RU2099618C1 - Contactless end seal - Google Patents

Abstract

FIELD: hydraulic machinery engineering; multi-mode turbomachines, especially cantilever compressor machines. SUBSTANCE: contactless end seal includes working gas flow rate limiter made in form of labyrinth and two sealing stages mounted in single housing in series. Each sealing stage is provided with seal ring which is movable axially and is locked against turn. Sealing ring is provided with projection formed due to stepped change of thickness of ring on side of inner diameter. This ring is tightly fitted in housing on flexible members by means of secondary seal forming sealing slot with revolving ring flexibly fitted on shaft; it is also provided with clearance control device made in form of circular stepped sealing surface having recess on side of periphery on end face of revolving ring with ribs located in zone of recess of stepped surface from step to periphery of ring; they have lesser height as compared with step; they are directed towards high-pressure cavity and are inclined in direction of rotation of shaft. This device may be also made in form of circular bores in outer cylindrical surface of revolving ring, thin-wall projection on sealing ring with bore at its base on the reverse of ring mounted for secondary rubber seal on side of sealing ring and housing of movable circular member made from polymer possessing increased antifriction properties; provision is made for unloading over inner cylindrical bearing surface of member. Construction of seal provides for amount and shape of clearance during operation of turbomachine excluding effect of start-stop mode on serviceability of end seal. EFFECT: enhanced stability of time characteristics, enhanced efficiency and increased service life. 4 dwg

Description

 The invention relates to a sealing technique, namely to mechanical seals of multi-mode turbomachines.

 A mechanical seal is known (see German patent 3722303, class F 16 J 15/34, 01/19/89), the clearance control device of which is made in the form of wedge-shaped grooves on the working end surface of the rotating ring, creating a pumping effect and pumping gas into the sealing gap. The sealing effect is provided by a smooth gap located below the inner diameter of the grooves.

 The disadvantage of this seal is the limited resource due to contact of the working surfaces during starts and stops of the turbomachine and, consequently, their wear. This leads to a decrease in the depth of the grooves and reduces their effectiveness, which can cause the seal to fail. In addition, to ensure low leakage of the working fluid through the seal, the smooth sealing gap must have a large length, which increases the dimensions of the seal. The clearance control device affects only the size of the gap, but not its shape.

 Other known mechanical seals with gas-dynamic chambers have the same drawbacks (US Pat. No. 2,623,357, class F 16 J 15/34, 1952; European Patent No. 0037210, class F 16 J 15/34, 03/18/81).

 The closest in technical essence to the proposed object is a mechanical hydrodynamic seal (see German patent N 2248572, CL F 16 J 15/34, 1976), in which the clearance control device is made hydrostatic in the form of a stepped surface from the side of the high-pressure cavity and deaf grooves connecting the area of the step with the area of a narrow gap. This provides an additional forced supply of lubricant to the contact zone, which, in turn, reduces the risk of wear of the contacting surfaces during operation of the turbomachine.

 A disadvantage of the known device is its low efficiency, since when supplying lubricant to the narrow gap area with the help of blind grooves, leakages through the seal also increase. In addition, when starting and stopping the turbomachine, the working surfaces will touch. Their wear leads to a decrease in the step and sharply reduces the force regulating the gap, since the lubricant enters into the blind grooves only when there is a step. This reduces the compaction life.

 The basis of the invention is the task of increasing the efficiency and resource of the mechanical seal by regulating the size and shape of the gap and eliminating the influence of wear of the sealing surfaces when starting and stopping the turbomachine on the gas-dynamic mechanism for regulating the size of the gap.

