RU112275U1 - STEAM TURBINE ASSEMBLY - Google Patents

Abstract

A steam turbine assembly comprising - a low pressure module (1), as well as a condenser (3) with a casing (3A), which is configured to receive steam coming from the low pressure module (1), while the low pressure module (1) contains a) an external casing (2), referred to as an exhaust hood, which together with a casing (3A) of the condenser (3) forms a cavity with reduced pressure, and b) an internal structure (10) designed to install at least one set of fixed blades and rotor equipped with at least one set of movable x blades, characterized in that - the internal structure (10) is supported by the foundation block (4), and the exhaust hood (2) is not supported by the said foundation block (4).

Description

The present utility model relates to steam turbine assemblies.

A steam turbine is a rotating device designed to convert the thermal energy of steam into mechanical energy, driving an electric generator (an alternating current generator or a turbogenerator), a pump, or another rotating mechanical drive device. By “mechanical drive device” is meant a device that consumes power and does the job.

The turbine as a whole includes at least three modules: a high pressure module, possibly a medium pressure module, as well as at least one low pressure module. The steam supplied by the steam generator is first directed to the high pressure module, and then to the medium pressure module and the low pressure module. Steam leaving the low pressure module is sent to a condenser, which is located below the low pressure modules.

The remainder of the utility model description is devoted to the low pressure module assembly.

A device of a similar type from the prior art is shown in figures 1 and 2.

The low pressure module 1 comprises an outer casing 2, referred to as an exhaust hood. The vapor pressure at the outlet of the low pressure module 1 in the working arrangement is of the order of several tens of Mbar, and the exhaust hood 2 forms a vacuum vessel with the casing 3A of the condenser 3. The low pressure module 1 also contains, inside the exhaust hood 2, an internal structure with two symmetric or asymmetric flows that are not shown, as well as a rotor 19 equipped with movable blades and auxiliary stationary blades of the low pressure module 1. The internal structure rests on the exhaust hood 2 using the support points located therein. The rotor 19 is supported by bearings, which are either directly mounted in the foundation block 4 or integrated in the low pressure module 1.

The exhaust hood 2 is supported on the foundation block 4 by means of supports 21. The foundation block 4 is connected to the base plate 5 by means of columns 6, the base plate 5 is mounted on the floor 7. The assembly consisting of the foundation block 4, columns 6 and the base plate 5 forms a concrete structure referred to as the support structure S of the turbogenerator. A similar design S carries the entire turbogenerator installation, consisting of all modules of the turbine and the generator.

The capacitor 3 is located under the foundation block 4 and rests on the base plate 5. The capacitor 3 has an inlet 3B for water, as well as an outlet 3C for water.

There are two possible layouts of capacitor 3.

In the first arrangement shown in FIG. 1, the capacitor 3 rests directly on the base plate 5. The coupling between the exhaust hood 2 and the condenser 3, thus, is made in the form of a flexible seal 8.

In the second embodiment shown in FIG. 2, where elements similar to those in FIG. 1 are denoted by the same reference numerals, the capacitor 3 is supported by the springs 11. The coupling between the exhaust hood 2 and the condenser 3 is rigid.

In such two devices of the prior art, the weight of the entire low pressure module 1 is perceived by the support structure S of the turbogenerator unit. In addition, in the first arrangement, the support structure S accepts the loads resulting from the pressure difference between the outer and inner walls of the exhaust hood 2, and in the second arrangement, the support structure S accepts part of the loads created by the weight of the water in the condenser 3. Support structure S, therefore, must be designed to withstand the effects of such forces.

As a result, the construction S is particularly bulky, and the columns on which the foundation block rests must have a large cross section.

In addition, in such two devices of the prior art, the movements of the exhaust hood are transmitted to the internal structure. Such movements may, for example, result from a vacuum in the condenser, a change in the mass of water in the condenser, or a change in temperature.

Therefore, relative motion occurs between the stationary parts and the moving parts of the low pressure module. The gaps between the stationary parts and the moving parts, and therefore the efficiency of the turbine cannot be optimized.

Finally, in such two devices of the prior art, the alignment of the shaft line is effected by directly affecting the vertical position of the bearing on which the rotor rests. This effect allows you to adjust the relative position of each. rotor bearings relative to other bearings. A similar procedure allows you to adjust the relative position of each of the rotor bearings relative to other bearings. A similar procedure is carried out during the assembly of the turbogenerator unit, as well as during routine maintenance, if such a relative position is violated.

