EP3561238A1 - Assembly for a steam turbine - Google Patents

Abstract

The invention relates to an arrangement comprising a steam turbine (2) and two additional steam lines to the steam turbine (2), wherein in each steam supply line, a diaphragm (10, 11) is arranged to thereby minimize unwanted rotor vibrations.

Description

The invention relates to an arrangement comprising a steam turbine, a steam supply, which is fluidly connected to an inflow of the steam turbine, wherein the inflow is fluidly connected to a flow channel and a steam valve, which is arranged in the steam supply, further comprising an additional steam line, the fluidic with an auxiliary inflow area of the steam turbine is connected, an additional steam valve, which is arranged in the additional steam line, wherein the Zusatzinströmbereich is arranged downstream of the flow channel.

Steam turbines usually include several sub-turbines, which are classified, for example, in a high-pressure, medium-pressure and low-pressure turbine section. There are embodiments of steam turbines comprising a plurality of sub-turbines and having a common shaft. The length of the shaft is comparatively long. In a steam generator, a live steam is generated. This live steam passes through live steam lines and a live steam valve in a high-pressure turbine section. This live steam usually flows into an inflow region of a high-pressure turbine part, wherein the inflow region opens into a flow channel, which is characterized by guide vanes and rotor blades. In the flow channel, the thermal energy of the steam is converted into a rotational energy of the wave.

In addition to the main valve, through which a live steam flows, there are embodiments in which an additional steam mass flow flows into the steam turbine to increase performance. This additional vapor mass flow is inserted downstream into the flow channel. However, the introduction of the additional vapor mass flow leads to conditions that act on the rotor, which carries the risk that the rotor could be excited to vibrate.

In order to keep the forces acting on the rotor by the introduction of the additional steam mass flow low, it is possible to divide this additional steam mass flow into two pipes after a steam valve, which may be an additional steam valve. The flow field in the area of the split between the two pipelines may be of a strongly transient nature, so that periodic disturbances in the two pipelines downstream can be initiated, which could lead to undesirable rotor vibration.

It is an object of the invention to provide a way in which the risk of rotor vibrations in the introduction of an additional mass flow is minimized.

This object is achieved by an arrangement comprising a steam turbine, a steam supply line, which is fluidically connected to an inflow region of the steam turbine, wherein the inflow region is fluidically connected to a flow channel and a steam valve, which is arranged in the steam supply line, further comprising an additional steam line, which is fluidically connected to an additional inflow region of the steam turbine, an additional steam valve which is arranged in the additional steam line, the additional inflow region being arranged downstream of the flow channel, a means for increasing the pressure loss being arranged in the additional steam line.

The invention thus consists in deliberately increasing the pressure loss in the additional steam line in order to dampen the disturbances that may possibly arise from the steam valve.

With this concept, a flow disturbance and the associated rotor oscillation is thus significantly reduced.

Advantageous developments are specified in the subclaims.

In a first advantageous development, the means is designed as a valve.

The valve is set to a position at which the pressure loss is optimal for the application. A further adjustment of the position is usually not required.

In a further advantageous embodiment, the agent is formed as a diaphragm. This is a particularly favorable embodiment. In this case, a single-hole orifice or a multi-hole orifice is arranged in the additional steam line. The pressure loss of the additional throttle body should be at least 5% of the pressure reduction of the additional steam valve during operation. Accordingly, the aperture is designed. In a particularly advantageous embodiment, the additional steam line is divided after the additional steam valve into a first additional steam line and into a second auxiliary steam line, wherein the first additional steam line opens into a first Zusatzzeinströmbereich in the flow channel and the second additional steam line opens into another second Zusatzzeinströmbereich in the flow channel, wherein in the first auxiliary steam line, a first means for reducing pressure and in the second additional steam line, a second means for reducing pressure is arranged.

