DE2344666A1 - BRUSH-WIRE STEAM SEALS - Google Patents

Description

Wire Brush Type Steam Seals The invention relates generally on shaft seals for turbo machines and especially on flexible steam seals, which have discrete wire elements that form the annular rows around the rotating Shaft of a steam turbine are arranged around.

The efficiency of a steam turbine depends in part on that maximum steam pressures are exerted on the turbine blades and the steam leakage is reduced to a minimum, which can lead to pressure losses. A source for steam leakage can occur in the axial direction along the rotor shaft between der'Welle and the turbine housing occur. Around any steam leakage along the rotor shaft to throttle or reduce, it is known to use annular, segmented sealing rings to be provided, each of which has a number of grooves concentric to the rotor axis, which tooth sections in between form a seal next to the rotor circumference form.

The sealing rings are radially inward towards the rotor by spring force biased. Under certain abnormal circumstances, the rotor may remove the sealing ring touch or rub against this, causing the sealing ring against the spring preload is bent radially outwards. The tooth sections of the tight tungaring are usually formed from a metal alloy and relatively rigid. One episode grinding or touching can result in permanent deformation or fungus formation be the number sections, which then causes the seal to bottom the increased clearance between the rotor and the seal is effective loses.

Another undesirable consequence of dragging or touching is between the rotor and the steam seal in the known shaft seals the build-up of frictional heat during the occurrence of a grinding contact. This Build-up of frictional heat can cause deformation of the rotor or increased wear and tear effect on the tooth sections of the packing ring.

The above-mentioned spring preload is useful for mitigation some damage that can be caused by the rotor on the sealing or packing ring rubs. According to the invention, however, the effects a grinding contact can be further reduced.

One of the tasks underlying the invention is therefore an improved seal for restricting the flow of propellant along it to create a rotating shaft.

Furthermore, a seal should be created, which is based on the occurrence a rotor contact reacts resiliently.

The present invention further includes a seal that during the occurrence of rotor contact develops minimal frictional heat.

These and related ones. Tasks are according to the invention by a shaft seal with a concentric to the rotor axis of a steam turbine annular sealing ring released, the at least one annular row of relative having flexible discrete wire elements, each one end in a is attached radially inner annular groove in the sealing ring and the free End protrudes radially inwards towards the rotor. According to one embodiment, the Wire elements in a single row per each annular groove, compressed and aligned aligned so that the arcuate curvature of the sealing ring is an overlapping and causes an offset fit under the wire elements at their free end. In A second embodiment is at least two rows of wire elements provided per groove, the second row being offset from the first row so that the wire elements in each row are closely spaced to one another and to one another are arranged in alignment. In another embodiment, is a number of closely spaced fine wire elements (brushes) per each Groove or groove provided, which form a brush-like configuration.

The free ends of each row of wire elements can point in the direction of inclined towards the high pressure area or, alternatively, a section of the wire element be chamfered so as to create a knife-edge seal next to the rotor circumference train, which occurs when a sliding connection occurs in the axial direction bends.

The invention will now be based on further features and advantages the following description and the accompanying drawings of various exemplary embodiments explained in more detail.

Figure 1 is a side view of part of a turbine housing and a part of a turbine rotor with a section of several according to the invention Sealing resp.

Packing rings.

Fig. 2 is an enlarged side view of a sealing ring according to an embodiment of the invention.

Fig. 3 is a perspective view of an inverted portion a sealing ring embodying an embodiment of the invention.

Figure 4 is a similar view to Figure 3 and shows a second Embodiment of the invention.

Figure 5 is a view similar to Figures 3 and 4 and shows a third embodiment, the invention.

1 and 2 is a rotor 11 of a steam turbine, not shown shown, which is rotatably mounted in a turbine shell 13. A ring-shaped one Slack or steam room contains a steam seal to reduce steam leakage to the atmosphere when the rotor passes through the turbine casing 13. In such Cases where adjacent sections are located in the same turbine casing, is the rotor against an internal axial steam leakage from the one section to the other sealed. This is done by sealing or

Packing rings 15 of the rotor shaft, which have a number of throttling points form, which limit the steam leakage along the rotor to a minimum, if the pressure is throttled from a high pressure area (HP) to a low pressure area (LP) will.

The sealing rings 15 can be segmented into arc segments and have a radially outer portion or wedge 17 which has the cross-sectional configuration a "T" can have.

This allows the sealing ring to be inserted movably into a keyway 19 if the shape of an annular groove around the inner circumference of the turbine housing Has. A spring 21 is fixedly mounted in the keyway and gives the sealing ring a radially inwardly directed preload.

According to FIGS. 1, 2 and 3, the sealing ring can be arcuate Segments 25 may be formed, a portion of which is shown in FIG. 3. Each Sealing ring segment is provided with at least one radially inner groove or Groove 27 and usually provided with a plurality of grooves with the arc configuration of the sealing ring segment match.

