DE1152703B - Multi-stage impulse turbine - Google Patents

Description

Multi-stage impulse turbine The invention relates to a multi-stage Impulse turbine with a split not in the axial plane, but in planes normal to the axis Housing with intermediate shelves divided in the axis plane, which together with the Runners are assembled into a package, which is then pushed into the housing and is centered in it with radial play, and with clamping means that the Hold the intermediate halves together radially and the intermediate floors axially during assembly and press them together so that they are vapor-tight in operation.

In a known turbine of this type, both the axial Clamping the intermediate floors as well as the radial clamping of their halves by one and the same means, namely by a cylindrical or conical sleeve. This has the undesirable property that if one of the intermediate floors in the Operate relatively more than one or both of the adjacent floors stretches, on the excessively stretched floor with excessive compression and on the adjacent one or more Soils with too little pressure or not at all, so that they are there excessively is claimed and writes badly here.

Avoiding this is the main purpose of the invention. This is based on the thought, the axial and the radial compression not by one and the same Means, but to effect each one through its own means. It therefore provides that Halves of each intermediate floor by a ring and the intermediate floors by several To clamp together axially parallel tie rods distributed over the circumference.

Each of these two remedies is known on its own. The first of them, the ring that holds the halves of an intermediate floor together, is known of turbines, in which the axial compression of the intermediate floors in operation takes place via the housing itself; this pressure through the housing is because that The housing will take on a different temperature and will therefore expand differently than the intermediate floors, undesirable. The second means, the axially parallel tie rod, is from a turbine known whose intermediate floors are not divided in the axial plane, so no radial Require clamping devices; the anchors consist of screw bolts that form the intermediate floor package penetrate and at the same time connect to a housing front wall.

That the propellant itself is also compressed in the factory causes, namely the intermediate floors axially and, because usually between the Package and the housing located annulus of propellant higher pressure than that Wheel chambers is fulfilled, their halves pressed together radially, is only mentioned in passing; that has nothing to do with the invention.

So that the rings can be easily assembled and still in the company the intermediate bottom halves fit together well, it is recommended that each ring is in on known way from material with a smaller coefficient of thermal expansion than that of the material of the false floor and that its seat diameter is chosen so that the ring the intermediate floor halves during assembly, so in cold Condition, with a slight snug fit, but in operating temperature with great pressure includes. This is known from the turbine mentioned at the beginning with which the intermediate floors both radially and axially pressing sleeve; there is the material of the rifle lower coefficient of thermal expansion than the material of the intermediate floors.

Around the intermediate floors at the distance required for the rotor disks To keep one another and at the same time to center them on one another is something special Spacer rings arranged between them. These special rings become dispensable, if each ring on each of the two intermediate floors adjacent to it radially and axially is applied, i.e. the neighboring rings are centered and distanced at the same time.

The tie rods should already provide a certain amount of pressure during assembly. Bolts as in the turbine mentioned above are undesirable because the Thread can sometimes be difficult to loosen. According to the invention it is proposed to effect the compression by heat shrinkage. The invention provides that the Tie rods with hook-shaped ends rest on the end faces of the intermediate floor package and shrunk onto it.

To center the shelves in the housing and that on the shelves to transmit the acting torque to the housing, is used in the case of the conical bushing equipped known turbine the bushing, which the torque force friction from the Receives intermediate floors and releases them to the housing through radial bolts or claws. The known ones provided with tie rods are used to absorb the torque Turbine the tie rods that also penetrate the housing wall. At one of the well-known Turbines in which the axial pressure of the intermediate floors is caused by the housing itself happens, are used for centering and for torque absorption axially parallel parallel keys, which engage both in the individual shelves and in the housing. The last Means also uses the invention; it provides that the tie rods are axially parallel Grooves of the individual shelves and the housing are fitted.

The difficult to carry out production of the fitting grooves in the housing can thereby be circumvented and a possibility for precise adjustment achieved that the fitting grooves of both the intermediate floor package and the housing through each of these parts arranged in pairs, releasably attached and in their longitudinal direction integral or divided fitting strips can be formed.

