EP1911933A1 - Rotor for a turbomachine - Google Patents

Abstract

The turbine (1) has a housing (39) provided with a feedthrough (20) for feeding an external cooling agent (21), and a rotor (5) that is partly formed in a hollow shape. The rotor includes a supply line (23) for feeding the external cooling agent into a hollow space (22) of the rotor via rotor cooling lines (24). The supply line is arranged adjacent to a balance piston (4). The rotor includes rotor blades allowing the flow of the cooling agent. The rotor blades are cooled by film cooling.

Description

The invention relates to a steam turbine comprising a housing and a rotor, wherein the housing has a passage for the passage of external cooling medium, wherein the rotor is at least partially hollow.

To increase the efficiency of a steam turbine, the use of steam at higher pressures and temperatures helps. The use of steam with such a steam condition places increased demands on the corresponding steam turbine.

For the purposes of the present application, a steam turbine is understood to mean any turbine or sub-turbine through which a working medium in the form of steam flows. In contrast, gas turbines are traversed with gas and / or air as a working medium, but that is subject to completely different temperature and pressure conditions than the steam in a steam turbine. In contrast to gas turbines, in steam turbines, for example, the working medium having the highest temperature and flowing to a partial turbine at the same time has the highest pressure. An open cooling system, as in gas turbines, is therefore not feasible without external supply. A steam turbine typically includes a vaned rotatably mounted rotor disposed within a casing shell. When flowing through the flow space formed by the housing jacket with heated and pressurized steam, the rotor is set in rotation by the steam via the blades. The rotor-mounted blades are also referred to as blades. In addition, usually stationary guide vanes are mounted on the housing jacket, which engage in the intermediate spaces of the moving blades. A vane is typically held at a first location along an interior of the steam turbine casing. It is usually part of a vane ring, which comprises a number of vanes arranged along an inner periphery on the inside of the steam turbine casing. Each vane has its blade radially inward. A vane ring at a location along the axial extent is also referred to as a vane row. Usually, a plurality of vane rows are arranged one behind the other.

An essential role in increasing the efficiency plays the cooling. In the previously known coolant methods for cooling a steam turbine housing is to distinguish between an active cooling and a passive cooling. With active cooling, cooling by one of the steam turbine is separated, i. effected in addition to the working medium supplied cooling medium. In contrast, a passive cooling is done only by a suitable leadership or use of the working medium. A known cooling of a steam turbine housing is limited to a passive cooling. For example, it is known to flow around an inner casing of a steam turbine with cool, already expanded steam. However, this has the disadvantage that a temperature difference over the Innengehäusewandung must remain limited, otherwise the inner housing would thermally deform too much at too large a temperature difference. Although a heat dissipation takes place in a flow around the inner housing, the heat removal takes place relatively far away from the point of heat supply. Heat removal in the immediate vicinity of the heat supply has not been realized sufficiently. Another passive cooling can be achieved by means of a suitable design of the expansion of the working medium in a so-called diagonal stage. However, this can only achieve a very limited cooling effect on the housing.

The rotatably mounted in the steam turbine steam turbine rotors are subjected to thermal stress during operation. The development and production of a steam turbine rotor is both expensive and time consuming. The steam turbine rotors are considered the most stressed and expensive components of a steam turbine. This increasingly applies to high steam turbines.

A feature of the steam turbine rotor is that they have no significant heat sink. Therefore, the cooling of the blades arranged on the steam turbine rotor is difficult.

The piston and inflow areas are particularly thermally stressed in the steam turbine rotors. Piston area is to be understood as the area of a thrust balance piston. The thrust balance piston acts in a steam turbine such that a force caused by the working medium force is formed on the rotor in one direction counter-force in the opposite direction.

A cooling of a steam turbine rotor is in the EP 0 991 850 B1 described. In this case, a compact or high-pressure and medium-pressure turbine part through a compound in the rotor, through which a cooling medium can flow, executed. A disadvantage here is felt that between two different expansion sections no controllable bypass can be formed. In addition, problems in transient operation are possible.

It would be desirable to form a steam turbine that is suitable for high temperatures.

