EP3130767A1 - Combined high and intermediate pressure steam turbine - Google Patents

Abstract

The invention relates to a steam turbine (1) having a high and medium pressure region (5, 6) arranged in a common outer housing (4), which in turn are arranged in a high-pressure inner housing (11) and a medium-pressure inner housing (18) the medium pressure range is double-flow. The invention further relates to a method for operating the steam turbine at a speed of over 50 Hz.

Description

The invention relates to a steam turbine comprising a rotatably mounted rotor, wherein the rotor has a high pressure blading area comprising a plurality of rows of blades designed for high pressure steam and wherein the rotor further comprises a medium pressure blading area comprising a plurality of rows of blades configured for medium pressure steam further comprising a high pressure inner housing disposed about the high pressure blading area, further comprising a medium pressure inner housing disposed about the medium pressure blading area, further comprising an outer housing disposed about the high pressure inner housing and the intermediate pressure inner housing is.

Furthermore, the invention relates to a method for operating a steam turbine with speeds of over 50 Hz.

Steam turbines are used to generate electrical energy. In this case, steam is generated in a power plant with high temperatures and high pressure and fed to a steam turbine. The thermal energy of the steam is converted into rotational energy of the rotor of the steam turbine and generates electrical energy via a coupling with an electrical generator. The frequencies of the rotor in this case correspond as constant as possible to the respective mains frequency of 50 Hz or 60 Hz. It is quite advantageous to have the high-pressure and / or medium-pressure turbine parts rotate at a higher frequency and then adapt the rotational speed to the required speed via suitable transmissions , A higher frequency for the high and medium pressure turbine parts leads to a more compact design, which leads to lower costs. Furthermore, the efficiency of the turbine is improved by the high frequencies and the reduced size. These benefits can be the extra losses and costs incurred by the Use of a required transmission arise, usually at least compensate.

However, the speed of a medium-pressure turbine section is limited due to the larger volume flows in that the blade heights can not exceed a maximum limit due to the centrifugal forces. Thus, the speed of the high-pressure turbine section is limited by the einäusige design but also.

If the speed of the high-pressure turbine section is not to be limited by the medium-pressure turbine section, then the steam turbine would have to be built separately with their own speed and each bound by its own gear to the total strand, resulting in increased costs due to the zweigehäusige construction and additional losses caused by the second necessary transmission.

At this point, the invention begins.

It is an object of the invention to provide a steam turbine which is suitable for high speeds.

The object is achieved by a steam turbine comprising a rotatably mounted rotor, wherein the rotor has a high-pressure blading area comprising a plurality of row blades designed for high-pressure steam, and wherein the rotor further comprises a medium-pressure blading area comprising a plurality of rows of blades designed for medium-pressure steam , further comprising a high pressure inner housing disposed about the high pressure blading area. Further comprising a medium-pressure inner housing, which is arranged around the medium-pressure blading region. Further comprising an outer housing which is arranged around the high-pressure inner housing and medium-pressure inner housing, wherein the medium-pressure blading area is designed to be double-flowed.

The invention is further achieved by a method for operating a steam turbine with a speed of more than 50 Hz, wherein the steam turbine is formed with a high-pressure and medium-pressure region in a common housing, wherein the medium-pressure region is carried out in two columns.

With the invention thus the advantage is achieved to further increase the speed. This achieves the possibility of a higher speed in combination with a high pressure turbine part.

In the dependent claims advantageous developments are given.

Thus, in a first advantageous development, the steam turbine is developed in such a way that it has a high-pressure exhaust steam region, which is designed in such a way that steam flows out of the steam turbine during operation through the high-pressure blading region.

In a further advantageous development, the high-pressure blading area is designed for a high-pressure steam whose input has the following values: temperature T of 540 ° C. to 610 ° C. and pressure P of 100 bar to 280 bar.

In a further advantageous development of the invention, the medium-pressure blading region is designed for a medium-pressure steam having the following values on the input side: temperature T of 540 ° C. to 630 ° C. and pressure P of 30 bar to 60 bar.

The above-described characteristics, features and advantages of this invention, as well as the manner in which they are achieved, will become clearer and more clearly understood in connection with the following description of the embodiments which will be described in detail in conjunction with the drawings.