 The problem is solved in that in a non-contact mechanical seal, consisting of a sequentially installed working gas flow restrictor in the form of a labyrinth and two sealing stages, each of which contains an axially movable sealing ring with a protrusion formed by a stepwise change in thickness rings on the side of the inner diameter, which is sealed by means of a secondary rubber seal in the housing on the elastic elements and form a sealing slit with a rotating ring resiliently mounted on the shaft, and a clearance adjusting device, wherein the clearance adjusting device is made in the form of a stepped annular sealing surface with a recess on the periphery side on the end face of the rotating ring with ribs located in the stepped surface recess zone from the step to the periphery of the ring and made smaller than the step, directed towards the high-pressure cavity and tilted to the direction of rotation of the shaft, as well as in the form of annular grooves on the outer cylindrical surface of the rotating ring, a thin-walled protrusion on the sealing ring with a groove at its base on the reverse side of the ring, mounted under the secondary rubber seal on the side of the sealing ring and the housing of the movable ring of polymer polymer antifriction properties and with unloading on the inner cylindrical supporting surface of the element.

 In FIG. 1 shows a sealing assembly in section; in FIG. 2 - working end face of a rotating ring; in FIG. 3 section of a sealing ring with a secondary seal; in FIG. 4 working position of a sealing ring at distortions.

 A mechanical non-contact seal, consisting of a sequentially installed in a single housing 1 flow restrictor of the working gas in the form of a labyrinth 2 and two stages of the seal 3 and 4, is designed to separate the gas (A) and oil (E) cavities (Fig. 1). The cavity A is formed by the housing 5 of the turbomachine and the rear side of the centrifugal wheel 6. The seal is a single unit and has a modular design. The rotating parts are fixed on the sleeve 7, which is mounted on the shaft 8 with the nut 9. The torque is transmitted using the pin 10. The sealing steps are fixed in the housing 1 by the covers 11 and 12. Stage 3 is the main, and the stage 4 is backup. They form four intermediate cavities. Gas is supplied to cavity B through channel 13 from the exit of the centrifugal stage 6 through fine filters. Part of it seeps through stage 3 into cavity B. The rest of the gas through the labyrinth 2 returns back to the centrifugal stage. Gas leaks from the main stage 3 through the labyrinth at the reserve stage 4 fall into the cavity Г and are discharged into the atmosphere through a system of channels 14. The backup stage 4 operates with a small pressure drop, leaks from it fall into the cavity D and are discharged through the channel 15 into the atmosphere. Spiral seal 16 separates the cavity D and the oil cavity E.

 Each of the steps contains an axially movable sealing ring 17 with a protrusion formed by a stepwise change in the thickness of the ring from the side of the inner diameter. The ring 17 is fixed against rotation by the protrusions on its outer part, which enter the grooves in the housing 18. It is sealed by means of a secondary rubber seal 19 in the housing 18 on the elastic elements 20. The sealing ring 17 forms a sealing gap with a rotating ring 3, which is resiliently mounted on the sleeve 7. This allows the centering of the ring 3 and the compensation of technological distortions (self-installation of the ring) during rotation of the rotor. Torque is transmitted using pin 21. Static seals are carried out by rubber rings 22.

 On the end surface of the rotating ring 3 (Fig. 2) there is a step 23 of height h with a recess from the periphery of the rotating ring. From the step toward the periphery of the ring, ribs 24 extend, made of a lower height H compared with the step, directed towards the high-pressure cavity and inclined in the direction of rotation of the shaft. The dashed lines 25 show the contours of the sealing ring 17 in contact with the ring 3. On the rotating ring 3, annular grooves 26 are made along the outer diameter to intensify heat removal from the contact zone. At the same time, these grooves act as a labyrinth seal to limit the flow rate of the working filtered filtered gas.

 The protrusion 27 (Fig. 3) on the sealing ring 17 from the side of the inner diameter is made thin-walled with a groove 28 at its base from the back of the ring. The secondary rubber seal 19 is installed on the side of the sealing ring 17 and the housing 18 on the λ-shaped element 29 with a small supporting inner cylindrical surface with gas-static unloading, which is ensured by the shape of the element 29. The element is made of polymer with increased antifriction properties.

