Abstract

The increase in renewable energy penetration on the grid has accelerated the need to transition conventional fossil-based energy sources from their traditional base load operation to more flexible operational regimes. The mode of operation changed dramatically in terms of number of starts, operating hours per annum, and variation in load level. This results in greater thermal transients on operational equipment leading to an increase in Low Cycle Fatigue damage. To ensure the continued integrity of the steam turbine components, it is essential to assess the lifetime status by applying residual lifetime analysis methods. Depending on the amount of lifetime consumption and the extend of potential crack findings, different component repair options are possible. The rework or repair options can be divided into two main groups, namely, cold- and hot-rework. These two options can also be carried out consecutively. All rework or repair options provide the opportunity to improve the application of a component by applying profiling with improved stress fields and even superior materials, in the case of hot rework. The aim of the rework/reconditioning is to ensure that the steam turbine component is suitable for future operation. This ensures that plants are well placed to deliver more flexible operation in the energy industry through carefully tailored refurbishments and reworks.

References

1.
Biesinger
,
F.
,
Lorini
,
H.
, and
Kühne
,
C.
,
2021
, “
Repair Options for Steam Turbine Rotors Subject to Flexible Operation
,”
Proceedings of the 53
,
Kraftwerkstechnisches Kolloquium
,
Dresden
, Oct. 5–6, pp.
760
774
.
2.
General Electric Company,
2019
, “
GE Steam Power Product Catalog
,” General Electric, Baden, Switzerland, accessed Nov. 27, 2022, https://www.ge.com/content/dam/gepower-steam/global/en_US/documents/Steam-Product-Catalog.pdf
3.
U.S. Energy Information Administration
,
2022
, “State Energy Data System,” U.S. Energy Information Administration, Washington, DC, accessed Nov. 28, 2022, https://www.eia.gov/state/seds/seds-data-complete.php?sid=US#CompleteDataFile
4.
Federal Ministry for Economic Affairs and Energy (BMWi)
,
2014
, “An Electricity Market for Germany’s Energy Transition,” Federal Ministry for Economic Affairs and Energy (BMWi), Berlin, Germany, accessed July 22, 2016, https://www.bmwk.de/Redaktion/DE/Downloads/G/gruenbuch-gesamt-englisch.html
5.
Helbig
,
K.
,
2015
, “
Betriebsoptimierung Von Kraft-Werken im Kontext Vom Lebensdauermanagement
,”
VDI Wissensforum
,
Wiesbaden
, Germany.
6.
Biesinger
,
F.
,
Lorini
,
H.
, and
Knauf
,
H.-H.
,
2016
, “
Steam Turbines Subject to Flexible Operation
,”
Int. J. Electr. Heat Gener.
, (
11
), pp.
35
40
.
7.
Robinson
,
E. L.
,
1938
, “
Effect of Temperature Variations on the Creep Strength of Steels
,”
Trans. ASME
,
60
(
3
), pp.
253
259
.10.1115/1.4020680
8.
Palmgren
,
A.
,
1924
, “
Die Lebensdauer von Kugellagern
,”
VDI-Z
,
68
(
14
), pp.
339
341
.
9.
Miner
,
M. A.
,
1945
, “
Cumulative Damage in Fatigue
,”
ASME J. Appl. Mech.
,
12
(
3
), pp.
159
164
.10.1115/1.4009458
10.
Biesinger
,
F.
,
Enste
,
K.
, and
Steinbock
,
J.
,
2014
, “
Betrieb Von Kraftwerken - Ergebnisse Und Erfahrungen Bei Wartungsintervallen Und -Strategien in Bezug Auf Hochdruckarmaturen Der Turbogruppe
,”
Int. J. Electr. Heat Gener.
, (
10
), pp.
24
34
.
11.
Schaaf
,
T.
,
Vogt
,
J.
,
Mohr
,
W.
, and
Helbig
,
K.
,
2013
, “
Flexibility Improvement of Steam Turbines for Conventional and CCPPs
,”
PowerGen Europe
,
Vienna, Austria
.
12.
Miller
,
D.
,
Priest
,
R. H.
, and
Ellison
,
E. G.
,
1984
, “
A Review of Material Response and Life Prediction Techniques Under Fatigue-Creep Loading Conditions
,”
High Temp. Mater. Process
,
6
(
3 and 4
), pp.
155
194
.
You do not currently have access to this content.