number of the probes in order to establish the second configuration of the sensors, and wherein, when the third removable routing element is coupled to the housing of the ventilator, the passageways of the third removable routing element cooperate with a corresponding number of the probes in order to establish the third configuration of the sensors. 4. The porting system of claim 3, wherein the sensors include a machine flow sensor, a proximal pressure sensor, and a monitor flow sensor, wherein the machine flow sensor includes a first machine flow probe and a second machine flow probe, wherein the proximal pressure sensor includes at least one proximal flow probe, wherein the monitor flow sensor includes a first monitor flow probe and a second monitor flow probe, and wherein the passageways of the first removable routing element, the passageways of the second removable routing element, and the passageways of the third removable routing element comprise a number of active passageways structured to permit the flow of gas therethrough, and a number of inactive passageways structured to resist the flow of gas therethrough. 5. The porting system of claim 4, wherein the at least one proximal pressure probe is a single proximal pressure probe, wherein the passageways of the first removable routing element include a first active passageway, a second active passageway, a third active passageway, a fourth active passageway, and a fifth active passageway, and wherein, when the ventilator is operated in accordance with the first mode and the first removable routing element is coupled to the housing of the ventilator, the first active passageway cooperates with the second active passageway in order to connect the first machine flow probe to the first monitor flow probe, the third active passageway connects the single proximal pressure probe to the atmosphere, and the fourth active passageway cooperates with the fifth active passageway in order to connect the second machine flow probe to the second monitor flow probe. 6. The porting system of claim 4, wherein the ventilator further includes a patient interface structured to deliver the flow of gas to an airway of a patient, wherein the at least one proximal pressure probe is a first proximal pressure probe connected to the proximal pressure sensor and a second proximal pressure probe connected to the patient interface, wherein the passageways of the second removable routing element include a first active passageway, a second active passageway, a third active passageway, a fourth active passageway, and a fifth active passageway, and wherein, when the ventilator is operated in accordance with the second mode and the second removable routing element is coupled to the housing of the ventilator, the first active passageway cooperates with the second active passageway in order to connect the first machine flow probe to the first monitor flow probe, the third active passageway connects the first proximal pressure probe to the second proximal pressure probe, and the fourth active passageway cooperates with the fifth active passageway in order to connect the second machine flow probe to the second monitor flow probe. 7. The porting system of claim 4, wherein the ventilator further includes a patient interface structured to deliver the flow of gas to an airway of a patient, an active exhalation valve cooperable with the patient interface, and an active exhalation controller, wherein the active exhalation controller includes at least one active exhalation controller probe, wherein the active exhalation valve includes at least one active exhalation valve probe, wherein the at least one proximal pressure probe is a first proximal pressure probe connected to the proximal pressure sensor, a second proximal pressure probe connected to the patient interface, a third proximal pressure probe connected to the patient interface, and a fourth proximal pressure probe connected to the patient interface, wherein the passageways of the third removable routing element include a first active passageway, a second active passageway, a third active passageway, a fourth active passageway, a first inactive passageway, and a second inactive passageway, and wherein, when the ventilator is operated in accordance with the third mode and the third removable routing element is coupled to the housing of the ventilator, the first active passageway connects the first monitor flow probe to the second proximal pressure probe, the second active passageway connects the first proximal pressure probe to the fourth proximal pressure probe, the third active passageway connects the second monitor flow probe to the third proximal pressure probe, the fourth active passageway connects the at least one active exhalation controller probe to the at least one active exhalation valve probe, the first machine flow probe is connected to the first inactive passageway, and the second machine flow probe is connected to the second inactive passageway. 8. A ventilator comprising: (a) a housing having an interior and an exterior with an exterior surface;(b) an inlet port extending from the exterior to the interior of the housing;(c) a flow generator disposed within the interior and being structured to generate a flow of gas;(d) an outlet port for discharging the flow of gas from the housing;(e) a plurality of sensors for monitoring a number of parameters with respect to the flow of gas; and(f) a number of interchangeable porting blocks structured to be selectively coupled to the housing of the ventilator to facilitate operation of the ventilator in a desired one of a plurality of different operating modes, wherein the number of interchangeable porting blocks is a plurality of porting blocks and wherein each porting block establishes a corresponding configuration of at least one of the plurality of sensors and passageways to facilitate the desired one of the operating modes of the ventilator. 