Abstract: Systems and methods for dynamic and automated control of a heating appliance based on atmospheric pressure conditions are provided. Particularly, a controller of the heating appliance may be configured to automatically adjust the amount of gas and/or air provided to the combustion chamber of the heating appliance based on changes in atmospheric pressure in the environment of the heating appliance. Changes in atmospheric pressure may impact the combustion process within the heating appliance, which may lead to inefficiencies in the operation of the heating appliance if the rate at which gas and/or air is provided remain constant during pressure changes. To mitigate these impacts, a barometric pressure sensor may be used to measure the atmospheric pressure at any given time and may provide this data to the controller. The controller may then adjust the rate at which gas and/or air is provided within the heating appliance to reduce such inefficiencies.

Abstract: An intense field dielectric air filtration system includes a perimeter frame for wall or ceiling mounting at the inlet of a return air duct for an air conditioning apparatus. A door including a grille disposed thereon is mounted for movement on the frame between working and non-working positions for access to an air filter unit, a pre-filter unit and an intense field particle charging unit. Contacts on the filter unit and the field charging unit engage cooperating contacts on an enclosure mounted on the frame when the door is closed to supply electrical power. An interlock is provided to interrupt power when the door is moved to an open position or the grille is removed. A control system disposed in the enclosure includes user control features accessible when the door is in an open position. An alternate embodiment includes a support frame for positioning the filtration system in ductwork or the like other than a return air inlet.

Abstract: An intense field dielectric air filtration system includes a perimeter frame for wall or ceiling mounting at the inlet of a return air duct for an air conditioning apparatus. A door including a grille disposed thereon is mounted for movement on the frame between working and non-working positions for access to an air filter unit, a pre-filter unit and an intense field particle charging unit. Contacts on the filter unit and the field charging unit engage cooperating contacts on an enclosure mounted on the frame when the door is closed to supply electrical power. An interlock is provided to interrupt power when the door is moved to an open position or the grille is removed. A control system disposed in the enclosure includes user control features accessible when the door is in an open position. An alternate embodiment includes a support frame for positioning the filtration system in ductwork or the like other than a return air inlet.