Patent Grant
11776702
The present disclosure relates generally to externally-heated turbine engines, and more specifically to control systems for externally-heated turbine engines.
Externally-heated gas turbine engines may be used to power aircraft, watercraft, and power generators. Externally-heated gas turbine engines typically include a compressor and a turbine, but utilize an external heat exchanger and heat source to raise the temperature of the working fluid within the engine. In this arrangement, it is possible for no combustion products to travel through the turbine. This may allow externally-heated gas turbine engines to burn fuels that would ordinarily damage the internal components of the engine.
The compressor compresses air drawn into the engine and produces high pressure air for the external heat source. Heat is transferred to the high pressure air from the external heat source and the heated high pressure air is directed into the turbine where work is extracted to drive the compressor and, sometimes, a generator connected to an output shaft. Combustion products from the external heat source can be exhausted in an alternative region of the externally-heated turbine engine.
The present disclosure may comprise one or more of the following features and combinations thereof.
A power-generation system for a nuclear reactor may include a power unit, a reactor heat exchanger, and a temperature control system. The power unit may include a first generator and a turbine engine. The first generator may produce electric energy. The turbine engine may be coupled to and configured to drive the first generator. The turbine engine may include a compressor and a turbine. The compressor may be configured to receive and compress ambient air to produce compressed air. The turbine may be configured to receive the compressed air after the compressed air is heated to extract work from the compressed air and drive the first generator.
The reactor heat exchanger may be in fluid communication with the compressor and the turbine. The reactor heat exchanger may be configured to transfer heat continuously from a nuclear reactor to the compressed air to heat the compressed air during use of the power-generation system. The temperature control system may be configured to regulate a temperature of the compressed air so that the temperature of the compressed air received by the turbine is within a predetermined range. The temperature control system may include a temperature control heat exchanger, a first fluid source, and a controller. The temperature control heat exchanger may be connected between the compressor and the turbine. The temperature control heat exchanger may also be in fluid communication with both the compressed air and the first fluid source to transfer heat between the compressed air and a first fluid from the first fluid source.
The controller may be programmed to adjust a flow rate of the first fluid through the temperature control heat exchanger. The controller may adjust the flow rate based on the temperature of the compressed air received by the turbine and a load demand on the first generator.
In some embodiments the first fluid source may include a blower configured to provide a flow of ambient air as the first fluid. In other embodiments, the temperature control heat exchanger may be fluidly connected to the turbine engine and the reactor heat exchanger downstream of the compressor and upstream of the reactor heat exchanger. In another embodiment, the temperature control heat exchanger may be fluidly connected to the turbine engine and the reactor heat exchanger downstream of the reactor heat exchanger and upstream of the turbine.
In a further embodiment, the temperature control system may further include an auxiliary power unit and a mixing valve. The mixing valve may be in fluid communication with the blower, the auxiliary power unit, and the temperature control heat exchanger. The auxiliary power unit may be configured to produce electric power and exhaust a second fluid. The controller may further be programmed to adjust a flow rate of the first fluid and a flow rate of the second fluid through the mixing valve.
In some embodiments, the controller may be programmed to deactivate the auxiliary power unit in response to the reactor heat exchanger heating the compressed air to a threshold temperature. In another embodiment, the first fluid may have a first temperature and the second fluid may have a second temperature. The first temperature may be less than the second temperature.
In other embodiments, the power-generation system may further include an auxiliary combustor. The auxiliary combustor may be connected between the temperature control heat exchanger and the turbine. The auxiliary combustor may also be in fluid communication with the compressed air to transfer heat to the compressed air. The controller may be programmed to deactivate the blower and activate the auxiliary combustor in response to the compressed air being below a threshold temperature.
In a further embodiment, the power-generation system may further include an auxiliary combustor connected between the temperature control heat exchanger and the turbine. The auxiliary combustor may also be in fluid communication with the compressed air to transfer heat to the compressed air. The controller may be programmed to deactivate the blower and the auxiliary power unit and activate the auxiliary combustor in response to the compressed air being below a threshold temperature and an increased load demand on the first generator.
According to another aspect of the present disclosure, a power-generation system may include a power unit, a reactor heat exchanger, and a temperature control system. The power unit may include a first generator and a turbine engine. The turbine engine may be coupled to the first generator and configured to drive the first generator. The turbine engine may include a compressor and a turbine. The compressor may produce compressed air.