The object of the invention is therefore to provide a steam turbine, which can be operated at high steam temperatures.

This object is achieved by a steam turbine, comprising a housing and a rotor, wherein the housing has a passage for the passage of external cooling medium, wherein the rotor is at least partially hollow, wherein a Supply line for carrying out the external cooling medium is provided in the cavity of the rotor.

With the invention is therefore proposed to supply external cooling medium in the rotor of the steam turbine, wherein the cooling medium is guided to a suitable point of the rotor. Here, the cavity is used as a suitable location. The cavity is expediently attached to the places which are exposed to a high thermal load.

The hitherto known method, in which the external cooling medium is flowed into the steam turbine and directly cools thermally stressed parts such as the thrust balance piston, is therefore improved by the cooling medium is passed after passing through the housing into the cavity of the rotor. For this purpose, the cooling steam must have a higher pressure than at the inflow, so that it can be guided into the cavity.

An advantage of this cooling principle according to the invention is that the temperature of the cooling medium is adjustable. Steam turbines are usually used at different loads. For example, a steam turbine is operated at full load or in partial load operation. The cooling requirements for the different load operations are different, so the demand for the cooling of the steam turbine in part load operation is lower than in full load operation.

In full load operation, therefore, more cooling medium or a lower temperature of the cooling medium is required, which according to the invention is readily possible, since the temperature of the cooling medium can be easily controlled.

Advantageous developments are shown in the subclaims.

Thus, the invention is advantageously developed if the rotor is designed such that the cooling medium via rotor cooling pipes can be flowed out of the cavity. The cooling medium first flows through external lines through the housing into the cavity of the rotor and then flows at suitable locations from the rotor back into the main flow. The cooling medium flows and cools the rotor from the inside. The outflow of the cooling medium from the rotor takes place at one or more points downstream.

By this measure, the cooling medium fulfills two tasks, so to speak, on the one hand, the cooling medium cools the rotor at suitable locations and on the other, the cooling medium contributes to the efficiency in which it is fed back into the main flow and performs work on the guide vanes and blades.

In an advantageous development, the supply line is arranged in the region of a steam inflow region. As a result, a suitable location for the supply line is found, since just the area of the steam inflow area is exposed to very high thermal loads and therefore requires a preferred cooling.

In a further advantageous development, the supply line is arranged next to a thrust balance piston. This makes it possible for the cooling medium, before it is guided into the cavity of the rotor, to cool the thrust balance piston. The thrust balance piston is subject to high thermal loads, especially at full load.

In an advantageous development, the rotor has rotor blades which are designed such that the cooling medium can be flowed through the rotor blades. This provides the advantage that in addition to the rotor and the blades can be cooled. In this case, the film cooling of the rotor blades known from gas turbine technology is preferably used. In this way, blade roots or other thermally stressed areas of the rotor can be effectively cooled.

In an advantageous development of the rotor is made of disc rotors and braced with a tie rod.

It is equally advantageous if the pancake is formed with a toothing for transmitting a torque. As a result, the rotor can be formed of different materials. It is conceivable, for example, that a pancake, which is exposed to lower thermal loads than a pancake, which is exposed to high thermal stress, is performed with a material that is less expensive and yet withstands the thermal stresses.

In a further advantageous development, the toothing is designed such that the cooling medium can be flowed between two adjacent disc rotors. For this purpose, the toothing is formed such that the toothing has passage openings. For example, channels can be provided in the so-called Hirth toothing. Through these channels, the cooling medium is flowable. This embodiment has the advantage that no additional bores have to be carried out for the passage of the cooling medium via radial channels, additional bores in the rotor cause a high concentration of stress by additional notches. Such stress concentrations omitted when the cooling medium is passed through the teeth.

Embodiments of the invention will be explained in more detail with reference to the following drawings. In this case, components with the same reference numerals have the same functionality.

FIG 1

ein Querschnitt einer Dampfturbine gemäß dem Stand der Technik,

FIG 2

ein Querschnitt eines Rotors einer Dampfturbine und eines Teils eines Gehäuses,

FIG 3

Querschnitt durch einen Rotor,

FIG 4

Querschnitt durch eine Verzahnung,

FIG 5

Querschnitt einer Verzahnung in alternativer Ausführungsform.

