A heater unit for a respiratory system is designed for natural convection cooling air to pass first through a transformer in the heater unit and then through a heat sink in the heater unit to which is mounted a power switch to conduct heat from the power switch to the cooling air passing through the
A heater unit for a respiratory system is designed for natural convection cooling air to pass first through a transformer in the heater unit and then through a heat sink in the heater unit to which is mounted a power switch to conduct heat from the power switch to the cooling air passing through the heat sink. A thermal break may be provided between the heat sink and the transformer. The transformer may be a toroidal transformer with the air passing through an aperture thereof such as from a hollow projection of the heater unit extending into the aperture. One side of the transformer may be situated along a surface of the heater unit and the heat sink secured to the heater unit against the opposite side of the transformer to hold the transformer in place. A venting chamber may be associated with an air exhaust of the heater unit to provide a circuitous exit path for air exiting the heater unit. The venting chamber may extend in generally surrounding relationship with the heater of the heater unit.
대표청구항▼
1. A heater unit adapted to be used with a water container in a respiratory system and configured to be cooled by natural convection, the heater unit comprising: a housing having an air inlet adjacent a bottom thereof and an air exhaust adjacent a top thereof and defining an interior chamber therebe
1. A heater unit adapted to be used with a water container in a respiratory system and configured to be cooled by natural convection, the heater unit comprising: a housing having an air inlet adjacent a bottom thereof and an air exhaust adjacent a top thereof and defining an interior chamber therebetween;a heated hot plate supported adjacent the top of the housing;locking structure on the housing adapted to selectively secure a water container to the housing in thermal communication with the hot plate;an electrical transformer and a power switch within the interior chamber of the housing;a heat sink within the interior chamber of the housing and in thermal communication with the power switch;the transformer and the heat sink being positioned such that a natural convection air path carries air from the air inlet, upwardly through the transformer, upwardly through the heat sink, and out the air exhaust. 2. The heater unit of claim 1, the transformer being a toroidal transformer and being positioned such that said natural convection air path extends through an aperture of the toroidal transformer. 3. The heater unit of claim 2 further comprising a hollow projection extending from the air inlet into the aperture of the toroidal transformer. 4. The heater unit of claim 3, the heat sink being secured to the heater unit above the toroidal transformer. 5. The heater unit of claim 1, one side of the transformer being situated against a surface of the housing and the heat sink being secured to the housing against an opposite side of the transformer. 6. The heater unit of claim 1, the heat sink including a plurality of fins defining air flow channels through the heat sink. 7. The heater unit of claim 1 further comprising a venting chamber associated with the air exhaust. 8. The heater unit of claim 7, the venting chamber and air exhaust cooperating to define a circuitous exit path for air exiting the air exhaust. 9. The heater unit of claim 8, the venting chamber extending in generally surrounding relationship with the hot plate. 10. The heater unit of claim 8, the air exhaust extending into the venting chamber. 11. The heater unit of claim 8 wherein the venting chamber and the air exhaust are configured such that the circuitous exit path carries air upwardly, then radially outwardly, then downwardly, then radially outwardly, then upwardly. 12. The heater unit of claim 7, the venting chamber extending in generally surrounding relationship with the hot plate. 13. A heater unit adapted to be used with a water container in a respiratory system and configured to be cooled by natural convection, the heater unit comprising: a housing defining an interior chamber;a heated hot plate supported by the housing;locking structure on the housing adapted to selectively secure a water container to the housing in thermal communication with the hot plate;an electrical transformer and a power switch within the interior chamber of the housing;a heat sink within the interior chamber of the housing and in thermal communication with the power switch;a first side of the transformer being situated against a surface of the housing and the heat sink being secured to the housing against a second, opposite side of the transformer. 14. The heater unit of claim 13 further comprising an elastomeric member sandwiched between the second, opposite side of the transformer and the heat sink. 15. The heater unit of claim 13 further comprising a cushion sandwiched between the first side of the transformer and the surface of the housing. 