The intermediate floors can be either from the low pressure end or from the high pressure end insert the housing; both are known. In the first of these cases, the thrust exerted by the propellant of the intermediate floors from the last one in the direction of flow Intermediate floor to be transferred to the housing. It is then advisable to do this to assign the axial fixation of the package in the opposite direction to the same intermediate floor, because then the distance between the fixing surfaces and thus the temperature changes caused game changes are the least. The invention therefore provides that this last intermediate floor protrudes radially over the other floors and that on its upper stream end face ring segment-shaped fixing pieces that rest on the housing are releasably attached.

In such a turbine, if the between the housing and the false floor package located annulus, as known, different propellant pressure than that in the first Wheel chamber prevailing is exposed, the current upper end of the package in the housing be slidably sealed. The invention therefore provides that the annular gap between the first intermediate floor in the flow sense and the housing by a sliding one Sealing ring is sealed, which is arranged in an annular groove of this intermediate floor and its material has a higher thermal expansion coefficient than the material of the Housing has.

Since then the tie rods do not extend to the top of the current face of this first Intermediate floor can be carried out, must be downstream of this intermediate floor Areas are created on which the hook-shaped ends of the anchor attack him. This can be done by having the first intermediate floor on its downstream side has an annular projection, which on the outer circumference with an annular groove and over the circumference is provided with incisions into which the tie rods protrude, and that a split ring is inserted into the annular groove, behind which the hook-shaped Grip the ends of the tie rods.

At that end of the intermediate floor package at which it is attached to the housing is in contact, is recommended because the tie rods extend beyond the face of the package, one arranged between the end faces of the last intermediate floor and the housing Support ring with notches into which the hook-shaped ends of the tie rods protrude.

And a resilient seal is also recommended there. Because if not or there is little propellant flowing through the turbine, its thrust may be on the intermediate floor package is not large enough to keep it pressed against the housing; however, a resilient seal will always be in contact with any migration of the package. The invention therefore provides that the support ring has a sealing ring and an annular membrane has, which the support ring to the intermediate floor and the sealing ring to the housing presses on. To protect this membrane it may be advisable that the sealing ring stop pins has, which limit the deflection of the annular diaphragm.

The drawing shows a turbine according to the invention and details thereof, namely in Fig. 1 the turbine in longitudinal section, Fig. 2 the same in cross section AB, Fig. 3 a tie rod in cross section, Fig. 4 the support ring in longitudinal section.

The housing 6 of the turbine is through the two parting lines 601 and 602 divided into the three sections 61, 62 and 63. The middle section 62 encloses the stage part of the turbine. All intermediate floors 1 arranged there are by means of several axially parallel tie rods 2 clamped together so that the intermediate floor package 15, together with these tie rods 2, an insert housing that is independent of the turbine housing 6 4 forms.

To transfer the clamping force acting in the tie rods 2 to the Intermediate floor package 15 these tie rods each have radially directed hook-shaped Ends 21 and 29 on. These lie on the end faces of the first and last guide pulley 11 and 19.

Extends between the insert housing 4 and the turbine housing 6 the free annular space 5. This is via the openings 612 with the front of the control stage 613 of the turbine located inflow channel 611 connected.

The axial thrust acting on the insert housing 4 is shown in FIG Embodiment on the outflow side AS via the one behind the last guide disc 19 arranged on the support ring 8 on the radially inwardly projecting ring shoulder 621 of the middle section 62 of the housing 6. The support ring 8 has incisions 81 for receiving the hook-shaped ends 29 of the tie rods 2.

For the radial cohesion of the halves of the intermediate floors 1 are used Undivided rings 3. Due to their arrangement, each cause between the intermediate floors 1 they at the same time the separation of the step spaces 151 from the outer annular space 5. on The reason for the inequality of the thermal expansion of intermediate floors 1 and rings 3 comes from when the ring shoulders 105 are heated, a firm support is established.

The transfer of the dead weight of the intermediate floor package 15 and of the reaction torque acting on the intermediate floors 1 on the housing 6 is thereby achieves that the tie rods 2 are inserted into the fitting grooves 152. These fitting grooves are formed by the screwed fitting strips 71 and 153.

For the axial fixation of the insert housing 4 against the direction of expansion The fixing pieces 72, which are designed in the form of ring segments, serve. These are located on the inwardly directed end face 191 of the with a larger outer diameter made last intermediate floor 19. The fixing pieces 72 are over the screws 73 releasably connected to the middle section 62 of the housing 6.