Show it:

FIG. 1

a cross section of a steam turbine according to the prior art,

FIG. 2

a cross section of a rotor of a steam turbine and a part of a housing,

FIG. 3

Cross section through a rotor,

FIG. 4

Cross section through a toothing,

FIG. 5

Cross-section of a toothing in an alternative embodiment.

1 shows a section through a high-pressure turbine part 1 according to the prior art. The high-pressure turbine part 1 as an embodiment of a steam turbine comprises an outer housing 2 and an inner housing 3 arranged therein. Within the inner housing 3, a rotor 5 is rotatably mounted about a rotation axis 6. The rotor 5 comprises blades 7 arranged in grooves on a surface of the rotor 5. The inner housing 3 has guide vanes 8 arranged in grooves on its inner surface. The guide 8 and blades 7 are arranged such that in a flow direction 13, a flow channel 9 is formed. The high-pressure turbine section 1 has an inflow region 10, through which live steam flows into the high-pressure turbine section 1 during operation. The live steam may have steam parameters above 300 bar and above 620 ° C. The relaxing in the flow direction 13 live steam flows alternately past the guide 8 and blades 7, relaxes and cools down. The steam loses in this case to internal energy, which is converted into rotational energy of the rotor 5. The rotation of the rotor 5 finally drives a generator, not shown, for power supply. Of course, the high pressure turbine part 1 may drive other equipment other than a generator, such as a compressor, a marine propeller, or the like. The steam flows through the flow channel 9 and flows out of the high-pressure turbine section 1 from the outlet 33. The steam exerts an action force 11 in the flow direction 13. The result is that the rotor 5 would perform a movement in the flow direction 13. An actual movement of the rotor 5 is through prevents a balance piston 4. This is done by 12 steam is flowed in a Ausgleichskolbenvorraum with a corresponding pressure, which causes the result of the building up pressure in Ausgleichskolbenvorraum 12, a force against the flow direction 13, which ideally should be just as large as the action force eleventh The steam which has flowed into the compensating piston antechamber 12 is generally diverted live steam, which has very high temperature parameters. As a result, the inflow region 10 and the compensating piston 4 of the rotor 5 are subjected to high thermal stress.

In FIG 2, a section of a steam turbine 1 is shown. The steam turbine has a housing 39. For the sake of clarity, only part of the housing 39 is shown in FIG. The housing 39 could be an inner housing 3 or an outer housing 2.

According to the invention, the steam turbine according to FIG. 2 is designed in such a way that the housing 39 has a passage 20 for the passage of external cooling medium 21. The rotor 5 is in this case at least partially hollow. The rotor 5 therefore has a cavity 22. The rotor 5 has a feed line 23 for carrying out the external cooling medium 21. The cooling medium 21 is guided via the passage 20 and the feed line 23 into the cavity 22. A first cooling effect of the cooling medium 21 is already achieved in the housing 39 in the region of the passage 20. Expediently, the passage 20 is arranged in the vicinity of the inflow region 10. The inflow region 10 is particularly thermally stressed, since there flows in the live steam. The cooling medium is guided from the passage 20 to the supply line 23 and flows into the cavity 22. The cooling medium 21 must in this case have a corresponding pressure.

The supply line 23 can be made by radial bores. Other embodiments, such as inclined leads are conceivable.

For the sake of clarity, neither guide 8 nor moving blades 7 are shown in FIG. The rotor 5 is designed such that the cooling medium 21 can be flowed out of the cavity 22 via rotor cooling lines 24.

The supply line 23 can be arranged next to a compensating piston 4. Since the balance piston is particularly thermally stressed, this would be an advantageous embodiment.