The reactor heat exchanger may be in fluid communication with the compressor and the turbine. The reactor heat exchanger may be configured to transfer heat from a nuclear reactor to the compressed air. The temperature control system may include a temperature control heat exchanger and a fluid source. The temperature control heat exchanger may be connected between the compressor and the turbine and in fluid communication with both the compressed air and the fluid source.
In some embodiments, the temperature control heat exchanger may be fluidly connected to the turbine engine and the cooling fluid source downstream of the compressor and upstream of the reactor heat exchanger. In another embodiment, the temperature control heat exchanger may be fluidly connected to the turbine engine and the cooling fluid source downstream of the reactor heat exchanger and upstream of the turbine.
In other embodiments, the temperature control system may further include a controller and a mixing valve. The mixing valve may be connected between the temperature control heat exchanger and the fluid source. The controller may be programmed to adjust the mixing valve to vary a flow rate of air through the mixing valve and to the temperature control heat exchanger.
In another embodiment, the fluid source may be a blower that provides a flow of cool ambient air to the mixing valve so that the temperature control heat exchanger extracts heat from the compressed air. In some embodiments, the controller may be programmed to increase the flow rate of the cool ambient air through the mixing valve in response to the temperature of the compressed air received by the turbine being above a predetermined temperature and a load demand on the first generator being above a predetermined output. In a further embodiment, the controller may be programmed to deactivate the blower in response to the temperature of the compressed air received by the turbine being below a predetermined temperature and a load demand on the first generator being below a predetermined output.
According to another aspect of the present disclosure, a method of operating a power-generation system for a nuclear reactor may include the steps of compressing air with a compressor, heating the compressed air with a reactor heat exchanger that is in thermal communication with a nuclear reactor, operating a fluid source to provide a heat transfer fluid, and transferring heat between the compressed air and the heat transfer fluid through a temperature control heat exchanger. The method may further include the steps of conducting the compressed air through a turbine after transferring heat between the compressed air and the heat transfer fluid, driving a generator with the turbine to produce an electrical power load, and controlling the flow of the heat transfer fluid through a mixing valve based on the temperature of the compressed air entering the turbine.
In some embodiments, the method may further include the step of deactivating the fluid source and closing the mixing valve in response to the temperature of the compressed air being below a predetermined value and the electrical power load from the generator being below a predetermined output. In another embodiment, the fluid source may be a blower configured to provide a flow of cool ambient air as the heat transfer fluid.
In other embodiments, the method may further include the step of activating the fluid source and opening the mixing valve in response to the temperature of the compressed air being above a predetermined value. The method may also activate the fluid source and open the mixing valve based on the electrical power load from the generator being above a predetermined output.
These and other features of the present disclosure will become more apparent from the following description of the illustrative embodiments.
For the purposes of promoting an understanding of the principles of the disclosure, reference will now be made to a number of illustrative embodiments illustrated in the drawings and specific language will be used to describe the same.
An illustrative power-generation system 10 includes a power unit 12, a reactor heat exchanger 14, and a temperature control system 16 as shown in
The temperature control system 16 includes a temperature control heat exchanger 32 fluidly connected with the compressor 24 so that it can increase or decrease the temperature of the compressed air 28 delivered to the turbine 26 to be within a predetermined range. The temperature control system 16 further includes a controller 40 and a fluid source 34 that may provide a first fluid 46 from a blower 42 and/or a second fluid 48 from an auxiliary power unit 44. In other embodiments, the fluid source 34 may be a canister of air or gas, a tank or supply of liquid, or other suitable alternative for providing cooling fluid. The controller 40 can individually and selectively vary the flow rate of the first fluid 46 and the second fluid 48 received by the temperature control heat exchanger 32. The varying flow rate of the fluids 46, 48 allows the controller to regulate the heat transferred between the compressed air 28 and the first and second fluids 46, 48 so that the system can respond to different power loads demanded by the power unit 12.
The power unit 12 includes a first generator 20 and the turbine engine 22 as shown in
The first generator 20 produces an electrical power load that may power an auxiliary device such as a building, aircraft, or provide additional electricity to an electrical grid. During operation of the power-generation system 10, a load demand of electrical power on the first generator 20 may vary such that the turbine 26 may need to provide more or less power to drive the first generator 20 to meet the load demand.
