阅读说明：本技术 用于密封两个机器部件之间的周向间隙的密封件 (Seal for sealing a circumferential gap between two machine parts ) 是由 P·希曼斯基 F·蒂多纳 于 2019-08-05 设计创作，主要内容包括：本发明涉及一种密封件,包括：主密封件,具有在机器部件之间建立无接触密封的靴,和将靴支撑在机器部件上的弹簧元件,使得靴的径向运动作为对施加到靴上的流体压力的反应；在轴向上密封弹簧元件的辅助密封件,辅助密封件具有至少两个在轴向上彼此相邻的层。为提高功能可靠性设置：层至少分别包含两个彼此径向并排定位的片；对于每层,一个片是固定的而另一个片通过固定在靴上是可移动的；从径向看,每两个直接彼此相邻的层的两个移动片具有不同的宽度,其中两个移动片中较宽的一个与一个较窄的固定片组合以形成层,两个移动片中较窄的一个与一个较宽的固定片组合以形成层；一层中的较宽的移动片与相应的另一层中的较宽的固定片在径向上重叠。(The invention relates to a seal comprising: a primary seal having a shoe establishing a contactless seal between the machine components and a spring element supporting the shoe on the machine component such that radial movement of the shoe is in reaction to fluid pressure applied to the shoe; an auxiliary seal which seals the spring element in the axial direction and which has at least two layers which are adjacent to one another in the axial direction. The method comprises the following steps of (1) setting for improving functional reliability: the layers each comprise at least two sheets positioned radially alongside one another; for each layer, one sheet is fixed and the other sheet is movable by being fixed to the boot; two moving sheets of each two directly adjacent layers have different widths as seen in the radial direction, wherein the wider one of the two moving sheets is combined with one narrower stationary sheet to form a layer and the narrower one of the two moving sheets is combined with one wider stationary sheet to form a layer; the wider moving sheets in one layer radially overlap the corresponding wider stationary sheets in the other layer.)

1. A seal (2) for sealing a circumferential gap between two machine components, wherein one of the machine components is rotatably mounted in an axial direction (A) relative to the other machine component, the seal comprising:

a main seal (4) having at least one shoe (6) for establishing a contactless seal between a plurality of said machine components, and having at least one spring element (8) supporting said shoe (6) on one of said machine components such that a radial movement (R) of said shoe (6) is enabled as a reaction to a fluid pressure applied to said shoe (6), and

an auxiliary seal (12) sealing the spring element (8) in the axial direction (A), wherein the auxiliary seal (12) has at least two layers (14, 20) adjacent to one another in the axial direction (A),

it is characterized in that the preparation method is characterized in that,

-a plurality of said layers (14, 20) comprising at least two sheets (16, 18, 22, 24) positioned radially side by side with each other, respectively,

-for each layer, one of said sheets (16, 22) is fixed and the other sheet (18, 24) is movably mounted by being fixed on said boot (6), wherein

-two moving sheets (24, 30) of each two directly adjacent layers (14, 20) have different widths, seen in the radial direction (R), wherein the wider one (24) of the two moving sheets is combined with the narrower one (22) of the two stationary sheets to form the layer (20), and the narrower one (30) of the two moving sheets (18) is combined with the wider one (16) of the two stationary sheets to form the layer (14), and

-the wider mobile tabs (24) of one layer (20) overlap the wider fixed tabs (16) of the respective other layer (14) in the radial direction (R).

2. The seal (2) according to claim 1,

characterized in that, for each layer (14, 32), a plurality of moving pieces (18, 34) is arranged in the circumferential direction (U), and the wider moving piece (34) in one layer (32) overlaps with the narrower moving piece (18) in the other layer (14) in the circumferential direction (U).

3. Seal (2) according to one of the preceding claims,

characterized in that a plurality of said layers (14, 20, 26, 32) are arranged without contacting each other at least in the overlapping area.