As a result of this, the position of the rotor relative to the stationary components changes, since the position of the stationary components during this procedure remains unchanged. In particular, the radial clearances in the steam flow between the moving components and the fixed components change. Such radial clearances, therefore, must be reinstalled after any leveling operation.

The purpose of this utility model is to solve these problems.

A utility model, therefore, is a steam turbine assembly comprising:

- low pressure module, as well

- a capacitor equipped with a casing and configured to receive steam coming from the low pressure module,

the low-pressure module contains a) an external casing, referred to as an exhaust hood, forming a cavity with a reduced pressure together with a condenser casing, and b) an internal structure capable of accommodating at least one set of fixed vanes and a rotor equipped with at least one set of movable blades.

In the device according to the utility model, the internal structure is supported by the foundation block, and the exhaust hood is not supported by the said foundation block.

As a result of this, while maintaining the seal between the exhaust hood and the condenser housing, the foundation block and columns no longer need to withstand the high loads created by the weight of the exhaust hood and the reduced pressure in the exhaust hood or the mass of water in the condenser.

Reducing the load on the foundation block and columns simplifies the support structure of the turbogenerator in terms of size and makes it less voluminous.

In addition, since the inner casing does not rest on the exhaust hood, movements of the exhaust hood are not transmitted to the inner housing. Relative movements between fixed parts and moving parts are reduced. The gaps between the fixed parts and the moving parts, and, consequently, the efficiency can be optimized.

Finally, in the device according to the utility model, the internal structure is supported by the foundation block, and the bearings are built into the internal structure. The line of shafts can be aligned due to direct impact, at the level of the supports of the internal structure, on the foundation block. Accordingly, since the bearings are embedded in the internal structure, the relative position of the movable components and the stationary components remains unchanged.

As a result, the line of the shafts can be aligned without changing the radial clearances between the moving components and the stationary components in the steam stream.

The exhaust hood can be supported by a condenser. In particular, it can be rigidly fixed in the capacitor.

The inner structure can be supported on the foundation block by means of at least one abutment surface of the inner structure extending beyond the hood.

The device may have at least one adjustable support system located between the support surface and the base unit.

The low pressure module has a front end and a rear end, the internal structure may include a supporting surface for the front end of the low pressure module, as well as a supporting surface for the rear end of the low pressure module.

At least one flexible seal may be installed between the internal structure and the exhaust hood.

The foundation block can be supported by columns using springs located below the foundation block and on top of each column.

The capacitor can directly rest on the base plate.

The low pressure module may further comprise at least one bearing integrated in the internal structure to support the rotor.

Other features and advantages of the present utility model will become more apparent from the following description, offered as an illustrative and non-limiting example, with reference to the accompanying drawings, where:

- figure 1 and 2 schematically shows two layouts from the prior art of the supporting structure supporting the turbine generator and condenser,

- figure 3 schematically shows the layout of the supporting structure supporting the turbogenerator installation, as well as the capacitor according to the utility model,

- figure 4 in perspective shows an exploded view of the exhaust hood and the internal structure of the device according to the utility model,

- figure 5 shows a view of the internal structure of the device according to the utility model, and

- figure 6 shows a view in longitudinal section of a device according to a utility model.

Figure 3, where the elements identical to the elements in figures 1 and 2 are denoted by the same reference positions, the device according to the utility model is shown.

In the device according to the utility model, the exhaust hood 2 of the low pressure module 1 is supported on the condenser 3, but not on the foundation block 4, which is connected to the base plate 5 by means of columns 6, as described with reference to figures 1 and 2. Condenser 3, except of this, can rely on the base plate 5 directly, without additional intermediate devices, such as springs.

The reduced pressure created in the exhaust hood 2, as well as the mass of water in the condenser 3, do not affect the foundation block 4 or the columns 6. Therefore, when calculating the supporting structure S formed from the foundation block 4, columns 6 and the base plate 5, it is necessary to take into account the effect of evacuation or the weight of water in the condenser 3.

According to a utility model, the exhaust hood 2 does not rest on the foundation block 4, while the inner structure 10 rests on the foundation block 4. The exhaust hood 2, respectively, is completely supported by the capacitor 3. The exhaust hood 2 can be rigidly fixed in the condenser 3, for example, welded to him. Due to the rigid attachment of the exhaust hood 2 with the condenser 3, the intrinsic movements of the capacitor 3 are transmitted to the exhaust hood 2, while the movements of the assembly formed from the capacitor 3 and the exhaust hood 2 are not transmitted to the internal structure 10.

The springs 20 can be located on top of the columns 6, below the foundation block 4. The springs 20 allow you to adjust the foundation block 4 during settlement of the supporting structure, for example, due to shear.