 When the shaft rotates, the ribs 24 provide the injection of the working medium into the gap zone, forming a gas-dynamic force that prevents the contact of the rings 3 and 17. The step 23 limits the size of the sealing gap, which reduces the leakage of the working medium through the seal. The height of the step h can be used to control the amount of leakage, and the height H and the slope of the ribs can be used to control the gas-dynamic force and rigidity of the lubricating film. During start-up and shutdown of the turbomachine, rings 3 and 17 contact only in the leakage zone, which prevents wear of the ribs 24. That is, even when the step wears out, the lubricant will be pumped into the gap, and the geometry of the ribs and, therefore, their ability to generate gas-dynamic force remains unchanged.

 This leads to a constant gap during operation of the turbomachine. Heat is generated in the friction zone, leading to thermal deformations of the rings. The annular grooves 26 increase the convective heat transfer to the cooling gas flowing between the rotating ring 3 and the cover 11, which reduces the temperature of the rings and the distortion of the shape of the gap. That is, in this case, the functions of intensifying heat transfer and labyrinth compaction are combined. If an inert separation gas is introduced between stages 1 and 2 into cavity G with leakage from the main sealing stage to the atmosphere directly from cavity B, this design eliminates the need for an additional labyrinth seal (see the BURGMANN catalog, page 56, bottom figure ) This reduces the axial dimensions of the sealing assembly by the axial length of the labyrinth seal, which is especially important with the cantilever arrangement of the compressor impeller, where the axial length of the sealing assembly has a decisive influence on the size of the cantilever and the dynamic characteristics of the rotor. The implementation of the protrusion 27 of the sealing ring 17 with a reduced thickness and a groove 28 provides for its compliance. With an increase in the pressure drop across the seal from power and temperature deformations, a cross-section of the sealing ring appears (Fig. 4). The protrusion 27 is bent, and at the exit from the slit, a section of plane-parallel clearance is established. The use of an additional element 29 between the secondary rubber seal 19, the sealing ring 17 and the housing 18 ensures that no jamming occurs during axial movements of the sealing ring 17 when tracking the rotor movements. With significant distortions of the shaft relative to the housing, the sealing ring will track these movements due to the elastic installation of the rotating ring 3 and the greater angular mobility of the ring 17 due to the possibility of increasing the gap between the inner surface of the sealing ring 17 and the centering surface of the housing 18. This was made possible due to the fact that the installed an additional element 29 prevents extrusion of the rubber ring into the gap.

 Thus, the proposed design of the seal will provide control of the size and shape of the gap during operation of the turbomachine and eliminate the influence of the start-stop mode on the performance of the mechanical seal. As a result, the seal will have stable characteristics over time, increased efficiency and resource.

 This seal can be used in multi-mode turbomachines with high pressures of the working medium. Especially effective is the application for cantilever compressor machines, where there are significant distortions of the shaft relative to the housing.

Claims (1)

 A non-contact mechanical seal, consisting of a labyrinth and two sealing stages, sequentially installed in a single enclosure of a working gas flow limiter, each of which contains an axially movable sealing ring with a protrusion formed by a stepwise change in the thickness of the ring from the side of the inner diameter, which installed tightly by means of a secondary rubber seal in the housing on the elastic elements and forms a sealing gap with elastic devices a rotating ring on the shaft, and a clearance adjustment device, characterized in that the clearance adjustment device is made in the form of a stepped annular sealing surface with a recess on the periphery side on the end working surface of the rotating ring with ribs located in the stepped surface recess zone from the step to the periphery rings and made of a lower height in comparison with a step directed towards the high-pressure cavity and inclined in the direction of rotation of the shaft, as well as in the form of annular grooves on the outer cylindrical surface of the rotating ring, a thin-walled protrusion on the sealing ring with a groove at its base on the reverse side of the ring, mounted under the secondary rubber seal on the side of the sealing ring and the body of the movable ring element made of polymer with increased antifriction properties and with unloading on the inner cylindrical supporting surface of the element.

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