The present invention relates to air cooled condensers. In particular, the invention relates to new designs for turbine exhaust ducts for air cooled condensers.
Air cooled condensers are used in the power generation industry to cool the steam exhaust from a steam turbine and convert it to water for return to the power generation cycle. The spent steam from a power generation steam turbine is typically delivered to a turbine exhaust duct which carries the steam to multiple air cooled condenser sections or “streets,” arranged in parallel. According to typical arrangements, a horizontal turbine exhaust duct approaches the center of the air cooled condenser (ACC) assembly where it meets with a large and intricate T-piece that contains guide vanes to direct the steam. The T-piece, with the help of the guide vanes, splits the exhaust flow, directing half of the steam in one direction along the ACC assembly and directing the other half of the steam in the other direction along the ACC assembly, see, e.g.,
The horizontal turbine exhaust duct and the T-piece are each constructed of arcuate shell plates,
Field assembly and welding of the steam turbine exhaust duct T piece is often the most difficult and time consuming aspects of ACC assembly. Purchasers of ACCs and the erectors who assemble them in the field face very high costs to install them, and one of the contributory factors to the high install cost is the amount of labor and man hours it takes to do the field assembly and welding of the T piece. The field welding is very expensive when compared to the cost of welding done in the factory. Additionally, field welding is often less efficient and it is harder to control quality.
According to the present invention, there is presented a change in the design of the ACC which would result in substantially less field welding, making ACCs having this design much more attractive to purchase and erect.
According to embodiments of the invention, ACCs will cost less money to fabricate, as the new design will lessen the amount of ducting that is needed to be shipped to the site, and reduce the amount of field assembly and welding.
According to one aspect of the invention, there is provided a double turbine exhaust duct design that eliminates the need for the conventional T-piece in a turbine exhaust duct assembly.
According to another aspect of the invention, there is provided a turbine exhaust duct assembly configured to approach a field-assembled air-cooled condenser between a first riser and a second riser and to feed steam to at least said first and second risers, including a first set of two or more turbine exhaust ducts configured to receive steam from a turbine and to approach said air cooled condenser in substantially parallel configuration, a second set of two or more turbine exhaust ducts configured to run approximately perpendicular to streets of said air cooled condenser, each said turbine exhaust ducts in said second set configured to receive steam from a single turbine exhaust duct in said first set of turbine exhaust ducts via an exhaust duct elbow unit, wherein said second set of two or more turbine exhaust ducts are each connected to one or more risers, each of which are configured to supply steam to a single street of said air cooled condenser.
According to another aspect of the invention, there is provided a turbine exhaust duct assembly for a field-assembled air-cooled condenser including a single primary turbine exhaust duct connected at a first end to a turbine or to a turbine to exhaust duct transition element and connected at a second end to a first end of a single-flow-to-multiple-parallel-flow divider duct element, said divider duct element connected at an opposite end to two or more subsidiary elbow and duct assemblies each of which is configured to supply steam to one or more streets of said field assembled air-cooled condenser.
According to another aspect of the invention, there is provided a turbine exhaust duct assembly comprising a round-to-oval single flow to multiple parallel flow divider element, a plurality of elbow units attached at one end to a multiple flow end of said flow divider and attached at another end to single sloping riser duct, each said sloping riser duct configured to supply steam to one or more streets of said air cooled condenser
According to another aspect of the invention, there is provided an inline V turbine exhaust duct design that eliminates the need for the conventional T-piece in a turbine exhaust duct assembly.
According to another aspect of the invention, there is provided a turbine exhaust duct design and assembly that avoids the need for a T-piece.
According to another aspect of the invention, there is provided a double duct turbine exhaust duct assembly that eliminates the T-piece, substantially reducing the steam-side pressure drop, minimizing the sub-cooling in the steam cycle (the temperature difference between ACC condensate temperature out and turbine steam temperature), thus improving the overall efficiency of the steam cycle plant heat rate (more electrical MW out, less BTUs in).
According to another aspect of the invention, there is provided an inline V turbine exhaust duct assembly that eliminates the T-piece, substantially reducing the steam-side pressure drop, minimizing the sub-cooling in the steam cycle (the temperature difference between ACC condensate temperature out and turbine steam temperature), thus improving the overall efficiency of the steam cycle plant heat rate (more electrical MW out, less BTUs in).