Embodiments of the invention will be described below with reference to the drawings. This is not intended to represent the embodiments significantly, but the drawing is illustrative only, executed in a schematized and / or slightly distorted form. With regard to additions to the teachings directly recognizable in the drawing reference is made to the relevant prior art.

The figure shows a schematic representation of the steam turbine according to the invention.

The figure shows a schematic representation of a steam turbine 1. The steam turbine 1 comprises a rotor 3 rotatably mounted about a rotation axis 2. The rotor 3 comprises a high pressure blading area 5 and a medium pressure blading area 6. The high pressure blading area 5 comprises a high pressure inflow area The high-pressure pressure flow channel 9 comprises high-pressure rotor blades 10 arranged on the rotor 3 and high-pressure stator blades 11 arranged in the high-pressure inner housing 12 (for reasons of clarity, only one was used in each case) High pressure bucket with the reference numeral 10 or 11 provided).

In operation, a high pressure steam typically having a temperature between 540 ° C and 610 ° C and a pressure between 100bar and 280bar flows. The thermal energy of the high-pressure steam is converted into mechanical energy of the rotor 3. After flowing through the high-pressure flow channel 9, the steam flows from the high-pressure blading region 5 into the high-pressure outflow region 12. The high-pressure steam subsequently flows out of the high-pressure outflow region 12 to a reheater unit (not shown), where it is again heated to a high temperature.

Subsequently, the steam flows into a medium-pressure inflow region 13 of the medium-pressure blading region 6. From the medium-pressure inflow region 13, the steam, which typically has temperatures between 540 ° C. and 630 ° C. and a pressure between 30 bar and 60 bar, flows into a medium-pressure flow channel 14. The flow channel 14 comprises a first flow 15 and one arranged in the opposite direction second tide 16 on. Both the first flow 15 and the second flow 16 have medium pressure guide vanes and blades 17. For clarity, only one blade is provided with the reference numeral 17 in each case. The blades 17 are disposed on the rotor 3 at the surface. The vanes 19 are arranged on an inner housing 18.

The steam flows into the inflow region 13 and thence through both the first flow 15 and the second flow 16. The thermal energy of the steam is converted into rotational energy of the rotor 3. The steam subsequently flows out of the medium-pressure outflow regions 20 into an intermediate space 21 between the outer housing 4 and the inner housings 18 and 11 and from there out of the steam turbine 1.

Although the invention has been further illustrated and described in detail by the preferred embodiment, the invention is not limited by the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Claims (5)

Steam turbine (1),
comprising a rotatably mounted rotor (3),
wherein the rotor (3) comprises a high pressure blading area (5) comprising a plurality of rows of blades (10) adapted for high pressure steam, and wherein the rotor (3) further comprises a medium pressure blading area (6) comprising a plurality of rows of blades having a medium-pressure steam is designed,
further comprising a high-pressure inner housing (11) arranged around the high-pressure blading area (5), further comprising a medium-pressure inner housing (18) arranged around the medium-pressure blading area (6), further comprising an outer housing (4 ) disposed around the high-pressure inner housing (11) and medium-pressure inner housing (18),
characterized in that
the medium-pressure blading area (6) is double-flowed. Steam turbine (1) according to claim 1,
comprising a high pressure exhaust zone formed such that a steam flowing in operation through the high pressure blading section (5) flows out of the steam turbine (1). Steam turbine (1) according to claim 1 or 2,
wherein the high-pressure blading region (5) is designed for a high-pressure steam whose input has the following values: temperature T of 540 ° C to 610 ° C and pressure P of 100bar to 280bar. Steam turbine (1) according to one of the preceding claims,
wherein the medium-pressure blading region (6) is designed for a medium-pressure steam having on the input side the following values: temperature T of 540 ° C to 630 ° C and pressure P of 30bar to 60bar. Method for operating a steam turbine (1) with a speed of more than 50 Hz,
wherein the steam turbine (1) is formed with a high-pressure and medium-pressure region in a common housing (4), wherein the medium-pressure region is designed to be double-flow.

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