Patent Application
20200284428
Embodiments of the invention relate generally to power generation and, more particularly, to a system and method for accommodating thermal displacement in a power generation plant.
The generation of electrical energy by means of coal-fired power generation plants is being constantly improved in terms of reduced environmental impact of coal combustion and an increase in the efficiencies of the plants. These improvements are largely driven by an increased focus on reducing the emissions associated with the combustion of coal, in an order to mitigate climate impacts.
The thermodynamic efficiency in a steam turbine-based power plant depends at least in part on the temperature and pressure of the steam, specifically, the higher the temperature and pressure of the steam, the greater the potential efficiency. Consequently, there has been a move in recent years to employ even higher steam temperatures and pressures than in the past. This trend has led to the development of new classes of power plants including a so-called “ultra-supercritical power plant” (which uses steam cycles at temperatures greater than about 600° C. and steam pressures in excess of 240 bar), and the advanced ultra-supercritical power plant (which uses steam cycles at even greater temperatures, in the range of about 700° C. to about 760° C.).
Maximum steam temperatures are limited, however, by the physical properties of the materials used to form components, such as the boiler steam pipes, that are exposed to the high-temperature steam. Typically, such materials lose strength as the temperature to which they are exposed rises. Historically, the development of stronger steels and alloys have enabled the use of higher steam temperatures in boilers—from subcritical steam temperatures to supercritical steam temperatures, and more recently, ultra-supercritical and advanced ultra-supercritical. To withstand the high pressure and temperature conditions that define these known classes of power plants, specialist alloys (e.g., nickel alloys) are required, especially for the superheater and for the piping that carries or conveys the steam from the steam generator to the turbine(s) (including the main steam piping and hot reheat piping).
In a typical power plant, particularly ultra-supercritical and advanced ultra-supercritical power plants, the steam generator (boiler) can often be in excess of 100 meters tall, and the main steam outlet and hot reheat outlet are typically located in a top portion of the boiler (i.e., well above ground level). Relatively long lengths of main steam piping and hot reheat piping are therefore necessary to connect the main steam outlet headers and hot reheat outlet headers at the top portion of the boiler to the turbines (e.g., the high-pressure turbine and intermediate pressure turbine, respectively), which are typically located at ground level. These long lengths of piping for such critical piping systems can contribute substantially to the cost of the power plant, particularly where much more expensive nickel-based alloys are utilized due to the increasingly higher steam temperatures.
Accordingly, recent developments in power plant design have also focused on ways of minimizing material costs for these critical piping systems. For example, existing solutions have involved elevating the turbines above ground level to bring the turbine inlets closer to the main steam outlet (and main steam outlet headers) and hot reheat outlet (and hot reheat outlet headers). By shortening the distance between these connection points, shorter lengths of piping could theoretically be utilized, thereby decreasing material costs.
Bringing the connection points closer together to thereby shorten the main steam piping and hot reheat piping, however, can present other challenges when trying to accommodate higher steam temperatures during system operation. In particular, at such high operating temperatures, the boiler, outlet headers, turbines and piping will expand (referred to herein as “thermal displacement” or “thermal expansion”). The rigid piping typically used in boiler applications are unable to accommodate thermal displacement, which can lead to the overstressing of system components. To avoid overstressing, it is therefore typically necessary to arrange “expansion loops” in serial fluid communication with the main steam and hot reheat piping runs. Such expansion loops are typically fabricated from standard pipes and elbows, having the same wall thickness and inside diameter of the pipes of the boiler piping system and are conventionally employed to absorb temperature expansion and contraction in steel pipes. However, the use of such expansion loops results in the need for additional pipe length (e.g., to form the expansion loops) and material costs.
In view of the above, there is therefore a need for a main steam and hot reheat piping arrangement whereby the length of such piping can be significantly reduced as compared to conventional power plant systems to decrease material costs, while also accommodating thermal expansion of boiler components during system operation to avoid overstressing.