According to the embodiment shown in FIG. 3, there is a number of wire elements 31 provided, which at one end of the Rille'bzw. Groove 27 attached are. The wire elements are pressed tightly together and are flush with one another in one individual row 35 in each groove or groove. Because of the arched curvature of the sealing ring segment, the free ends of the wire elements form a little bit overlapping and staggered fit with one another, creating a relatively self-contained Seal arises. The free ends of the wire elements usually do not touch the rotor circumference, but are arranged in close proximity to this. Furthermore you can the grooves or grooves in the sealing ring or the sealing ring segments in the direction be inclined on the high pressure area (HP) so that the wire elements also are inclined in the same direction, creating a knife edge seal next to the Rotor circumference is formed.

This type of arrangement is referred to as a helical tooth arrangement. It is also advantageous because the high pressure area has the slope that Closing the seal instead of opening it. Bend in this embodiment when contact occurs between the rotor circumference and the wire elements these in the circumferential direction and in the axial direction, the axial bending due to the the wire elements given slope or inclination occurs.

Fig. 4 shows a second embodiment of the present invention, the one packing or sealing segment 25 and the one already explained above Has groove or recess 27.

In this embodiment, however, the groove may be at least two Rows 37 of the wire elements in an aligned but offset relation take up. The offsetting or nesting of the rows of wire elements is prevented a steam leakage due to gaps between adjacent wire elements that if there are radius differences between the fixed and free ends of the wire elements, which were pressed tightly together in the first embodiment. In this embodiment the wire elements do not need to be pressed tightly together due to the offset relationship although they are still necessarily closely spaced. This embodiment is a bit more flexible due to the larger distance between the wire elements and can also be implemented in a helical arrangement as described above has been described.

The wire elements can have a diameter of the order of magnitude 1.6 mm (1/16 inch) and as technically necessary based on wire element diameter, Be spaced length and diameter of the turbine shell itself.

In Fig. 5 is a third embodiment of the present invention shown, the one packing ring segment 25 and the groove or recess 27 has. The groove can accommodate numerous rows of finer wire elements 41, which form a brush-like configuration 43. The wire elements can be related on alternating rows also staggered or

be nested, and the flexibility will be according to the density of the Wire elements varied. The wire elements in this embodiment can on beveled on the low pressure sides by creating a knife edge seal so that they move axially when there is a grinding contact with the rotor circumference Direction can bend. Alternatively, a Helical tooth arrangement applied. will.

The mode of operation is as follows: Under normal operating conditions the free ends of the wire elements are at a very close distance from the rotor circumference arranged even if there is no contact. Under abnormal operating conditions the rotor circumference can touch the wire elements or rub against them. If this occurs, the sealing ring or the ring segment bends due to the spring 21 in a known manner radially outwards.

In addition and according to the invention, the wire elements bend axially in the high pressure direction and also in the circumferential direction, creating a tight seal alongside the rotor shaft is maintained.

When the abnormal conditions recede and, consequently, the rotor seal contact the wire elements will then spring back to their original state.

Claims (8)

Expectations 0 seal, especially for a turbomachine, which is driven by the axial Flow of a propellant is driven and a turbine shell and one therein arranged rotor, with an annular clearance formed therebetween is, g e k e n n n z e i c h n e t d u r c h at least one annular sealing or packing ring (15), which is arranged concentrically to the rotor (11) and through the Turbine casing (13) is held, and at least one row of rings closely spaced Wire elements (35, 37, 43) arranged in the annular clearance, each wire member having one end attached to the packing ring (15) is attached, and has a free end very close to the rotor (11), so that with this a relatively flexible throttle seal can be formed. 2. P 'ung-according to claim 1, d a d u r c h g e k e n n -z z c h n e t that every ring-shaped sealing or Packing ring (15) with at least one annular groove or recess (27) is provided on its radially inner circumference, in which one end each wire element is attached. 3. Seal according to claim 2, d a d u r c h g e k e n n -z e i c h n e t that each annular groove or recess (27) is an annular row of wire elements (35) with the attached end of each wire element squeezed closely together and with the adjacent wire elements of the same row of rings is arranged in alignment, so that the curvature of the annular sealing or Packing ring (15) an overlapping and offset relation under the free ends the wire elements are formed. 4. Seal according to claim 2, since d u r c h gek e n n -z e i c h n e t that each annular groove (27) is at least two rows of rings closely spaced Has wire elements (37), wherein the rows of rings are arranged such that the wire elements of one row with respect to the wire elements of the next row are offset in the axial direction. 5. Seal according to claim 2, since dur c h- ge e n n -z e i c h n e t that each annular groove or recess (27) numerous finer wire elements (43) arranged in a brush configuration concentric to the rotor are. 6. -D "t, ung according to claim 2, d a d u r c h g e k e n n -z« i c h n e t that the propellant is from a high pressure area (HP) to a low pressure area (LP) flows and the grooves or depressions (27) and the wire elements in the direction are inclined to the high pressure area. 7. Seal according to claim 2, d a d u r c h g e k e n n -z e i c h n e t that the propellant is from a high pressure area (HP) to a low pressure area (LP) flows and the wire elements (43) at the free end in the direction of the low-pressure area are bevelled. 8. Seal according to one or more of claims 1 to 7, d a d It is noted that the annular sealing or packing ring (15) biased in a keyway (19) of the turbine shell (13) by a spring (21) is. Blank page