Control schemes for thermal management of power production systems and methods

The invention claimed is: 1. A method for control of a power production plant, the method comprising: passing a plurality of streams through a heat exchange unit (HEU) defining a first HEU end having a first operational temperature and a second HEU end having a second, lower operational temperature, the plurality of streams comprising at least a first, higher temperature stream passing from the first HEU end toward the second HEU end and at least a second, lower temperature stream passing from the second HEU end toward the first HEU end so that the at least a first, higher temperature stream is cooled and the at least a second, lower temperature stream is heated; and implementing a control function that causes a portion of the at least a first, higher temperature stream to bypass a section of the HEU so that a mass flow of the at least a first, higher temperature stream through the section that is bypassed is reduced, wherein the control function is implemented in response to a signal received by a controller and defining an operating condition of the power production plant, the signal comprising one or both of the following: a signal indicating a change in power demand effective to cause an operational change of a turbine altering power generation from the power production plant; a signal indicating that a temperature within the HEU is within a defined threshold of a maximum operating temperature of the HEU. 2. The method of claim 1 , wherein the at least a first, higher temperature stream includes a heated turbine exhaust stream from the turbine. 3. The method of claim 1 , wherein the at least a second, lower temperature stream is a recycle stream that is being heated in the HEU, wherein the at least a first, higher temperature stream is an exhaust stream being cooled in the HEU, and wherein a portion of the recycle stream is passed to the exhaust stream such that a mass flow of the exhaust stream passing through a section of the HEU is increased. 4. The method of claim 1 , wherein the at least a second, lower temperature stream is an oxidant stream that is being heated in the HEU, wherein the at least a first, higher temperature stream is an exhaust stream being cooled in the HEU, and wherein a portion of the oxidant stream is passed to the exhaust stream such that a mass flow of the exhaust stream passing through a section of the HEU is increased. 5. The method of claim 1 , further comprising adding heat to one or more of the plurality of streams passing through the HEU, wherein the heat is added at an intermediate temperature range within the HEU at a point that is positioned between the first HEU end and the second HEU end, and wherein the heat is added using a heater that is operated independent of the HEU. 6. The method of claim 5 , wherein the heater is a combustion heater. 7. The method of claim 6 , wherein the heat is added to a turbine exhaust stream passing through the HEU, and wherein an exhaust stream from the combustion heater is added directly to the turbine exhaust stream. 8. A power production plant comprising: a turbine; a power generator; a heat exchange unit (HEU); one or more compressors or pumps; and a control unit; wherein the HEU is configured for heat exchange between a plurality of streams passing between a first HEU end having a first operational temperature and a second HEU end having a second, lower operational temperature, the plurality of streams comprising at least a first stream passing from the first HEU end toward the second HEU end and at least a second stream passing from the second HEU end toward the first HEU end; wherein the HEU includes a recirculation line and a recirculation valve that are interposed between a turbine exhaust stream and a recycle stream or are interposed between a turbine exhaust stream and an oxidant stream; and wherein the control unit is configured to receive a signal defining an operating condition of the power production plant and, based thereon, output one or more signals effective to one or both of: divert a portion of one or more of the plurality of streams around a section of the HEU; and cause the recirculation line and the recirculation valve to implement flow of fluid between one of the at least a first stream and one of the at least a second stream. 9. The power production plant of claim 8 , further comprising a bypass line, a bypass valve, and a bypass heat exchanger operational with the bypass line. 10. The power production plant of claim 8 , further comprising a heater that is configured for operation independent of the HEU, the heater being configured for addition of heat to an exhaust stream from the turbine at a point that is positioned between the first HEU end and the second HEU end. 11. The power production plant of claim 10 , wherein the heater is a combustion heater. 12. A method for control of a power production plant, the method comprising: passing a plurality of streams through a heat exchange unit (HEU) defining a first HEU end having a first operational temperature and a second HEU end having a second, lower operational temperature, the plurality of streams comprising at least a first stream passing from the first HEU end toward the second HEU end and at least a second stream passing from the second HEU end toward the first HEU end so that the at least a first stream is cooled and the at least a second stream is heated; and implementing a control function that alters a mass flow of one or more of the plurality of streams passing through the HEU, the control function being effective to: cause a portion of the at least a first stream to be passed to the at least a second stream so that a mass flow of the at least a second stream is increased while passing through a section of the HEU; or cause a portion of the at least a second stream to be passed to the at least a first stream so that a mass flow of the at least a first stream is increased while passing through a section of the HEU. 13. The method of claim 12 , wherein the at least a second stream is a recycle stream that is being heated in the HEU, wherein the at least a first stream is an exhaust stream being cooled in the HEU, and wherein a portion of the recycle stream is passed to the exhaust stream such that a mass flow of the exhaust stream passing through a section of the HEU is increased. 14. The method of claim 12 , wherein the at least a second stream is an oxidant stream that is being heated in the HEU, wherein the at least a first stream is an exhaust stream being cooled in the HEU, and wherein a portion of the oxidant stream is passed to the exhaust stream such that a mass flow of the exhaust stream passing through a section of the HEU is increased. 15. The method of claim 14 , wherein the control function is executed in response to one or both of the following signals received by a controller: a signal indicating a change in power demand effective to cause an operational change of a turbine altering power generation from the power production plant; a signal indicating that a temperature within the HEU is within a defined threshold of a maximum operating temperature of the HEU. 16. A method for control of a power production plant, the method comprising: passing a plurality of streams through a heat exchange unit (HEU) defining a first HEU end having a first operational temperature and a second HEU end having a second, lower operational temperature, the plurality of streams comprising at least a first, higher temperature stream passing from the first HEU end toward the second HEU end and at least a second, lower temperature stream p