A system for a power generation plant is provided. The system includes a boiler having a superheater, a first header fluidly coupled to an outlet of the superheater and being configured to receive steam from the superheater. A turbine is positioned generally adjacent to the outlet of the superheater, and a main steam piping system extends from the first header to the turbine and is arranged to direct a flow of the steam from the first header to the turbine. The system also includes a first flexible portion upstream from the first header, fluidly coupled between the first header and the boiler.
In another embodiment, a system for a power generation plant is provided. The system includes a boiler having a superheater and a reheater. A main steam outlet header is fluidly coupled to an outlet of the superheater and is arranged to receive steam from the superheater. A hot reheat outlet header is fluidly coupled to an outlet of the reheater and is arranged to receive steam from the reheater. The system further includes a high-pressure turbine adjacent to the outlet of the superheater, and an intermediate-pressure turbine adjacent to the outlet of the reheater. A main steam piping system extends from the main steam outlet header to the high-pressure turbine and is configured to direct a flow of the steam from the main steam piping system to the high-pressure turbine. A hot reheat piping system extends from the hot reheat outlet header to the intermediate-pressure turbine and is configured to direct a flow of the steam from the hot reheat piping system to the intermediate-pressure turbine. The system includes a first flexible portion upstream from the main steam outlet header which is operative to flex with respect to the main steam outlet header and the boiler in response to a thermal displacement of the boiler; and the system further includes a second flexible portion upstream from the hot reheat outlet header which is operative to flex with respect to the hot reheat outlet header and the boiler in response to the thermal displacement of the boiler.
The present invention will be better understood from reading the following description of non-limiting embodiments, with reference to the attached drawings, wherein below:
Reference will be made below in detail to exemplary embodiments of the invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference characters used throughout the drawings refer to the same or like parts. While embodiments of the invention are suitable for coal-fired power plants, embodiments of the invention may also be suitable for any type of power generation facility where thermal displacements must be accommodated.
As used herein, “operatively coupled” refers to a connection, which may be direct or indirect. The connection is not necessarily a mechanical attachment. As used herein, “fluidly coupled” or “fluid communication” refers to an arrangement of two or more features such that the features are connected in such a way as to permit the flow of fluid between the features and permits fluid transfer.
Embodiments of the invention relate to a system and method for accommodating thermal displacements of components in a power generation plant. The system includes a boiler having a superheater, a first header fluidly coupled to an outlet of the superheater and being configured to receive steam from the superheater, a turbine elevated to a location generally adjacent to the outlet of the superheater, and a main steam piping system extending from the first header to the turbine and being configured to direct a flow of the steam from the first header to the turbine. The system further includes a flexible portion upstream from the first header allowing located between the first header and the boiler and operative to flex in response to to thermal displacement of the boiler. In an embodiment, the flexible portion may comprise a plurality of flexible or bendable tubes that operatively couple corresponding tubes of the superheater in fluid communication with the first header.
Referring to
The high-temperature steam turbines HP1, IP1 and high-pressure gas turbine HPT operate at high temperatures since their components are manufactured from nickel-based or other specialty alloy materials. Main steam piping system 18, hot reheat piping system 20, and piping system 22, are also manufactured from nickel-based or other specialty alloy materials. These piping systems 18, 20, 22 each comprise a plurality of pipes that may be run over a minimal length due to the vertical arrangement of the turbines parallel with the boiler. Their minimal length provides a significant cost saving in view of the high costs of the nickel-based or other specialty alloy materials. In an embodiment, rather than being arranged vertically, the turbines may simply be elevated from the ground level so as to be in close association with the steam outlets of the boiler (namely, the outlets of the headers from which the turbines are fed).
In operation, feedwater is fed via line 14 into boiler 12, and is there heated in the evaporator and superheater to a temperature in excess of, for example, 700° C. at a pressure of 350 bar and, more particularly, to a temperature between about 700° C. and 820° C. at a pressure of between about 350 bar and 425 bar. From the boiler, the superheated steam is fed to the main steam piping system 18 via the header 19, and to high temperature high pressure steam turbine HP1, where the steam is expanded. The expanded steam, which still has a temperature in excess of at least 600° C., for example, is then fed via a line 24 to a conventional high-pressure steam turbine HP2. Together with a conventional intermediate-pressure steam turbine IP2, a conventional low-pressure steam turbine LP2 and a second generator G2, this forms a conventional turbo train arranged on a second rotor 26.