9. A method of operating a ventilator comprising: (a) providing the ventilator with a flow generator structured to generate a flow of gas, and a plurality of sensors for monitoring a number of parameters with respect to the flow of gas, the ventilator having a housing, wherein the ventilator has a plurality of modes of operation, and wherein the sensors are configurable to a plurality of different predetermined configurations corresponding to the modes of operation of the ventilator;(b) providing a number of porting blocks each having a removable routing element;(c) selecting one of the modes of operation of the ventilator;(d) selecting the porting block among the number of porting blocks which corresponds to the selected mode of operation of the ventilator; and(e) attaching the removable routing element of the selected porting block to the housing of the ventilator in order to configure the sensors in the predetermined configuration corresponding to the selected mode of operation of the ventilator. 10. A porting block for a ventilator, the ventilator including a housing having an exterior surface including a recess, an inlet port, a flow generator structured to generate a flow of gas, an outlet port structured to discharge the flow of gas from the housing, and a plurality of sensors structured to monitor a number of parameters with respect to the flow of gas, the ventilator being operable among a plurality of modes of operation, the porting block comprising: a removable routing element structured to be selectively coupled to the housing of the ventilator at or about the recess, in order to configure the sensors in one of a plurality of different predetermined configurations corresponding to a desired one of the modes of operation of the ventilator, the removable routing element comprising a first side and a second side disposed opposite the first side, wherein, when the removable routing element is coupled to the housing, the second side of the routing element is structured to be substantially flush with respect to the exterior surface of the housing of the ventilator, adjacent the recess, and,a fastening mechanism structured to fasten the removable routing element to the housing of the ventilator. 11. The porting block of claim 10, wherein the sensors of the ventilator include a plurality of probes, wherein the removable routing element further comprises a first end, a second end disposed opposite and distal from the first end, and a plurality of passageways extending from the first side toward the second side, and wherein, when the removable routing element is coupled to the housing of the ventilator, the passageways are structured to cooperate with the probes in order to establish the one of the predetermined configurations of the sensors. 12. The porting block of claim 11, wherein the removable routing element further comprises a finger tab disposed between the first end of the removable routing element and the second end of the removable routing element, at or about the second side of the removable routing element, and wherein the finger tab is structured to facilitate the removal of the removable routing element from the recess of the housing of the ventilator. 13. The porting block of claim 11, wherein the housing of the ventilator includes an exterior surface having at least one aperture, wherein the removable routing element further comprises at least one protrusion extending outwardly from the first side of the removable routing element, and wherein, when the removable routing element is coupled to the housing of the ventilator, the at least one protrusion is structured to be disposed within a corresponding one of the at least one aperture. 14. The porting block of claim 13, wherein the at least one protrusion is a first protrusion and a second protrusion, wherein the at least one aperture of the exterior surface of the housing of the ventilator is a first aperture and a second aperture, wherein the probes includes at least a first probe structured to be accessible at or about the first aperture, and a second probe structured to be accessible at or about the second aperture, wherein the passageways of the removable routing element comprise a first passageway extending through at least a portion of the first protrusion, and a second passageway extending through at least a portion of the second protrusion, and wherein, when the removable routing element is coupled to the housing of the ventilator, the first protrusion is structured to be disposed in the first aperture in order that the first probe cooperates with the first passageway, and the second protrusion is structured to be disposed in the second aperture in order that the second probe cooperates with the second passageway. 15. The porting block of claim 11, wherein the removable routing element is replaceable with another removable routing element having a different arrangement of passageways, and wherein, responsive to replacing the removable routing element, the sensors are reconfigured to another one of the predetermined configurations corresponding to a different one of the modes of operation of the ventilator.
