Method of air preheating for combustion power plant and systems comprising the same

What is claimed is: 1. A heat exchanger for transferring heat between a first gas flow and a second gas flow, the heat exchanger comprising: a housing having a first inlet plenum for receiving the first gas flow, a first outlet plenum for discharging the first gas flow, a second inlet plenum for receiving the second gas flow, and a second outlet plenum for discharging the second gas flow; where the first gas flow comprises a combustion air stream; and where the second gas flow comprises a reducer gas stream output from a reducer of a chemical looping system and an oxidizer gas stream output from an oxidizer of the chemical looping system and containing primarily nitrogen; a rotor disposed within the housing; heat exchange elements disposed in the rotor; the heat exchanger comprising at least three sectors; a first sector that is operative to receive a combustion air stream; a second sector that is opposed to the first sector and that is operative to receive the oxidizer gas stream and a third sector that is operative to receive the reducer gas stream, the first sector, the second sector and the third sector being divided from one another by sector plates that extend across the housing; and a pressurized layer disposed between the first sector and both of the second sector and the third sector and separating the first sector from both of the second sector and the third sector; where the pressurized layer is at a higher pressure than the combustion air stream, the reducer gas stream and the oxidizer gas stream so that the combustion air stream is prevented from leaking into either the oxidizer gas stream or the reducer gas stream; wherein a pressure of the combustion air stream in the first sector is greater than a pressure of the oxidizer gas stream in the second sector, and the pressure of the oxidizer gas stream in the second sector is greater than a pressure of the reducer gas stream in the third sector so that any pressure differential driven leakage that occurs between sectors is in a direction from the oxidizer gas stream towards the reducer gas stream. 2. The heat exchanger of claim 1 , where the pressurized layer is operative to receive either vent gas from a gas processing unit, an oxidizer gas stream from an oxidizer unit or both the vent gas and the oxidizer gas stream. 3. The heat exchanger of claim 1 , wherein the rotor rotates about a rotor post. 4. The heat exchanger of claim 1 , wherein the heat exchanger is a regenerative air preheater. 5. The heat exchanger of claim 1 , wherein the heat exchanger includes a fourth sector that is operative to receive a portion of the oxidizer gas stream; and wherein the pressurized layer is disposed between the first sector and the second sector, the third sector and the fourth sector. 6. The heat exchanger of claim 5 , wherein the third sector that is operative to receive the reducer gas stream lies between the second sector and the fourth sector that are operative to receive the oxidizer gas stream. 7. The heat exchanger of claim 1 , wherein the pressurized layer comprises a pressurized oxidizer gas stream that is at a higher pressure than the oxidizer gas stream that is received in the second sector. 8. A method for reducing gas leakage between a first gas flow and a second gas flow passing through a heat exchanger; said method comprising: providing a heat exchanger including: a housing having a first inlet plenum for receiving the first gas flow, a first outlet plenum for discharging the first gas flow, a second inlet plenum for receiving the second gas flow, and a second outlet plenum for discharging the second gas flow; where the first gas flow comprises a combustion air stream; and where the second gas flow comprises a reducer gas stream output from a reducer of a chemical looping system and an oxidizer gas stream output from an oxidizer of the chemical looping system and containing primarily nitrogen; a rotor disposed within the housing; heat exchange elements disposed in the rotor; the heat exchanger comprising at least two sectors; a first sector that is operative to receive the combustion air stream; and a second sector that is opposed to the first sector and that is operative to receive either the reducer gas stream, the oxidizer gas stream or both the reducer gas stream and the oxidizer gas stream, the first sector and the second being separated from one another by at least one sector plate that extends across the housing, and a pressurized layer disposed between the first sector and both the second sector; where the pressurized layer is at a higher pressure than the combustion air stream, the reducer gas stream and the oxidizer gas stream; heating a portion of the heat exchanger with heat derived from the reducer gas stream and/ or the oxidizer gas stream; and heating the combustion air stream with the portion of the heat exchanger that derives its heat from the reducer gas stream and/ or the oxidizer gas stream; wherein the pressurized layer is formed by pressurizing a portion of the oxidizer gas stream and discharging the pressurized portion of the oxidizer gas stream into the pressurized layer. 9. The method of claim 8 , further comprising rotating the heat exchange elements about a rotor post. 10. The heat exchanger of claim 2 , wherein the vent gas, oxidizer gas stream or the vent gas and oxidizer gas stream is heated with a heater prior to being received by the pressurize layer. 11. The method of claim 8 , further comprising the step of heating the pressurized portion of the oxidizer gas stream before discharge to the pressurized layer. 12. A heat exchanger for transferring heat between a first gas flow and a second gas flow, the heat exchanger comprising: a housing having a first inlet plenum for receiving the first gas flow, a first outlet plenum for discharging the first gas flow, a second inlet plenum for receiving the second gas flow, and a second outlet plenum for discharging the second gas flow; where the first gas flow comprises a combustion air stream; and where the second gas flow comprises a reducer gas stream output from a reducer of a chemical looping system and an oxidizer gas stream output from an oxidizer of the chemical looping system and containing primarily nitrogen; a rotor disposed within the housing; heat exchange elements disposed in the rotor; the heat exchanger comprising at least four sectors; a first sector that is operative to receive a combustion air stream; a second sector that is opposed to the first sector and that is operative to receive a first portion of the oxidizer gas stream, a third sector that is operative to receive the reducer gas stream, and a fourth sector that is opposed to the first sector and that is operative to receive a second portion of the oxidizer gas stream, the first sector, the second sector, the third sector and the fourth sector being divided from one another by sector plates that extend across the housing; and a pressurized layer disposed between the first sector and each of the second sector, the third sector and the fourth sector and separating the first sector from each of the second sector, the third sector and the fourth sector; where the pressurized layer is at a higher pressure than the combustion air stream, the reducer gas stream and both the first portion and the second portion oxidizer gas stream so that the combustion air stream is prevented from leaking into either the first portion and the second portion of the oxidizer gas stream or the reducer gas stream; wherein the third sector that is operative to receive the reducer gas stream lies between the second sector and the fourth sector that are operative to receive the first p