4. Seal (2) according to one of the preceding claims,

characterized in that a plurality of said sheets (16, 18, 22, 24, 28, 30) in one layer (14, 20, 26, 32) are arranged without contacting each other.

5. Seal (2) according to one of the preceding claims,

characterized in that, at least in one layer (14, 20, 26, 32), the number of moving sheets (18, 24, 30) corresponds to the number of shoes (6).

6. Seal (2) according to one of the preceding claims,

characterized in that the fastening sheet (16) of the innermost layer (14) is formed by an intermediate sheet.

7. Seal (2) according to one of the preceding claims,

characterized in that the mobile flap (18) of the innermost layer (14) is formed by a radial attachment of the shoe (6).

8. Seal (2) according to one of the preceding claims,

characterized in that three layers (14, 20, 26) are arranged, wherein the axially innermost and the axially outermost layers (14, 26) have the same structure.

9. Seal (2) according to one of the preceding claims,

characterized by a holder (10) for the main seal (4), wherein the fixing tabs (16, 22, 28) are fixed to the holder (10).

10. A unit comprising two machine parts, wherein one of the machine parts is rotatably mounted in an axial direction (A) relative to the other machine part and a circumferential gap is formed between the two machine parts, in which circumferential gap a seal according to any one of the preceding claims is arranged,

characterized in that the axial thickness of the axially innermost layer (14) is selected such that the size of the gap between the shoe (6) and the opposite machine component can be adjusted by the position of the auxiliary seal (12).

11. The unit of claim 10, wherein the unit is,

characterized in that the axially innermost layer (36) is arranged only as a spacer below the sealing layers (20, 26) without sealing action.

Technical Field

The invention relates to a seal for sealing a circumferential gap between two machine parts, one of which is mounted axially rotatably relative to the other, comprising: a main seal having at least one shoe for establishing a contactless seal between the machine components and having at least one spring element supporting the shoe on one of the machine components such that radial movement of the shoe can be reacted to fluid pressure applied to the shoe; and an auxiliary seal which seals the spring element in the axial direction, wherein the auxiliary seal has at least two layers which are adjacent to one another in the axial direction.

Background

Such seals are known, for example, from publication US2008/100000a 1. The seal is used in particular for sealing a gap between a rotor and a housing of a turbomachine.

The advantage of the above-described seal is that the sealing gap is set by the volume flow acting on the seal, so that the sealing gap can be flexibly readjusted in the case of different positions of the rotor and the housing. This working principle is implemented in so-called boots, which are suspended in a resilient manner on a support. Such a system is a primary seal system, also known as a primary seal.

Such radially flexible seals require an axial secondary sealing system or secondary seal which also seals the varying axial gap in a flexible manner. This is achieved, for example, by two plates which are each equipped with a spring system, so that they respectively press on the bracket and thus close the opening gap in the direction of the boot. In order to enable the two spring systems (i.e. the spring system of the boot and the spring system of the secondary seal) to run in parallel in a low-friction manner, while keeping the area of the spring system for the secondary seal covered, two assemblies are provided, namely one intermediate plate and one cover. These assemblies have clearance relative to the primary sealing system and free space relative to the secondary sealing system. In gas turbine applications, such a working principle must be realized by means of very complex components. This results in the necessity of ensuring very high manufacturing accuracy, and misalignment of the assembly due to manufacturing accuracy and temperature effects may block the secondary sealing system, so that the corresponding lamellae of the secondary seal cannot completely close the opening axial gap in the direction of the shoe, as required.

Disclosure of Invention

The object of the invention is to provide a seal which has an increased functional reliability compared to the prior art and is more particularly suitable for gas turbines.