The sealing ring 91, which is used to seal the free annular space 5 against the inflow space 614 located directly in front of the insert housing 4, is located in the annular groove 111 running over the outer circumferential surface of the first intermediate floor 11 the outer end face of this first intermediate floor 11 are articulated. Instead, their hook-shaped ends 21, which are directed radially outwards, rest against the end face of the divided ring 114 directed towards the inflow side ES. This split ring 114 is located in the annular groove 113, which extends over the outer circumference of the annular projection 112 of the first intermediate floor 11. The incisions on this annular extension are identified by 115.

The sealing ring 99, which is provided to seal the free annular space 5 against the outflow channel 631 , is located in the annular groove 622 running over the end face of the annular attachment 621. The annular diaphragm 991 arranged on its inwardly directed end face is connected to the support ring via the sealing weld 992 8 connected. The stop pins 993 fixed in the bores 994 serve to limit the deflection of the annular diaphragm 991.

Claims (12)

PATENT CLAIMS: 1. Multi-stage impulse turbine with not in the axial plane, but housing divided in planes normal to the axis, with intermediate shelves divided in axis plane, which are assembled into a package together with the runner during assembly, the one on it is inserted into the housing and is centered in it with radial play so that it can move freely in terms of heat, and with clamping means that the intermediate halves radially and the intermediate floors axially Hold together during assembly and press together vapor-tight during operation, thereby characterized in that the two halves of each intermediate floor (1) are known per se Way through a ring (3) and the intermediate floors in a known manner at least three axially parallel tie rods (2) distributed over the circumference are clamped together are. 2. Turbine according to claim 1, characterized in that each ring (3) in in a manner known per se from material with a lower coefficient of thermal expansion than that of the material of the intermediate floor (1) and that its seat diameter is chosen so that the ring the intermediate floor halves during assembly, so in cold Condition, with a slight snug fit, but in operating temperature with great pressure includes. 3. Turbine according to claim 2, characterized in that each ring (3) on each of the two intermediate floors adjacent to it rests radially and axially. 4. turbine according to one of claims 1 to 3, characterized in that the tie rods (2) with hook-shaped ends (21, 29) rest on the end faces of the intermediate floor package and shrunk onto it. 5. Turbine according to claim 4, characterized in that that the tie rods (2) in axially parallel grooves (152) of the individual intermediate floors and of the housing are fitted. 6. Turbine according to claim 5, characterized in that the fitting grooves (152) of both the intermediate floor assembly (15) and the housing (6) by fitting strips (71 , 153) . 7. Turbine according to one of claims 1 to 6, in which the intermediate floor package is pushed into the housing from the high pressure end and will be thrust exerted by the propellant from its last intermediate floor in the flow sense is transferred to the housing, characterized in that this last intermediate floor (19) protrudes radially over the other floors and that on its upstream end face ring segment-shaped fixing pieces (72) rest, diz attached to the housing (6) in a detachable manner are. e. Turbine according to claim 7, characterized in that the annular gap between the first intermediate floor (11) in the flow direction and the housing (6) by a sliding sealing ring (91) is sealed in an annular groove (111) of this intermediate floor is arranged and its material has a higher coefficient of thermal expansion than the material of the housing. 9. Turbine according to claim 8, characterized in that the first Intermediate floor (11) on its downstream side an annular extension (112) has, which on the outer circumference with an annular groove (113) and over the circumference with Incisions (115) is provided into which the tie rods (2) protrude, and that A split ring (114) is inserted into the annular groove, behind which the hook-shaped Grab the ends (21) of the tie rods. 10. Turbine according to claim 7, characterized by one between the end faces of the last intermediate floor (19) and the housing (6) arranged support ring (8) with incisions (81) into which the hook-shaped The ends (29) of the tie rods protrude. 11. Turbine according to claim 10, characterized in that that the support ring (8) has a sealing ring (99) and an annular membrane (991), the support ring (8) on the intermediate floor (19) and the sealing ring (99) presses against the housing (6). 12. Turbine according to claim 10, characterized in that the sealing ring (99) has stop pins (993) which limit the deflection of the annular diaphragm (991). Considered publications: German Patent Nos. 190159, 401169, 437062, 500077, 538088, 554367, 1.023051, 1055 548; French patent specification No. 896166.