Here, the fact is considered that the additional steam mass flow is divided into two pipes. These pipes each open into an additional inflow region into the flow channel. For example, the first auxiliary inflow region may be located at a 3 o'clock position and the second inflow region may be at a 9 o'clock position, for example. The steam flowing in through the first auxiliary steam line and the second auxiliary steam line can lead to rotor vibrations that are minimized by both in each case a means is arranged in the first auxiliary steam line and in the second auxiliary steam line, which is designed to reduce the pressure. Thus, it is proposed to arrange in the first auxiliary steam line a first means that is either a valve, a diaphragm or a single-hole orifice or a multi-hole orifice. Furthermore, it is proposed to form the second means, which is arranged in the second auxiliary steam line, as a valve, as a diaphragm, as a single-hole diaphragm or as a multi-hole diaphragm. The pressure loss in each pipeline can be adjusted symmetrically or asymmetrically. This means that the pressure loss through the first means in the first auxiliary steam line is different than the pressure loss of the second means in the second auxiliary steam line in the asymmetric setting. In the symmetrical setting, the pressure loss through the first means and through the second means is identical. In this configuration, the static forces acting on the rotor are minimal. The stronger the flow is damped, the lower the risk of rotor vibrations.

In an advantageous development, the steam turbine is designed as a high-pressure turbine part. Other sub-turbine types such as combined high-medium pressure, medium-pressure, combined medium-low pressure or low-pressure turbines are not excluded.

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 connection with the drawing.

Embodiments of the invention will be described below with reference to the drawings. These are not intended to represent the embodiments significantly, but the drawing, where appropriate for explanation, executed in a schematized and / or slightly distorted form. With regard Additions to the teachings directly recognizable in the drawing, reference is made to the relevant prior art.

Figur

eine schematische Darstellung der erfindungsgemäßen Anordnung

It shows

figure

a schematic representation of the arrangement according to the invention

The figure shows an arrangement 1, comprising a steam turbine 2. The steam turbine 2 has an unspecified outer housing, an inner housing and a rotor. After the additional steam valve, the steam flows to a flow divider 5. There, the steam is divided and flows to a first auxiliary steam line 6 and a second auxiliary steam line 7. The first auxiliary steam line 6 opens here in a first additional inflow region 8, which opens into the flow channel, not shown.

The second additional steam line 7 opens into another second additional inflow region 9, which opens into the flow channel, not shown.

In the first auxiliary steam line 6, a first means 10 for reducing pressure is arranged. In the second additional steam line, a second means 11 is arranged. The first means may be a valve, an orifice, a single orifice, or a multi-hole orifice.

The second means 11 may be a valve, an orifice, a single-hole orifice or a multi-hole orifice.

The pressure reduction by the first means in the first auxiliary steam line 6 may have a different value than the value of the pressure reduction, which is achieved by the second means in the second auxiliary steam line 7 (asymmetric arrangement of the pressure losses).

In an alternative embodiment, the value of the pressure reduction achieved by the first means and the second means may be the same (symmetrical arrangement of pressure drops).

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 (8)

Arrangement (1) comprising
a steam turbine (2),
a steam supply line, which is fluidically connected to an inflow region of the steam turbine, wherein the inflow region is fluidically connected to a flow channel and
a steam valve located in the steam supply line,
further comprising
an additional steam line (3), which is fluidically connected to an additional inflow region (8, 9) of the steam turbine (2),
an additional steam valve (4), which is arranged in the additional steam line (3),
wherein the additional inflow region (8, 9) is arranged downstream of the flow channel,
characterized in that
in the additional steam line (6, 7) a means (10, 11) is arranged to increase the pressure loss. Arrangement according to claim 1,
wherein the means (10, 11) is a valve. Arrangement according to claim 1,
wherein the means (10, 11) is a diaphragm. Arrangement according to claim 1 or 3,
wherein the means (10, 11) is a single hole or a multi-pinhole. Arrangement according to one of the preceding claims,
wherein the additional steam line (3) divides after the additional steam valve (4) into a first additional steam line (6) and into a second auxiliary steam line (7),
wherein the first auxiliary steam line (6) opens into a first additional inflow region (8) in the flow channel and
the second additional steam line (7) opens into another second additional inflow area (9) into the flow channel,
in which
in the first additional steam line (6) a first means (10) for reducing pressure and in the second additional steam line (7) a second means for reducing pressure are arranged. Arrangement according to claim 5,
wherein the value of the pressure loss achieved by the first means (10) is different from that of the pressure loss achieved by the second means (11). Arrangement according to one of the preceding claims,
wherein the means (10, 11) is designed such that the pressure loss directly after the additional valve (4) or before the additional inflow region (8, 9) is at least 5% of the pressure reduction of the steam valve (4) during operation. Arrangement according to one of the preceding claims,
wherein the steam turbine (2) is designed as a high-pressure turbine section, wherein other types of sub-turbine such as combined high-medium-pressure, medium-pressure, combined medium-low pressure or low-pressure turbines are not excluded.

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