DE663207C - Turbine, especially for ship systems, with bridging of steps - Google Patents

Description

Turbine, especially for ship systems, with bridging of steps Turbine systems, especially for ships, which operate with highly superheated high-pressure steam are operated, require in order to control the thermal expansion and for reasons of strength a distribution of the gradient over several, usually three, enclosures. Even if the Training several small individual turbines offers considerable advantages, it is a complication, especially with regard to the arrangement of the pipelines and the thus greater space requirements are available. These conditions are particularly uncomfortable, when it comes to special systems, which usually only use a fraction of the main machine output be operated, it is necessary to arrange a further single turbine in order to also with lower performance of the overall situation to achieve sufficient profitability. It must then z. B. four individual turbines with the associated pipelines housed , whereby the space requirement is increased even further. It occurs with this arrangement also has two other disadvantages. The high-pressure turbine is maintained at full machine power the steam bypassing the marching turbine directly from the boiler with, for example 6o atm. and 4S0 ° C. When marching, the steam from the boiler is initially the March turbine fed, in which it expands considerably and thereby its temperature humiliated. When entering the central relaxation area For example, it becomes a high-pressure turbine at a pressure of 8 atm. only one more Have a temperature of 250 ° C. The housing, especially the high pressure turbine, is that is, different thermal stresses and strains in the two operating states have, which can be a nuisance in the small gaps in the turbines.

Furthermore, it is with the arrangement of a special single turbine necessary for operation with lower power, when switching to full power the switch off upstream single turbine, not only in the steam path, but also in the mechanical connection with the overall situation. Otherwise, either would the upstream single turbine is running at too high a speed at full power, or, in order to avoid this, it would have to be unnecessarily large and difficult with many steps be built. The above-mentioned shutdown of the upstream single turbine of the mechanical connection with the overall system is now again quite difficult, likewise switching on when the performance of the machine system is reduced from full on low performance. The entire system will come to a standstill, albeit a brief one be necessary for the purpose of disengaging or engaging the upstream single turbine. This Standstill is not permitted, as this greatly reduces the value of the entire system would. In order to avoid this, facilities have already been provided for the To make switching on and off during operation possible. However, these are Facilities are complex, expensive, and sometimes require a great deal of space and weight. By the turbine design according to the invention is intended to overcome the disadvantages outlined will, in a simpler, more reliable and weight-saving manner Way. The invention consists in that the guiding devices behind the first, in all the instinctual states acted upon, the stages lie in one special component arige 'are arranged, which at the same time has a bypass channel absorbs the steam when bridging the middle stages.

The subject matter of the invention is to be explained in more detail with reference to the drawing will. The turbine housing of the first expansion area is shown which in the manner described below, the steam into the second and then the third housing of a z. B. via a gear on the propeller shaft of a ship working turbine systems arrives.

The turbine consists of the housing 1, the component 2 carrying the guide disks 3, 3 ', 3 ″ 3 ... and the bypass duct, the nozzle box, the shaft 6 and the stages of the turbine 7, 8, 8 `, 8", 8 " , 8"", 9, 9 'and the switchover valve 1o. The component 2 is only supported by the annular shoulder 11 in an annular groove 12 of the housing 1.

In known turbines in which a group of stages is bridged is possible, a special bypass channel is provided on the outside of the turbine housing. It is also known in such turbines, the intermediate floors of the bridged Stage not to lead in the outer casing wall, but in a special one Component which, however, is rigidly connected to the housing wall .. In contrast, can the component 2, the independent link of the machine, is completely free of all thermal expansions follow. It can neither through the otherwise external steam bypass duct nor due to the different temperatures of the turbine in different operating states Stresses occur between this component and the housing. Likewise are unilateral Thermal expansion in the turbine housing, which in the known design is caused by one-sided Arrangement of the bypass channel on the outside of the housing, avoided.

Furthermore, turbine types are known in which the guide disks are housed in a special inner housing part. Apart from the lack of it The arrangement of a bypass channel in these systems is this inner housing part fixed in two places in the outer casing. Caused by thermal expansion Stresses are supposed to be absorbed by a disk that is flexible in the axial direction will.

Certainly everyone will be able to avoid the occurrence of Stresses and safety of the type of delivery by the requirements of the invention appropriate storage taken into account; being in addition to the storage in an annular groove a further longitudinally movable bearing 13 can be provided .v rden: it is then expediently close to the entry end, d. h: near the first covered steps 8, 8 'and thus at the point of greatest heating of the part: 2 arranged while the bearing in the annular groove 12 near the last stages of the turbine, d. H. near the coldest part of the turbine is attached.