The reactor heat exchanger 14 is fluidly coupled with the compressor 24 and the turbine 26 and located external to the turbine engine 22 as shown in
The nuclear reactor 30 may be slow to initially generate and transfer heat through the reactor heat exchanger 14 and to the compressed air 28 in the startup mode. As such, other heat sources such as an auxiliary power unit and/or an auxiliary combustor 38 may be used to supplement the nuclear reactor heat during the startup mode.
During steady operation of the power-generation system 10, the nuclear reactor 30 provides generally constant heat that is transferred to the compressed air 28 via the reactor heat exchanger 14. The nuclear reactor 30 may be able to adjust its heat output, however, at a slow rate compared to the rate desired by the turbine engine 22. As such, if the load demand on the first generator 20 changes, the nuclear reactor heat may not be able to respond quickly enough. The blower 42 may supply cool air to cool the compressed air 28 relatively quickly so that the work extracted by the turbine 26 matches the demand on the first generator 20. In other embodiments, the reactor heat exchanger 14 may be fluidly coupled with another heat source to provide heat to the compressed air 28.
The temperature control system 16 regulates the temperature of the compressed air 28 received by the turbine 26 so that the turbine 26 can produce power to meet a load demand on the first generator 20 or to operate the turbine engine 22 at an idle speed. The temperature control system 16 includes a temperature control heat exchanger 32, a fluid source 34, a mixing valve 36, and a controller 40 as shown in
The temperature control system 16 regulates the temperature of the compressed air 28 received by the turbine 26 within a predetermined range that allows the turbine 26 to produce power to meet a load demand on the first generator 20. If the temperature of the compressed air 28 is above the predetermined range, the turbine 26 produces surplus power and drives the first generator to produce surplus electrical power above the load demand. If the temperature of the compressed air 28 is below the predetermined range, the turbine 26 may extract insufficient work from the compressed air 28 to meet the load demand on the first generator 20.
The temperature control system 16 also regulates the temperature of the compressed air 28 received by the turbine 26 to be at least at a threshold temperature. The threshold temperature of the compressed air 28 allows the turbine 26 to extract sufficient work from the compressed air 28 to operate the compressor 24 and the first generator 20 at an idle speed. If the compressed air 28 is below the threshold temperature, the turbine 26 may extract insufficient work from the compressed air 28 so that the turbine 26 cannot operate the compressor 24 and the first generator 20 at the idle speed without support from the temperature control system 16.
The temperature control heat exchanger 32 is fluidly coupled to the fluid source 34 via the mixing valve 36 to provide a flow of a fluid 46, 48 to the temperature control heat exchanger 32 as shown in
In the illustrative embodiment of
The auxiliary power unit 44 exhausts a second fluid 48 at a second temperature that flows to the temperature control heat exchanger 32. Illustratively, the second fluid is exhaust gases from an engine included in the auxiliary power unit 44. The first temperature of the first fluid 46 is less than the second temperature of the second fluid 48. The second fluid 48 transfers heat to the compressed air 28 when the second fluid 48 passes through the temperature control heat exchanger 32. The auxiliary power unit 44 further includes a second generator 50 to provide electrical power to the power-generation system 10 for example at the startup mode of the system 10.
In some embodiments, the auxiliary power unit 44 is a turbine engine having a compressor, combustor, and turbine. The compressor of the auxiliary power unit 44 receives and compresses ambient air and the combustor mixes the compressed ambient air with fuel and ignites the mixture. Work is extracted from the ignited mixture by the turbine of the auxiliary power unit 44, and the turbine is coupled with the second generator 50 to produce electrical power. In other embodiments, the second generator 50 is smaller (less kW) than the first generator 20 and provides sufficient electrical power for the components of the power-generation system 10 and does not output additional electrical power to auxiliary units or accessories.
The mixing valve 36 is fluidly coupled to the blower 42, the auxiliary power unit 44, and the temperature control heat exchanger 32 as shown in FIG. 1. The first fluid 46 and the second fluid 48 flow through the mixing valve 36 and the mixing valve 36 regulates the flow rate of the first fluid 46 and/or the second fluid 48 provided to the temperature control heat exchanger 32. The mixing valve 36 can be configured to allow only the first fluid 46 to pass through the mixing valve 36, only the second fluid 48 to pass through the mixing valve 36, or a mixture of the first fluid 46 and the second fluid 48 through the mixing valve 36. The flow rate of each of the first fluid 46 and the second fluid 48 may be individually and selectively adjusted.