According to another aspect of the invention, there is provided a method for substantially reducing the steam-side pressure drop, minimizing the sub-cooling in the steam cycle (the temperature difference between ACC condensate temperature out and turbine steam temperature), thus improving the overall efficiency of the steam cycle plant heat rate (more electrical MW out, less BTUs in), the method comprising delivery of spent plant steam to an ACC via a double duct turbine exhaust duct assembly, without the T-piece used in a conventional turbine exhaust design.
According to another aspect of the invention, there is provided a method for substantially reducing the steam-side pressure drop, minimizing the sub-cooling in the steam cycle (the temperature difference between ACC condensate temperature out and turbine steam temperature), thus improving the overall efficiency of the steam cycle plant heat rate (more electrical MW out, less BTUs in), the method comprising delivery of spent plant steam to an ACC via an inline V turbine exhaust duct assembly, without the T-piece used in a conventional turbine exhaust design.
According to another aspect of the invention, there is provided a method for reducing the required size of an ACC for a specified plant steam output and/or lowering the fan horsepower requirements of an ACC by reducing steam side pressure drop, the method comprising delivery of spent plant steam to an ACC via a double duct turbine exhaust duct assembly, without the T-piece used in a conventional turbine exhaust design.
According to another aspect of the invention, there is provided a method for reducing the required size of an ACC for a specified plant steam output and/or lowering the fan horsepower requirements of an ACC by reducing steam side pressure drop, the method comprising delivery of spent plant steam to an ACC via an inline V turbine exhaust duct assembly, without the T-piece used in a conventional turbine exhaust design.
According to another aspect of the invention, there is provided a method for facilitating de-aeration of a steam condensate, reducing corrosion in the steam cycle and for increasing the life of a power plant, the method comprising delivery of spent plant steam to an ACC via a double duct turbine exhaust duct assembly, without the T-piece used in a conventional turbine exhaust design.
According to another aspect of the invention, there is provided a method for facilitating de-aeration of a steam condensate, reducing corrosion in the steam cycle and for increasing the life of a power plant, the method comprising delivery of spent plant steam to an ACC via an inline V turbine exhaust duct assembly.
The subsequent description of the preferred embodiments of the present invention refers to the attached drawings, wherein:
In the following description, numerous details are set forth to provide a more thorough explanation of the present invention. It will be apparent, however, to one skilled in the art, that the present invention may be practiced without these specific details.
According to an additional advantage of this embodiment, the size of the exhaust tubes may be reduced by as much as 50% making it feasible to ship circumferentially assembled ducts to the final assembly location, significantly reducing the amount of field assembly and welding required. That is, instead of delivering many individual shell plates to make into a single run of TED (Turbine Exhaust Duct) and T piece at the site, embodiments of the invention provides the alternative of providing two circumferentially whole ducts. While the shipping of circumferentially assembled turbine exhaust ducts to the final assembly location requires break bulk load shipping, resulting in increased shipping costs, as well as increased manufacturing costs due to the shift of welding from the field to the factory, the elimination of significant field assembly and welding, and attendant difficulties, may be sufficient in some cases to offset the additional costs.
According to both the double-duct and V-shaped duct embodiments described above, the requirement for the T-shaped piece with the complicated guide vane system is eliminated. According to both designs, the overall assembly has fewer parts, is lighter in weight, and will be less expensive to supply and ship. The present designs also result in less field labor required to unload, handle, assemble and weld the turbine duct assemblies as it is delivered in fewer pieces, and reduces the amount of field welding required, reducing the amount of welding sets and welding consumables required at the site. The invention also reduces the risk and exposure to poor quality welding and poor labor efficiency at site. There will also be a resultant reduction of inspection costs as there will be many fewer field welds that need to be inspected. The new designs will, in addition, require less access scaffolding and scissor/JLG lifts. These changes all translate into a much reduced installed cost at site.
Additionally, by eliminating the T-shaped piece, the steam-side pressure drop is significantly reduced, minimizing the sub-cooling in the steam cycle, that is, the temperature difference between the ACC condensate temperature and the turbine steam temperature. This results in an improvement in the overall efficiency of the steam cycle plant heat rate. In addition, the reduction in steam side pressure drop also results in smaller ACCs and/or lower fan horsepower requirements on the ACC. The former results in lower capital investment costs; the latter results in lower plant operating costs. The reduced sub-cooling also facilitates an easier deaeration of the condensate. This reduces the corrosion in the complete steam cycle, resulting in an increase in the overall life of the power plant.
This application claims priority from U.S. Provisional Application No. 61/653,613 filed on May 31, 2012, and entitled “IMPROVED TURBINE EXHAUST DUCT DESIGN,” the specification of which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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61653613 | May 2012 | US |