A breathing assistance apparatus capable of operating in alternating inhalation and expiratory phases includes a pressurized respiratory gas source, an inhalation duct to supply gas from the pressurized respiratory gas source to a patient, and an expiratory duct for expiratory gas of the patient. Th
A breathing assistance apparatus capable of operating in alternating inhalation and expiratory phases includes a pressurized respiratory gas source, an inhalation duct to supply gas from the pressurized respiratory gas source to a patient, and an expiratory duct for expiratory gas of the patient. The apparatus further includes a set of flow rate sensors positioned to sense a first flow rate of the expiratory duct and a second flow rate of the inhalation duct, and a controller, including a processor, configured to control the gas source. The inhalation duct includes an inhalation valve, the inhalation valve configured to provide proportional operation and the inhalation valve is selectively controlled by the controller to move to a specific position to allow a desired level of flow through the inhalation valve to the patient.
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1. A breathing assistance apparatus capable of operating in alternating inhalation and expiratory phases, the apparatus comprising: a pressurized respiratory gas source,an inhalation duct to supply gas from the pressurized respiratory gas source to a patient,an expiratory duct for expiratory gas of
1. A breathing assistance apparatus capable of operating in alternating inhalation and expiratory phases, the apparatus comprising: a pressurized respiratory gas source,an inhalation duct to supply gas from the pressurized respiratory gas source to a patient,an expiratory duct for expiratory gas of the patient,a set of flow rate sensors positioned to sense a first flow rate of the expiratory duct and a second flow rate of the inhalation duct, anda controller, including a processor, configured to control the gas source, the controller further configured to compare the first flow rate and the second flow rate in a volumetric mode, and to trigger a new inhalation phase based on a difference between the first flow rate and the second flow rate,wherein the inhalation duct includes an inhalation valve comprising a valve body having an orifice configured to connect to the inhalation duct, and a moving element defining a recess for allowing passage of a gas therethrough, the moving element being translatable relative to the valve body in a first direction such that the orifice and recess are capable of alignment to allow the gas from the gas source to pass through to the inhalation duct in use, wherein a translation of the moving element is proportional to passage of the gas from the gas source through the inhalation duct via the orifice during use. 2. The breathing assistance apparatus of claim 1 wherein the processor is configured to trigger the new inhalation phase based on a determined difference between the first flow rate and the second flow rate. 3. The breathing assistance apparatus of claim 2 wherein the processor is configured to trigger the new inhalation phase based on a comparison of the determined difference and a memorized threshold. 4. The breathing assistance apparatus of claim 3 wherein the processor is configured to trigger the new inhalation phase when the determined difference exceeds the memorized threshold. 5. The breathing assistance apparatus of claim 3 wherein the expiratory duct includes an exhalation valve. 6. The breathing assistance apparatus of claim 5 wherein the exhalation valve is selectively controlled by the controller to move between an open position and a closed position. 7. The breathing assistance apparatus of claim 5 wherein the controller is configured to set the exhalation valve to a closed position in response to the trigger of the new inhalation phase. 8. The breathing assistance apparatus of claim 1 wherein the inhalation valve is selectively controlled by the controller to move between an open position and a proportional position. 9. The breathing assistance apparatus of claim 1 wherein the controller is configured to set the inhalation valve to an open position from a closed position in response to the trigger of the new inhalation phase. 10. The breathing assistance apparatus of claim 1 wherein the expiratory duct includes an exhalation valve, and wherein the controller is configured, in response to the trigger of the new inhalation phase, to set the inhalation valve to an open position from a closed position and to set the exhalation valve to a closed position. 11. The breathing assistance apparatus according to claim 1 wherein the moving element is operable to block the orifice in a closed position, and to at least partially free the orifice in an open position, the recess comprising at least a first part having a geometry corresponding to a proportional operation of the inhalation valve when the first part is aligned with the orifice. 12. The breathing assistance apparatus according to claim 11, wherein the recess is shaped so that when the moving element moves the inhalation valve from the closed position to the open position, the first part is aligned with the recess which causes a progressive opening of the inhalation valve. 13. The breathing assistance apparatus according to claim 12, wherein the first part of the recess is generally triangular. 14. The breathing assistance apparatus according to claim 13, wherein the moving element is designed so that the first part corresponds to angular positions used for volumetric modes. 15. The breathing assistance apparatus according to claim 11, wherein the recess further comprises a second part having a geometry corresponding to all or nothing operation of the inhalation valve when the second part is aligned with the orifice and the second part is aligned with the recess after the first part has aligned with the orifice. 16. The breathing assistance apparatus according to claim 15, wherein the second part of the recess is generally rectangular and the second part corresponds to angular positions used for barometric modes. 17. The breathing assistance apparatus according to claim 1, wherein the moving element includes a variable width, the passage of gas being greatest at a largest width of the moving element. 18. A control method of a controller of a breathing assistance apparatus capable of operating in alternating inhalation and expiratory phases, the method comprising: controlling with a controller, including a processor, a pressurized respiratory gas source, the gas source being coupled with an inhalation duct to supply gas from the pressurized respiratory gas source to a patient and an expiratory duct for expiratory gas of the patient,with the controller, comparing a first flow rate and a second flow rate, andin a volumetric mode, controlling a trigger of a new inhalation phase based on a difference between the first flow rate and the second flow rate,wherein the inhalation duct includes a proportional inhalation valve comprising a valve body having an orifice configured to connect to the inhalation duct, and a moving element defining a recess therethrough, and being configured to move laterally with respect to the valve body, a displacement of the moving element being proportional to passage of gas from the gas source through the inhalation duct via the orifice during use, and in response to the trigger of the new inhalation phase, setting the inhalation valve to move to a specific position to allow a desired level of flow through the inhalation valve for delivery to the patient. 19. The control method of claim 18 wherein the trigger of the new inhalation phase is based on determining a difference between the first flow rate and the second flow rate. 20. The control method of claim 19 wherein the trigger of the new inhalation phase is based on comparing the determined difference and a memorized threshold. 21. The control method of claim 20 wherein the trigger of the new inhalation phase comprises determining when the determined difference exceeds the memorized threshold. 22. The control method of claim 20 further comprising controlling an exhalation valve of the expiratory duct. 23. The control method of claim 22 further comprising with the controller, selectively setting the exhalation valve to move between an open position and a closed position. 24. The control method of claim 22 further comprising in response to the trigger of the new inhalation phase, setting the exhalation valve to a closed position. 25. The control method of claim 18 further comprising with the controller, selectively setting the inhalation valve to move between an open position and a proportional position. 26. The control method of claim 18 further comprising in response to the trigger of the new inhalation phase, setting the inhalation valve to an open position from a closed position. 27. The control method of claim 18 wherein the expiratory duct includes an exhalation valve, and further comprising in response to the trigger of the new inhalation phase, setting the inhalation valve to an open position from a closed position and setting the exhalation valve to a closed position.
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이 특허에 인용된 특허 (19)
Tobia Ronald L., Adaptive control system for a medical ventilator.
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