Email this article K-65-12.8 condensing steam turbine
- Authors: Valamin A.E.1, Kultyshev A.Y.1,2, Gol’dberg A.A.1, Sakhnin Y.A.1, Bilan V.N.1, Stepanov M.Y.1,2, Polyaeva E.N.1, Shekhter M.V.1, Shibaev T.L.1
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Affiliations:
- ZAO Ural Turbine Works
- Ural Federal University
- Issue: Vol 63, No 11 (2016)
- Pages: 771-776
- Section: Steam-Turbine, Gas-Turbine, and Combined-Cycle Plants and Their Auxiliary Equipment
- URL: https://journals.rcsi.science/0040-6015/article/view/172426
- DOI: https://doi.org/10.1134/S0040601516110100
- ID: 172426
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Abstract
A new condensing steam turbine K-65-12.8 is considered, which is the continuation of the development of the steam turbine family of 50–70 MW and the fresh steam pressure of 12.8 MPa, such as twocylinder T-50-12.8 and T-60/65-12.8 turbines. The turbine was developed using the modular design. The design and the main distinctive features of the turbine are described, such as a single two-housing cylinder with the steam flow loop; the extraction from the blading section for the regeneration, the inner needs, and heating; and the unification of some assemblies of serial turbines with shorter time of manufacture. The turbine uses the throttling steam distribution; steam from a boiler is supplied to a turbine through a separate valve block consisting of a central shut-off valve and two side control valves. The blading section of a turbine consists of 23 stages: the left flow contains ten stages installed in the inner housing and the right flow contains 13 stages with diaphragm placed in holders installed in the outer housing. The disks of the first 16 stages are forged together with a rotor, and the disks of the rest stages are mounted. Before the two last stages, the uncontrolled steam extraction is performed for the heating of a plant with the heat output of 38–75 GJ/h. Also, a turbine has five regenerative extraction points for feed water heating and the additional steam extraction to a collector for the inner needs with the consumption of up to 10 t/h. The feasibility parameters of a turbine plant are given. The main solutions for the heat flow diagram and the layout of a turbine plant are presented. The main principles and features of the microprocessor electro hydraulic control and protection system are formulated.
About the authors
A. E. Valamin
ZAO Ural Turbine Works
Author for correspondence.
Email: skbt@utz.ru
Russian Federation, ul. Frontovykh Brigad 18, Yekaterinburg, 620017
A. Yu. Kultyshev
ZAO Ural Turbine Works; Ural Federal University
Email: skbt@utz.ru
Russian Federation, ul. Frontovykh Brigad 18, Yekaterinburg, 620017; ul. Mira 19, Yekaterinburg, 620002
A. A. Gol’dberg
ZAO Ural Turbine Works
Email: skbt@utz.ru
Russian Federation, ul. Frontovykh Brigad 18, Yekaterinburg, 620017
Yu. A. Sakhnin
ZAO Ural Turbine Works
Email: skbt@utz.ru
Russian Federation, ul. Frontovykh Brigad 18, Yekaterinburg, 620017
V. N. Bilan
ZAO Ural Turbine Works
Email: skbt@utz.ru
Russian Federation, ul. Frontovykh Brigad 18, Yekaterinburg, 620017
M. Yu. Stepanov
ZAO Ural Turbine Works; Ural Federal University
Email: skbt@utz.ru
Russian Federation, ul. Frontovykh Brigad 18, Yekaterinburg, 620017; ul. Mira 19, Yekaterinburg, 620002
E. N. Polyaeva
ZAO Ural Turbine Works
Email: skbt@utz.ru
Russian Federation, ul. Frontovykh Brigad 18, Yekaterinburg, 620017
M. V. Shekhter
ZAO Ural Turbine Works
Email: skbt@utz.ru
Russian Federation, ul. Frontovykh Brigad 18, Yekaterinburg, 620017
T. L. Shibaev
ZAO Ural Turbine Works
Email: skbt@utz.ru
Russian Federation, ul. Frontovykh Brigad 18, Yekaterinburg, 620017
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