The steam expanded in conventional high-pressure steam turbine HP2 is returned via a line 16 (e.g., cold reheat piping) to boiler 12, where it is again heated in the reheater 13. This reheated steam is fed to the hot reheat piping system 20 via the header 21, into high temperature intermediate pressure steam turbine IP1. The steam expanded in IP1 is fed via a line 28 to conventional intermediate-pressure steam turbine IP2 and there further expanded and further expanded in the series connected low-pressure steam turbine LP2. Finally, the steam is fed to a condensation and feedwater heating facility 50.
Piping system 22 feeds exhaust gas from boiler 12 via a high-temperature filter 30 to high pressure gas turbine HPT, in which the exhaust gas is expanded. The expanded exhaust gas is then fed to a series connected controllable low-pressure gas turbine LPT arranged on a separate rotor. The exhaust gas is further expanded therein and then fed to a selective catalytic reducer SCR in order to reduce nitrogen oxides. The exhaust gas may then be fed to a series of exhaust gas heated feedwater heaters (not shown).
Turning now to
As illustrated in
In an embodiment, the main steam piping system 18 and hot reheat piping system 20 may be outfitted with main steam bypass valves 42 and hot reheat bypass valves 44 to selectively control the flow of steam therethrough, as shown in
In an embodiment, the connecting tubes 45, 47 of the connecting tube arrays 46, 48 are arranged extending from, and in fluid communication with, corresponding heat exchanger tubes of the superheater 15 and reheater 13, for example by welding or mechanically coupling, and may generally have the same wall thickness and diameter as the heat exchanger tubes of the superheater and reheater.
As best illustrated in
In particular, to compensate for the horizontal and vertical thermal displacement from the boiler and the thermal displacement from the turbine and critical piping, the headers 19, 21 are located outside the main steel structure of the boiler 12, and are thus essentially ‘decoupled’ or separated from the boiler 12. The connecting tube arrays 46, 48 extend from the heat exchanger tube bundles within the boiler 12 (e.g., the superheater 15 and reheater 13, respectively), and are fluidly connected to the headers 19, 21 outside the main structure of the boiler 12. Because the connecting tube arrays 46, 48 comprise relatively thin-walled tubes having small diameters (e.g., about 1.5 inches in one embodiment), these tubes 45, 47 are operative to more readily elastically bend and flex than typical piping having thicker walls and larger diameters that is conventionally fluidly coupled to the heat exchanger tube bundles.
In particular, the horizontal header connecting tube portions 52 of the connecting tube arrays 46, 48 allow for thermal expansion of the boiler in the vertical direction, as they are able to deflect upwardly and downwardly as the boiler expands and contracts in the vertical direction. Similarly, the vertical header connecting tube portions 54 of the connecting tube arrays 46, 48 allow for thermal expansion of the boiler in the horizontal direction and for thermal expansions from the turbine(s), piping 18, 20, and outlet headers 19, 21, as they are able to deflect laterally as these components expand and contract laterally. In an embodiment, the outlet headers 19, 21 may be supported on z-stops, but they are otherwise able to expand horizontally towards the boiler due to the thermal expansion of the turbine and piping 18, 20.
In contrast to existing designs where the main steam outlet header and hot reheat outlet header are essentially coupled to the boiler, e.g., through a substantially rigid connection with the enclosing walls of the boiler, the main steam outlet header 19 and/or hot reheat outlet header 21 are moved outside of the main enclosing walls of the boiler 12 and fixedly integrated with the main steam piping system 18 and hot reheat piping 20 system, respectively.
