A venturi connector includes a housing having a mixing chamber defined therein and at least one window that is in fluid communication with the mixing chamber and is open to atmosphere to allow air to be entrained into the mixing chamber. The connector includes a nozzle actuator member includes a bod
A venturi connector includes a housing having a mixing chamber defined therein and at least one window that is in fluid communication with the mixing chamber and is open to atmosphere to allow air to be entrained into the mixing chamber. The connector includes a nozzle actuator member includes a body having a plurality of discrete nozzles formed therein. The nozzles are defined by different sized venturi orifices through which gas flows, thereby allowing the concentration of the gas delivered to the patient to be varied. The nozzle actuator member is disposed within one window formed in the housing between the gas port and the mixing chamber such that the position of the nozzle actuator member within the housing can be adjusted so as to position one of the discrete nozzles into the gas flow path, thereby controlling the flow rate of the gas into the mixing chamber and ultimately the concentration of gas delivered to the patient.
대표청구항▼
1. A venturi connector comprising: a housing having a mixing chamber defined therein and at least one window that is in fluid communication with the mixing chamber and is open to atmosphere to allow air to be entrained into the mixing chamber to form a venturi effect;a gas port extending outwardly f
1. A venturi connector comprising: a housing having a mixing chamber defined therein and at least one window that is in fluid communication with the mixing chamber and is open to atmosphere to allow air to be entrained into the mixing chamber to form a venturi effect;a gas port extending outwardly from the housing for connecting to a supplemental gas source, the gas port defining a gas flow path for delivering the supplemental gas to the mixing chamber; anda nozzle actuator member comprising a body having a plurality of discrete nozzles formed therein, the nozzles being defined by different sized venturi orifices through which gas flows; the nozzle actuator member being disposed within one window formed in the housing between the gas port and the mixing chamber such that the position of the nozzle actuator member within the housing can be adjusted so as to position one of the discrete nozzles into the gas flow path, thereby controlling the flow rate of the supplemental gas into the mixing chamber and a concentration of the supplemental gas delivered to a patient;wherein the housing including a lower hub having a lower sealing surface and an upper hub having an upper sealing surface, the lower hub being defined at one end of the gas port, the lower and upper hubs defining the gas flow path with the upper hub forming a gas exit into the mixing chamber, the nozzle actuator member being rotatable within the housing to permit one select nozzle to be positioned between the lower and upper hubs and placed within the gas flow path;wherein the housing includes a first retention member that is connected to the lower hub and a second retention member that is connected to the upper hub, the nozzle actuator member having a first shaft section extending outwardly from a top face of the body of the nozzle actuator member and a second shaft section extending outwardly from a bottom face of the nozzle actuator member, the first shaft section being rotatably coupled to the second retention member and the second shaft section being rotatably coupled to the first retention member to permit rotation of the nozzle actuator member within the housing to allow one select nozzle to be positioned between the lower and upper hubs and placed within the gas flow path. 2. The connector of claim 1, wherein the first shaft section and the second retention member have complementary detents that engage one another and provide tactile feedback to a user as the nozzle actuator member is rotated within the housing. 3. The connector of claim 1, wherein the nozzle actuator member is snap-fittingly coupled to the housing. 4. The connector of claim 1, wherein the lower hub, upper hub and one select nozzle are centrally located within the housing. 5. The connector of claim 1, wherein the at least one window comprises two windows formed in the housing with the nozzle actuator member being at least partially disposed within one window of the two windows. 6. The connector of claim 1, wherein the nozzle actuator member is eccentrically coupled to the housing. 7. The connector of claim 1, wherein the nozzle actuator member includes six discrete nozzles that are spaced apart and formed circumferentially about a center axis about which the nozzle actuator member rotates within the housing. 8. The connector of claim 7, wherein the orifices of the six nozzles are configured to produce gas concentrations of 24%, 28%, 31%, 35%, 40% and 50%, respectively. 9. A venturi connector comprising: a housing having a mixing chamber defined therein and at least one window that is in fluid communication with the mixing chamber and is open to atmosphere to allow air to be entrained into the mixing chamber to form a venturi effect;a gas port extending outwardly from the housing for connecting to a supplemental gas source, the gas port defining a gas flow path for delivering the supplemental gas to the mixing chamber; anda nozzle actuator member comprising a body having a plurality of discrete nozzles formed therein, the nozzles being defined by different sized venturi orifices through which gas flows; the nozzle actuator member being disposed within one window formed in the housing between the gas port and the mixing chamber such that the position of the nozzle actuator member within the housing can be adjusted so as to position one of the discrete nozzles into the gas flow path, thereby controlling the flow rate of the supplemental gas into the mixing chamber and a concentration of the supplemental gas delivered to a patient;wherein the at least one window comprises two windows formed in the housing with the nozzle actuator member being at least partially disposed within one window of the two windows; wherein the body of the nozzle actuator member extends radially beyond an outer periphery of the housing. 10. A venturi connector comprising: a housing having a mixing chamber defined therein and at least one window that is in fluid communication with the mixing chamber and is open to atmosphere to allow air to be entrained into the mixing chamber to form a venturi effect;a gas port extending outwardly from the housing for connecting to a supplemental gas source, the gas port defining a gas flow path for delivering the supplemental gas to the mixing chamber; anda nozzle actuator member comprising a body having a plurality of discrete nozzles formed therein, the nozzles being defined by different sized venturi orifices through which gas flows; the nozzle actuator member being disposed within one window formed in the housing between the gas port and the mixing chamber such that the position of the nozzle actuator member within the housing can be adjusted so as to position one of the discrete nozzles into the gas flow path, thereby controlling the flow rate of the supplemental gas into the mixing chamber and a concentration of the supplemental gas delivered to a patient; wherein the nozzle actuator member includes a peripheral wall on which discrete nozzle indicia are formed to indicate a gas concentration that is produced by a respective nozzle, each nozzle having associated nozzle indicia. 11. The connector of claim 10, wherein the nozzle indicia are circumferentially offset from the respective nozzle to which they relates. 12. The connector of claim 11, wherein the nozzle indicia are located about 180 degrees from the respective nozzle to which they relate. 13. A venturi nozzle member for use in a venturi connector housing comprising: a body having a plurality of discrete venturi nozzles formed therein, the nozzles being defined by different sized venturi orifices through which supplemental gas flows, the body having means for rotatably coupling the body to the venturi connector housing;wherein the means comprises a first shaft section extending upwardly from a top surface of the body and a second shaft section extending downwardly from a bottom surface of the body, the first and second shaft sections being axially aligned, the body rotating about the first and second shaft sections;wherein the first shaft section includes detents for restricting free rotation of the body within the venturi connector housing. 14. The venturi nozzle member of claim 13, wherein there are six discrete nozzles that are spaced apart and formed circumferentially about a center axis about which the nozzle actuator member rotates within the housing. 15. The venturi nozzle member of claim 14, wherein the orifices of the six nozzles are configured to produce gas concentrations of 24%, 28%, 31%, 35%, 40% and 50%, respectively. 16. The venturi nozzle member of claim 13, wherein the body includes a peripheral wall on which discrete nozzle indicia are formed to indicate a gas concentration that is produced by a respective nozzle, each nozzle having associated nozzle indicia. 17. The venturi nozzle member of claim 16, wherein the nozzle indicia are circumferentially offset from the respective nozzle to which it relates they relate. 18. The venturi nozzle member of claim 17, wherein the nozzle indicia are located about 180 degrees from the respective nozzle to which they relate.
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