The longitudinally displaceable bearing 13, which is expedient in the parting line takes place, z. B. be secured against rotation by a spring.

Switching from a lower to a high speed level or vice versa, by setting a valve or slide in the wall of the Bypass channel q. of the inner component. It is well known; in the outside on the outside Housing of a turbine of the type already mentioned lying bypass channel in the valve to arrange. This type of construction is in no way compatible with the arrangement proposed here of the valve in the now inside, in the inner housing without connection with the outer Compare housing lying bypass channel. The installation of the valve will be like this made that the change in length of the component caused by thermal expansion 2 has no effect on the position of the valve. Again, this arrangement offers the possibility of a particularly simple structure of the entire turbine including its control devices undertake and switch this so that the transition from one speed level to the other is made possible by setting only the main reversing valve.

This simple switching option is particularly important with regard to this to the statements made at the beginning about the operational requirements.

The valve ro, which is caused by the changes in length caused by thermal expansion of the component 2 should not be changed in its position, for example from your valve body 16, which contains the valve seat 17, and the valve disk 18. The sealing pressure is provided by the insert sleeve itself, which is provided with windows recorded and thus kept away from component e. The valve body 16 is at rg fixed in the housing 1, while the seal in the component 2 with the necessary play done by piston rings 2o.

The mode of operation of the turbine is as follows: At low power, ie also at a low speed of the turbine system, the live steam coming from the boiler is fed to the nozzle box 5 and initially acts on the first stage 7 of the turbine. The valve io is, as shown, closed, so the steam must take its way through stages B. 8 ', 8 ", 8"' and 8 "", in order to then continue through stages 9, 9 'into the evaporation arc 14 and from this on the other not shown z. B. to get two single turbines into the condenser. In-full power of the steam occurs again by the nozzle box 5 in the turbine and applied as 7, the first stage at part load, the valve io is however now opened as shown dotted, and gives the way through the opening 1 5 in the bypass duct q. and from there, bypassing levels 8 to 8 "", to levels 9, 9 '. While in the first case of operation, each step can only handle a slight gradient due to the low circumferential speed, the number of steps must be reduced at full speed (second operational case) in order to obtain a favorable gradient distribution for each case at a much higher circumferential speed, which is shown in is possible particularly well when applying the present invention.

The described design, peculiar to the invention, achieves that a simple and easy to manufacture component that can be easily and safely inserted into the Turbine housing can be installed, in place of an otherwise necessary cumbersome Cast execution occurs. By storing it in only one place, which is about the coldest Part of the turbine takes place, and the optionally to be arranged longitudinally displaceable Leadership at the. The place of the greatest heating of the inserted part is a complete one Security against the occurrence of stresses created by thermal expansion. as well the thermal expansions of both the housing and the suspended component 2 are at be approximately the same in both operating states, since the inlet temperature of the steam before the first stage and the temperature at the entrance to the march stages or in Bypass channel are practically the same. Due to the special type of installation of the Valve io this is kept free from tension.

The structure of the entire turbine set is clear and concise and the number of pipelines is largely limited.

From the figure it can be seen that switching from one circuit on the other at any time without the turbine having to come to a standstill while driving can be done by simply setting the valve io, which is expedient in the immediate Dependent on the setting of the main reversing valve. Takes place.

Due to the special way in which the valve io is installed, this is ensured by Tensions kept free.

Claims (6)

PATENT CLAIMS: i. Turbine, especially for ship systems, in the a number after the first and before the last step or steps horizontal steps can be bridged, characterized in that for the purpose of creation favorable thermal expansion ratios the guiding devices behind the first, in all operating states acted upon level in a special level Component (2) are arranged, which also has a bypass channel (q.) For the Absorbs steam when bridging the middle stages. 2. turbine according to claim i, characterized in that the component (2) is only in an annular groove in the outer housing is stored. 3. Turbine according to claim i and 2, characterized in that the Component (2) apart from the bearing in an annular groove at one end in the axial direction near its other end longitudinally movable z. B. is stored in the parting line. q .. Turbine according to claims i to 3, characterized in that the switchover from from a low to a high speed level or vice versa by setting a Valve or slide in the Umführ ungskanal (q.) Takes place, so that without a standstill the machine from the circuit for low power to the circuit for high power or the other way round can be passed over. 5. Turbine according to claim i to .4, characterized in that that the setting of the switching valve (io) in the immediate, z. B. more mechanical Dependent on the setting of the main reversing valve takes place. 6. Turbine after Claims i to 5, characterized in that the installation of the switching valve (io) takes place in such a way that the changes in length of the particular due to thermal expansion Component (2) do not change the position of the valve.