As noted hereinabove, while it was previously necessary to accommodate thermal displacement in the piping systems coupled to the heat exchanger tube bundles by arranging expansion loops or like structures between the outlet headers and the turbine (i.e., within the main steam and hot reheating piping downstream from the headers), the embodiments described herein eliminate this need. By disposing the outlet headers 19, 21 outside of the boiler 12 structure, and fluidly coupling the flexible tube arrays 46, 48 between the outlet headers 19, 21 and the boiler 12 (i.e., upstream of the headers), the small diameter tubes 45, 47 of the tube arrays 46, 48 defining the at least one flexible coupling tube portion 56, flexibly accommodate thermal displacement events. In an embodiment, the system 10 includes a first flexible coupling tube portion 56 disposed upstream from the first header 19 is fluidly coupled between the first header 19 and the boiler 12 operative to flex relative the first header 19 and the boiler 12 in response to a thermal displacement of the boiler. In an embodiment the system 10 may include a second flexible coupling tube portion 56 upstream from the second header 21 operative to flex relative the second header 21 and the boiler 12 in response to a thermal displacement of the boiler. The flexure provided by relatively small diameter tubes 45, 47 of the tube arrays 46, 48 accommodate thermal expansion and contraction of system components, minimizing or preventing the buildup of stresses in the piping 18, 20 system.
By disposing the flexible coupling tube portion 56 defined by the tube arrays 46, 48 upstream from the headers 19, 21 (again, by locating the headers outside the boiler 12 and by using the plurality of narrow thin-walled tubes to provide flexibility during thermal expansion), no expansion loops or like structures that would be typically necessary to allow for flexure are needed in the thicker-walled main steam piping system and hot reheat piping system, thereby allowing the lengths of piping for such systems to be greatly minimized. As discussed above, this can significantly reduce the costs of manufacture of a power plant as a whole, particularly where very expensive, specialty alloys (e.g., nickel based alloys) are used for critical piping systems. In addition to substantial cost savings, using short piping lengths for the main steam and hot reheat piping also results in faster manufacturing and reduced assembly time.
The configuration of the system of the invention, namely, the particular arrangement of the main steam piping system, hot reheat piping system, outlet headers and connecting tube arrays discussed above, allows the headers 19, 21, critical piping systems and turbines to move/expand relative to the boiler 12, and vice versa. As set forth in detail above, this configuration arranges at least one flexible coupling tube portion 56 of the system located upstream from the headers 19, 21 (between the superheater/reheater and the headers 19, 21, indicated generally by flexible coupling tube portion 56 in
While the header connecting tubes have been described herein as being able to bend or flex to provide flexibility to the system to accommodate relative movement between the boiler and headers as a result of their relatively thin-walled and/or smaller diameter construction as compared to the relatively thick-walled and/or larger diameter main steam and hot reheat piping, it is contemplated that the ability to provide relative movement between the boiler and headers may be achieved by other means as well. For example, a greater flexing or bending ability may be provided in the header connecting tubes as compared to the main steam and hot reheat piping by varying the parameters of the header connecting tubes as compared to the main steam and hot reheat piping. Varying the parameters may include for example, providing the header connecting tubes with thinner walls, smaller diameter, different material selection, or other different material properties that facilitate bending as compared to the main steam and hot reheat piping.
As used herein, an element or step recited in the singular and proceeded with the word “a” or “an” should be understood as not excluding plural of said elements or steps, unless such exclusion is explicitly stated. Furthermore, references to “one embodiment” of the present invention are not intended to be interpreted as excluding the existence of additional embodiments that also incorporate the recited features. Moreover, unless explicitly stated to the contrary, embodiments “comprising,” “including,” or “having” an element or a plurality of elements having a particular property may include additional such elements not having that property.
This written description uses examples to disclose several embodiments of the invention, including the best mode, and also to enable one of ordinary skill in the art to practice the embodiments of invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to one of ordinary skill in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2018/082856 | 11/28/2018 | WO | 00 |
| Number | Date | Country | |
|---|---|---|---|
| 62591471 | Nov 2017 | US |