16. The heater unit of claim 13 the transformer being a toroidal transformer, the heater unit further comprising a hollow projection over which the toroidal transformer is situated with the hollow projection extending an aperture of the toroidal transformer. 17. A heater unit adapted to be used with a water container in a respiratory system and configured to be cooled by natural convection, the heater unit comprising: a housing having an air inlet and an air exhaust and defining an interior chamber therebetween;a heated hot plate supported adjacent the air exhaust;locking structure on the housing adapted to selectively secure a water container to the housing in thermal communication with the hot plate;heat generating electrical components within the interior chamber of the housing adapted to be cooled by air passing into the air inlet, upwardly through the interior chamber, and out the air exhaust; anda venting chamber associated with the air exhaust. 18. The heater unit of claim 17, the venting chamber and the air exhaust cooperating to define a circuitous exit path for air passing out the air exhaust. 19. The heater unit of claim 18, the venting chamber extending in generally surrounding relationship with the hot plate. 20. The heater unit of claim 18 the air exhaust extending into the venting chamber. 21. The heater unit of claim 18 wherein the venting chamber and the air exhaust are configured such that the circuitous exit path passes air upwardly, then radially outwardly, then downwardly, then radially outwardly, then upwardly. 22. The heater unit of claim 17, the venting chamber extending in generally surrounding relationship with the hot plate. 23. A method for cooling a heater unit by natural convection, the heater unit adapted to be used with a water container in a respiratory system and having an electrical transformer and a power switch within a housing defining an interior chamber of the heater unit and a heat sink within the interior chamber and in thermal communication with the power switch, the heater unit further including a heater supported by the housing and locking structure on the housing adapted to selectively secure a water container to the housing in thermal communication with the heater, the method comprising passing air upwardly through the transformer and then upwardly through the heat sink. 24. The method of claim 23 wherein the transformer is a toroidal transformer, passing air through the transformer including passing air through an aperture of the toroidal transformer. 25. The method of claim 23 wherein the heat sink includes a plurality of fins defining air flow channels through the heat sink, passing air through the heat sink including passing air through the air flow channels. 26. The method of claim 23 further comprising passing air out of the interior chamber through an air exhaust and then along a circuitous exit path. 27. The method of claim 26 wherein the step of passing air out of the interior chamber through the air exhaust and then along the circuitous exit path comprises passing air upwardly, then radially outwardly, then downwardly, then radially outwardly, then upwardly. 28. The method of claim 26 wherein the circuitous exit path extends in generally surrounding relationship with the heater of the heater unit. 29. A method of mounting an electrical transformer within a heater unit, the heater unit adapted to be used with a water container in a respiratory system, the heater unit including a housing, a heater supported by the housing, and locking structure on the housing adapted to selectively secure a water container to the housing in thermal communication with the heater, the heater unit configured to be cooled by natural convection, the method comprising positioning a first side of the transformer adjacent an interior surface of the heater unit and securing a heat sink to the heater unit against a second, opposite side of the transformer. 30. The method of claim 29 further comprising sandwiching an elastomeric member between the second side of the transformer and the heat sink. 31. The method of claim 29 further comprising sandwiching a cushion between the first side of the transformer and the interior surface of the heater unit. 32. A method of venting a heater unit by natural convection, the heater unit adapted to be used with a water container in a respiratory system, the heater unit having a housing defining an interior chamber, a heater supported by the housing, locking structure on the housing adapted to selectively secure a water container to the housing in thermal communication with the heater, and an air exhaust, the method comprising passing air upwardly and out of the interior chamber through the air exhaust and then along a circuitous exit path. 33. The method of claim 32 wherein the circuitous exit path extends in generally surrounding relationship with the heater of the heater unit. 34. The method of claim 32 wherein the step of passing air through the air exhaust and then along the circuitous exit path comprises passing air upwardly, then radially outwardly, then downwardly, then radially outwardly, then upwardly.
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