Figure 4 shows a General view of the module 1 low pressure device. The exhaust hood 2 comprises a front portion 2A and a rear portion 2B. The front part 2A comprises a lower part 2A1, as well as an upper part 2A2, bolted together in the seal plane P. Similarly, the lower part 2B includes a lower part 2B1 and an upper part 2B2, bolted together in the seal plane P.

The exhaust hood 2 is located around the inner structure 10, however, as such it does not support it. The inner structure 10 consists of a central part 10A, as well as two outlet ends 10B, 10C, namely, the front outlet end 10B and the rear outlet end 10C. The central part 10A of the inner structure 10 is designed to support at least one set of fixed blades, as well as to accommodate a rotor equipped with at least one set of movable blades. The steam enters the central part 10A of the inner structure 10 through at least one tube 12. Then the steam is separated into a front stream and a back stream. Similar two streams expand in the central part 10A of the inner structure 10, driving the rotor. Then the steam is directed towards the front outlet end 10B, as well as towards the rear outlet end 10C. Bearings 22 are integrated in the front outlet end 10B as well as in the rear outlet end 10C to support the rotor of the low pressure module 1.

As shown in FIG. 5, each outlet end 10B, 10C comprises a steam diffuser 13 fixedly mounted in the central part 10A of the internal structure 10, the steam diffuser 13 is welded to the rods 14. The cone 15 completes the steam direction. The ring plate 16 is welded to the cone 15, and traction 14. After assembly of the device, the flexible seal 18 is fixedly attached to the outlet ends 10B, 10C, more precisely to the annular plate 16 of each of the outlet ends 10B, 10C, as well as to the front of the exhaust hood 2 (Fig.6). The flexible seal 18 provides a seal between the outer part and the inner part of the exhaust hood 2. It also provides relative axial and vertical expansion between the inner structure 10 and the assembly formed by the exhaust hood 2 and the condenser 3.

Each of the exhaust ends 10B, 10C further comprises an area 17 of the support. In the working arrangement of the device 1, each bearing area 17 extends beyond the exhaust hood 2 and allows the internal structure to be supported by the outlet ends 10B, 10C on the foundation block 4 using the support systems 9. Such support systems 9 can be adjusted if necessary to change the position of the internal structure 10 relative to the foundation block 4, in order to align the shaft line in case of alignment errors. Such support systems may, for example, comprise actuators or consist of simple support surfaces.

Due to the fact that the rotor 19 of the low-pressure module 1 is supported by bearings on the front outlet end 10B and the rear outlet end 10C, the radial clearances between the stationary components and the moving components do not change when the shaft axis is aligned.

Claims (10)

1. A steam turbine assembly comprising - low pressure module (1), as well as - a condenser (3) with a casing (3A), which is configured to receive steam coming from the low pressure module (1), while low pressure module (1) contains a) the outer casing (2), called the exhaust hood, forming together with the casing (3A) of the condenser (3) a cavity with reduced pressure, and b) an internal structure (10) for mounting at least one set of fixed blades, and a rotor provided with at least one set of movable blades, characterized in that - the internal structure (10) rests on the foundation block (4), and the exhaust hood (2) does not rest on the said foundation block (4). 2. The node according to claim 1, characterized in that the exhaust hood (2) is supported by a capacitor (3). 3. The node according to claim 2, characterized in that the exhaust hood (2) is fixedly mounted in the capacitor (3). 4. An assembly according to any one of claims 1 to 3, characterized in that the internal structure (10) is supported on the foundation block (4) by means of at least one supporting surface (17) of the internal structure (10) protruding beyond the exhaust cap (2). 5. The node according to claim 4, characterized in that it contains at least one adjustable support system (9) located between the support surface (17) and the base unit (4). 6. An assembly according to any one of claims 1 to 3, characterized in that the low pressure module (1) has a front end and a rear end, the internal structure (10) contains a supporting surface (17) for the front end of the low pressure module (1) , as well as the supporting surface (17) for the rear end of the low pressure module (1). 7. An assembly according to any one of claims 1 to 3, characterized in that at least one flexible seal (18) is located between the internal structure (10) and the exhaust hood (2). 8. An assembly according to any one of claims 1 to 3, characterized in that the foundation block (4) is supported by columns (6) with springs (20) located below the foundation block (4) and on top of each column (6). 9. An assembly according to any one of claims 1 to 3, characterized in that the capacitor (3) directly rests on the base plate (5). 10. An assembly according to any one of claims 1 to 3, characterized in that the low-pressure module (1) further comprises at least one bearing (22) integrated in the internal structure (10) to support the rotor (19).