In the illustrative embodiment, the temperature control system 16 further includes a bypass duct 52 that exhausts compressed air 28 exiting the temperature control heat exchanger 32 away from the turbine 26 and into ambient air as shown in
The controller 40 is connected to the turbine engine 22, the nuclear reactor 30, temperature control heat exchanger 32, the mixing valve 36, the auxiliary combustor 38, and the auxiliary power unit 44 in the illustrative embodiment as shown in
The controller 40 may selectively operate the mixing valve 36 in multiple different configurations to regulate the amount of the first fluid 46 and the second fluid 48 in the mixture that is provided to the temperature control heat exchanger 32 as shown in
In the illustrative embodiment shown in
In the illustrative embodiment shown in
In another embodiment, the controller 40 configuration shown in
In the illustrative embodiment of
In another embodiment, the controller 40 maintains operation of the power-generation system 10 in the running mode as shown in
In a further embodiment, the controller 40 maintains operation or the power-generation system 10 in the running mode as shown in
Another embodiment of a power-generation system 210 in accordance with the present disclosure is shown in
The power unit 212 includes a generator 220 and a turbine engine 222 as shown in
The temperature control system 216 regulates the temperature of the compressed air 228 received by the turbine 226 within a predetermined range that allows the turbine 226 to produce power to meet a load demand on the generator 220. The temperature control system 216 includes a temperature control heat exchanger 232, a blower 242, an auxiliary power unit 244, a mixing valve 236, and a controller 240 as shown in
The temperature control heat exchanger 232 is fluidly coupled to the blower 242 and the auxiliary power unit 244 via the mixing valve 236 to provide a flow of a first fluid 246 and a second fluid 248 respectively to the temperature control heat exchanger 232. The temperature control heat exchanger 232 is connected to and located between the compressor 224 and the reactor heat exchanger 214. The temperature control heat exchanger 232 is fluidly connected to the compressed air 228 and the first and second fluids 246, 248 and transfers heat therebetween.
The present disclosure may provide a manner for rapidly adjusting the output of an externally-heated gas turbine engine. Externally-heated gas turbine engines have been explored and developed for use in the power-generation market, but for most of these applications, the external-heated system may be easily adjusted by controlling the amount of fuel combusted. In some applications, such as nuclear fueled, the amount of heat produced may not be quickly adjusted to accommodate load changes of the power-generation system.
The power-generation system 10 as shown in
While the disclosure has been illustrated and described in detail in the foregoing drawings and description, the same is to be considered as exemplary and not restrictive in character, it being understood that only illustrative embodiments thereof have been shown and described and that all changes and modifications that come within the spirit of the disclosure are desired to be protected.
| Number | Name | Date | Kind |
|---|---|---|---|
| 3864919 | Frutschi | Feb 1975 | A |
| 4293384 | Weber | Oct 1981 | A |
| 4761957 | Eberhardt et al. | Aug 1988 | A |
| 5165239 | Bechtel et al. | Nov 1992 | A |
| 5799490 | Bronicki et al. | Sep 1998 | A |
| 8019522 | Coons | Sep 2011 | B2 |
| 10641121 | Skertic | May 2020 | B2 |
| 10801409 | Eifert | Oct 2020 | B2 |
| 10851704 | Homison | Dec 2020 | B2 |
| 20100050639 | Janus et al. | Mar 2010 | A1 |
| 20100064688 | Smith | Mar 2010 | A1 |
| 20190017443 | Eifert | Jan 2019 | A1 |
| 20190024527 | Skertic | Jan 2019 | A1 |
| 20200191048 | Homison | Jun 2020 | A1 |
| Entry |
|---|
| Ka At-Attab and Za Zainal, Externally Fired Gas Turbine Technology: A Review, Aug. 8, 2014, 14 pages. |
| Colin F. McDonald and Charles R. Boland, The Nuclear Closed-Cycle Gas Turbine—Dry Cooled Commercial Power Plant Studies, Nov. 1979, https://www.osti.gov/servlets/purl/5664698, 21 pages. |
| International Atomic Energy Agency, Gas Turbine Power Conversion Systems for modular HTGRs, Aug. 2001, https://www-pub.iaea.org/MTCD/Publications/PDF/te_1238_pm.pdf, 216 pages. |
| Number | Date | Country | |
|---|---|---|---|
| 20220254526 A1 | Aug 2022 | US |