The cooling medium 21 flowing out of the rotor cooling duct 24 mixes with the working medium coming from the inflow region 10, which as a rule is a vapor. The cooling medium 21 cools, inter alia, from the supply line 23, the rotor 5 on an inner surface 25 of the cavity 22nd

The steam turbine 1 may be designed such that the rotor 5 has blades 7, which are designed such that the cooling medium 21 can be flowed through the blade 7. As a result, the blade 7 is cooled. The blades 7 in this case have individual openings. The blades 7 are cooled by the so-called film cooling. Film cooling is known from gas turbine technology.

Preferably, the rotor 5 is designed such that the blade feet, the balance piston 4 or other critical areas that are thermally stressed, are coolable.

The rotor 5 shown in FIG 2 is welded to a weld 26 of two partial rotors 27, 28. This offers the advantage that the first part rotor 27, which is particularly stressed thermally, can be made of a different thermally loadable material than the part rotor 28. Of course, the rotor 5 can be made of a uniform material, ie without a weld 26.

In FIG 3, a rotor is shown, which is composed of three disc rotors 29, 30, 31. In alternative embodiments, the rotor 5 may be made of only two disc rotors. The three pancake rollers 29, 30, 31 are firmly clamped together by means of a tie rod 32. For this purpose, the tie rod at its ends a thread 34. By turning the tie rod 32, a movement of the tie rod 32 in the rotation axis direction, which results in that the three pancake 29, 30, 31 are compressed. Conveniently, the pancake 29, 30, 31 at their points of contact 35, 36 has a toothing for transmitting a torque. The toothing can be designed as a Hirth, rectangular or trapezoidal toothing.

4 shows a first embodiment of a toothing 37, 38 is shown. The toothing 37, 38 is designed as a triangular toothing 37. The toothing 37 is designed such that a supply line 23 is formed. Through the supply line 23, the cooling medium 21 is flowable.

5 shows an alternative embodiment of a toothing 37, 38 is shown. The toothing 38 shown in FIG. 5 is designed as a trapezoid toothing 38. In this case, the trapezoidal toothing 38 is designed such that feed lines 23 are formed, through which the cooling medium 21 can be flowed.

Claims (15)

Steam turbine
comprising a housing (2, 3, 39) and a rotor (5),
the housing (2, 3, 39) having a passage (20) for passing through external cooling medium (21),
wherein the rotor (5) is at least partially hollow,
characterized in that
the rotor (5) has a feed line (23) for passing the external cooling medium (21) into the cavity (22) of the rotor (5). Steam turbine according to claim 1,
wherein the rotor (5) is designed such
the cooling medium (21) can be flowed out of the cavity (22) via rotor cooling lines (24). Steam turbine according to claim 1 or 2,
in which the supply line (23) in the region of an inflow region (10) is arranged. Steam turbine according to claim 1, 2 or 3,
in which the supply line (23) is arranged next to a compensating piston (4). Steam turbine according to one of the preceding claims, in which the cooling medium (21) flowing out of the rotor (5) during operation can be mixed with a flow medium. Steam turbine according to one of the preceding claims, in which the rotor (5) has moving blades (7),
that are designed
the cooling medium (21) can be flowed through the moving blades (7). Steam turbine according to claim 6,
in which the blades (7) are coolable by means of film cooling. Steam turbine according to one of the preceding claims,
wherein the rotor (5) is designed such
that blade feet, the thrust balance piston (4) or other thermally stressed areas of the rotor (5) are coolable. Steam turbine according to one of the preceding claims,
wherein the rotor (5) has outlet openings for the radial exit of the cooling steam (21). Steam turbine according to one of the preceding claims,
wherein the rotor (5) is designed as a welded hollow shaft. Steam turbine according to one of claims 1 to 9,
in which the rotor (5) is designed as a disc rotor (29, 30, 31) clamped with a tie rod (32). Steam turbine according to claim 11,
in which the disc drivers (29, 30, 31) are formed with toothings (37, 38) for transmitting a torque. Steam turbine according to claim 12,
wherein the toothing (37, 38) is designed as Hirth, rectangular or trapezoidal toothing. Steam turbine according to claim 11 or 12,
wherein the toothing (37, 38) is formed such that the cooling medium (21) is flowable between two adjacent disc rotors. Steam turbine according to claim 14,
wherein the toothing (37, 38) has passage openings.

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