Regenerative activated carbon filtration for aircraft obiggs

1 . An onboard aircraft inerting system comprising: a main inlet for connection to an upstream source of pressurized air, the pressurized air containing VOC contaminants; a filter module comprising an activated carbon media for adsorbing VOC contaminants from the air stream supplied thereto by the main inlet; a thermal control system upstream of the filter module for controlling the temperature of the air stream transported to the filter module; flow control components for directing air flow exiting the filter module; wherein in a normal mode, the flow control components direct filtered air exiting the filter module to a first passage connected to one or more air separation modules, and in a regeneration mode, the flow control components direct air exiting the filter module to a second passage connected to an overboard outlet for release to a lower pressure ambient environment; and wherein in regeneration mode the activated carbon media is operated at a higher temperature than in normal mode, the higher temperature being sufficient to desorb the VOC contaminants adsorbed during normal mode. 2 . The aircraft inerting system of claim 1 , further comprising an ozone converter upstream of the thermal control system. 3 . The aircraft inerting system of claim 1 , wherein the filter module further comprises a heating device for heating the activated carbon media. 4 . The aircraft inerting system of claim 1 , wherein the flow control components comprise a flow control valve and a system controller arranged to control operation of the flow control valve. 5 . The aircraft inerting system of claim 1 , wherein the pressurized air of the upstream source is at temperature of at least 50° C. 6 . The aircraft inerting system of claim 1 , wherein in regeneration mode, the air stream passing through the filter module is at a pressure lower than the air pressure of the air stream passing through the filter in normal mode. 7 . The aircraft inerting system of claim 1 , wherein the filter module further comprises a particulate and aerosol filter. 8 . The aircraft inerting system of claim 1 , further comprising a bypass line for diverting the air stream from the main inlet to the filter module so that the air stream bypasses the thermal control system upstream of the filter module. 9 . The aircraft inerting system of claim 8 , wherein the bypass line includes a flow control valve for directing flow through the bypass line and an orifice for controlling the flow and reducing the pressure of the flow to the filter module. 10 . The aircraft inerting system of claim 2 , further comprising a bypass line for diverting the air stream from the main inlet to the filter module so that the air stream bypasses the thermal control system and the ozone converter upstream of the filter module. 11 . The aircraft inerting system of claim 10 , wherein the bypass line includes a flow control valve for controlling flow through the bypass line and an orifice for reducing the pressure of the flow to the filter module. 12 . A method of regenerating an onboard aircraft inerting system comprising: providing a stream of pressurized air, the pressurized air containing VOC contaminants; passing the stream of air through a filter module containing activated carbon media to adsorb the VOC contaminants; directing the flow of air exiting the filter module in a regeneration mode of operation to a passage connected to an overboard outlet for release to a lower pressure ambient environment; regenerating the activated carbon media by desorbing the VOC contaminants adsorbed on the carbon media while the aircraft is in flight; wherein desorbing the VOC contaminants comprises raising the temperature of the carbon media to a temperature sufficient to release the VOC contaminants adsorbed thereon 13 . The method of claim 12 , wherein raising the temperature of the carbon media comprises heating the carbon media using a heating device located in the filter module. 14 . The method of claim 12 , wherein the stream of pressurized air containing VOC contaminants is at a temperature of at least 50° C. 15 . The method of claim 12 further comprising lowering the pressure of the air stream entering the filter module.