Energy-harvesting respiratory method and device
First Claim
1. A device for providing respiratory assistance comprising:
- one or more sensors that monitor respiratory activity;
a microchip or microscale computer which receives signals from the one or more sensors;
an energy-harvesting impeller or turbine which is rotated by gas outflow during exhalation;
a generator which is driven by rotation of the energy-harvesting impeller or turbine, wherein electricity generated by the generator is accumulated and stored over the span of X normal respiratory cycles, and wherein X is greater than 5;
an energy-using impeller or turbine which increases gas inflow during inhalation; and
an actuator which drives the rotation of the energy-using impeller or turbine, wherein this actuator is controlled by the microchip or other microscale computer so as to use the electricity which was accumulated and stored over the span of X normal respiratory cycles to drive the rotation of the energy-using impeller or turbine during a specific respiratory cycle when signals from the one or more sensors indicate that gas inflow is needed to correct, or avoid, an acute episode of a respiratory condition, and wherein the generator and the actuator are separate energy-transducing members.
1 Assignment
0 Petitions
Accused Products
Abstract
This invention is a method, device, and system to provide respiratory assistance to people with Obstructive Sleep Apnea (OSA), or other respiratory conditions, comprising harvesting and storing energy from gas outflow during exhalation and using that stored energy to increase gas inflow during inhalation. In an example, this invention may provide Positive End-Expiratory Pressure (PEEP) or Continuous positive Airway Pressure (CPAP). This invention can be embodied in a self-contained energy-harvesting positive airway pressure mask, nasal inserts, or mouth appliance. This invention offers a combination of the following five benefits for Obstructive Sleep Apnea (OSA) treatment: minimally-invasive; energy self-sufficient; freedom of movement; hypercapnia avoidance; and adjustable energy harvesting over multiple respiratory cycles.
-
Citations
3 Claims
-
1. A device for providing respiratory assistance comprising:
-
one or more sensors that monitor respiratory activity; a microchip or microscale computer which receives signals from the one or more sensors; an energy-harvesting impeller or turbine which is rotated by gas outflow during exhalation; a generator which is driven by rotation of the energy-harvesting impeller or turbine, wherein electricity generated by the generator is accumulated and stored over the span of X normal respiratory cycles, and wherein X is greater than 5; an energy-using impeller or turbine which increases gas inflow during inhalation; and an actuator which drives the rotation of the energy-using impeller or turbine, wherein this actuator is controlled by the microchip or other microscale computer so as to use the electricity which was accumulated and stored over the span of X normal respiratory cycles to drive the rotation of the energy-using impeller or turbine during a specific respiratory cycle when signals from the one or more sensors indicate that gas inflow is needed to correct, or avoid, an acute episode of a respiratory condition, and wherein the generator and the actuator are separate energy-transducing members.
-
-
2. A device for providing respiratory assistance comprising:
-
one or more sensors that monitor respiratory activity; a microchip or microscale computer which receives signals from the one or more sensors; an energy-harvesting impeller or turbine which is rotated by gas outflow during exhalation; a generator which is driven by rotation of the energy-harvesting impeller or turbine, wherein electricity generated by the generator is accumulated and stored over the span of X normal respiratory cycles, and wherein X is greater than 5; an energy-using impeller or turbine which increases gas inflow during inhalation; and an actuator which drives the rotation of the energy-using impeller or turbine, wherein this actuator is controlled by the microchip or other microscale computer so as to use the electricity which was accumulated and stored over the span of X normal respiratory cycles to drive the rotation of the energy-using impeller or turbine during a specific respiratory cycle when signals from the one or more sensors indicate that gas inflow is needed to correct, or avoid, an acute episode of a respiratory condition, and wherein there are two gas flow channels, a first channel for exhalation and a second channel for inhalation, and wherein the energy-harvesting impeller or turbine is in the first channel and the energy-using impeller or turbine is in the second channel. - View Dependent Claims (3)
-
Specification