Model-based partial letdown thrust balancing

What is claimed is: 1. A combined cycle power plant comprising: an opposed flow steam turbine having a high pressure (HP) section and an intermediate pressure (IP) section, and a rotor axially disposed between the HP section and the IP section; a heat recovery steam generator (HRSG); a high pressure (HP) steam line that conducts steam from the HRSG to an inlet on the HP section; an intermediate pressure (IP) steam line that conducts steam from the HRSG to an inlet of the IP section; a high pressure (HP) exhaust line that returns exhaust from the HP section to the HRSG; a district heating (DH) system line that provides steam from the HRSG to a DH system; a valved letdown line that provides a variable fraction of steam from the IP steam line to the DH system via the DH system line; and a valved cascaded bypass line including a valve, wherein the cascaded bypass line provides a variable fraction of steam to the HP exhaust line from the HP steam line, the variable fraction of steam thereby bypassing the HP section, wherein the variable fraction ranges from none of the steam in the HP line when the valve is closed to a fractional portion of the steam in the HP line when the valve is open, and wherein the valve is opened and the fractional portion of steam is provided in response to a condition in which the fraction of steam provided from the IP steam line to the DH system line causes a thrust imbalance on the rotor between the HP section and the IP section. 2. The combined cycle power plant of claim 1 , further comprising a control system, the control system comprising: a computing device including a processor and a memory, the memory including instructions which when executed by the processor, cause the computing device to: receive at least one of steam flow, pressure, or temperature data measured at the inlet on the HP section; and predict or determine a presence or an absence of a thrust imbalance between the HP section and the IP section based on the at least one of the steam flow, pressure, or temperature data. 3. The combined cycle power plant of claim 2 , wherein the computing device is further operable to: enter the at least one of the steam flow, pressure, and temperature data into a model of the opposed flow steam turbine; and using the model and the steam flow, pressure, and temperature data, determine a thrust or a predicted thrust on the rotor in each of the HP section and IP section, wherein the presence or absence of a thrust imbalance between the HP section and the IP section is determined based on the determined or predicted thrust on the rotor in each of the HP section and the IP section. 4. The combined cycle power plant of claim 2 , wherein the computing device is further caused to: send a signal causing the valve in the cascaded bypass line to open at least partially, thereby increasing the fraction of steam provided to the HP exhaust line from the HP steam line, bypassing the HP section, in the event of predicting or determining that a thrust imbalance is present wherein a thrust in the HP section is greater than an opposing thrust in the IP section. 5. The combined cycle power plant of claim 2 , wherein the computing device is further caused to: send a signal causing the valve in the cascaded bypass line to close at least partially, thereby decreasing the fraction of steam provided to the HP exhaust line from the HP steam line, bypassing the HP section, in the event of predicting or determining that a thrust imbalance is present wherein a thrust in the IP section is greater than an opposing thrust in the HP section. 6. The combined cycle power plant of claim 1 , further comprising a gas turbine for providing hot gas, wherein the hot gas is conducted to the HRSG to generate steam. 7. The combined cycle power plant of claim 6 , wherein the gas turbine operates at less than Max-NL load and at or greater than about Min-NL load. 8. A combined cycle power plant comprising: an opposed flow steam turbine having a high pressure (HP) section and an intermediate pressure (IP) section, and a rotor axially disposed between the HP section and the IP section; a heat recovery steam generator (HRSG); a high pressure (HP) steam line that conducts steam from the HRSG to an inlet on the HP section; an intermediate pressure (IP) steam line that conducts steam from the HRSG to an inlet of the IP section; a high pressure (HP) exhaust line that returns exhaust from the HP section to the HRSG; a district heating (DH) system line that provides steam from the HRSG to a DH system; a valved letdown line that provides a variable fraction of steam from the IP steam line to the DH system via the DH system line; a valved cascaded bypass line including a valve, wherein the cascaded bypass line provides a variable fraction of steam to the HP exhaust line from the HP steam line, the variable fraction of steam thereby bypassing the HP section, wherein the variable fraction ranges from none of the steam in the HP line when the valve is closed to a fractional portion of the steam in the HP line when the valve is open, and wherein the valve is opened and the fractional portion of steam is provided in response to a condition in which the fraction of steam provided from the IP steam line to the DH system line causes a thrust imbalance on the rotor between the HP section and the IP section; and a control system, the control system comprising: a computing device including a processor and a memory, the memory including instructions which when executed by the processor, cause the computing device to: receive at least one of steam flow, pressure, or temperature data measured at the inlet on the HP section; predict or determine a presence or an absence of a thrust imbalance between the HP section and the IP section based on the at least one of the steam flow, pressure, or temperature data; enter the at least one of the steam flow, pressure, and temperature data into a model of the opposed flow steam turbine; and using the model and the steam flow, pressure, and temperature data, determine a thrust or a predicted thrust on the rotor in each of the HP section and IP section, wherein the presence or absence of a thrust imbalance between the HP section and the IP section is determined based on the determined or predicted thrust on the rotor in each of the HP section and the IP section. 9. The combined cycle power plant of claim 8 , further comprising a gas turbine for providing hot gas, wherein the hot gas is conducted to the HRSG to generate steam. 10. The combined cycle power plant of claim 9 , wherein the gas turbine operates at less than Max-NL load and at or greater than about Min-NL load. 11. A combined cycle power plant comprising: an opposed flow steam turbine having a high pressure (HP) section and an intermediate pressure (IP) section, and a rotor axially disposed between the HP section and the IP section; a heat recovery steam generator (HRSG); a gas turbine for providing hot gas, wherein the hot gas is conducted to the HRSG to generate steam, and wherein the gas turbine operates at less than Max-NL load and at or greater than about Min-NL load; a high pressure (HP) steam line that conducts steam from the HRSG to an inlet on the HP section; an intermediate pressure (IP) steam line that conducts steam from the HRSG to an inlet of the IP section; a high pressure (HP) exhaust line that returns exhaust from the HP section to the HRSG; a district heating (DH) system line that provides steam from the HRSG to a DH system; a valved letdown line that provides a variable fraction of steam from the IP steam line to the DH system via the DH system line; and a valved cascaded by