According to the invention, this object is achieved by a seal for sealing a circumferential gap between two machine parts, wherein one machine part is mounted axially rotatably relative to the other machine part, comprising: a main seal having at least one shoe for establishing a contactless seal between the machine components and having at least one spring element supporting the shoe on one of the machine components such that radial movement of the shoe can be reacted to fluid pressure applied to the shoe; and an auxiliary seal sealing the spring element in the axial direction, wherein the auxiliary seal has at least two layers adjacent to one another in the axial direction; wherein the layers each comprise at least two sheets positioned radially side by side with respect to each other; wherein in each layer one sheet is fixed and the other sheet is movably mounted by being fixed to the boot; wherein the two moving sheets of each two directly adjacent layers have different widths as seen in the radial direction, wherein the wider one of the two moving sheets is combined with the narrower one of the stationary sheets to form a layer, and the narrower one of the two moving sheets is combined with the wider one of the stationary sheets to form a layer; and the wider moving sheet in one layer radially overlaps the corresponding wider stationary sheet in the other layer.

The invention is based on the following considerations: a sealing system is proposed in which no other spring system is required, the sensitivity and complex design of which is considered to be one of the key points of the known auxiliary sealing systems. In the proposed seal, in particular, the intermediate plate is dispensed with, as a result of which critical interactions between the auxiliary seal according to the prior art and the intermediate plate are avoided. The reliability of the seal is significantly improved since clamping of the secondary seal is no longer required. Furthermore, potential subsequent processing is significantly reduced since the unevenness of the sheet of the secondary seal is no longer present. Due to the layered structure, the complexity is also significantly reduced when assembling the seal. No longer any system acts on the secondary seal in a complex manner, thereby simplifying design and assembly and reducing the number of tests during seal manufacture.

Here, a layer is understood to mean a single sheet, or two or more sheets arranged one after the other in the radial direction and having the same position in the axial direction.

In the case of two layers, the axially outer layer radially overlaps a portion of the adjacent layer in the position of maximum extension. And then may be performed in an alternating manner a plurality of times. The radially inner layer overlaps once and the radially outer layer overlaps once. These short pieces that provide space for the overlapping pieces are understood only as axial spacer pieces, whereby the next layer lying above is again situated in one plane.

Alternatively, a further single sheet may be applied as the last outermost layer, the sheet overlapping circumferentially with the layer below it and being secured directly or indirectly to the stent. This layer achieves the protection function for thin and sensitive sheets located thereunder in terms of transport, installation and operation.

Advantageously, the sheets are made of a material resistant to high temperatures and/or corrosion, in particular steel. The moving plate is composed in particular of a material which maintains the surface quality required for forming the sealing surface during the service life provided and meets the strength requirements during this service. For high temperature applications, high temperature resistant steels, nickel-based alloys or cobalt-based alloys may be chosen, for example

Or similar materials. Non-corrosion resistant materials of sufficient strength, even with relatively low temperature loads, that have the required surface quality to form a sealing surface during service life, are advantageous for all applications.

According to a preferred embodiment, in each layer, a plurality of moving pieces are provided in the circumferential direction, and a wider moving piece in one layer overlaps with a narrower moving piece in another layer in the circumferential direction. The overlap thus produced in the circumferential direction further improves the sealing properties of the seal.

According to a further preferred embodiment, the layers are arranged without contacting each other at least in the overlap region. In particular, in the construction of the respective further layer, the narrower sheet can be temporarily introduced between the layer located below and the new layer, which narrower sheet is removed again after fixing the sheets in their position. A certain amount of clearance can thereby be achieved, which reduces friction between the sheets and does not block the system under lateral forces of the applied pressure.

Preferably, the plurality of sheets in one layer are arranged without contacting each other. This applies in particular to the case in which a fluid pressure is exerted on the boot of the seal. The radial gaps which are produced between the lamellae of one layer are sealed in the radial direction and (possibly) in the circumferential direction by the overlapping of the lamellae of two mutually adjacent layers.

Preferably, the number of moving sheets corresponds to the number of boots, at least in one layer. The moving plate has a circular arc-shaped configuration, and the dimensions of the moving plate optimally match the dimensions of the boot.

Preferably, the innermost anchor sheet is formed by an intermediate sheet. The middle plate must be very stiff so that it can support the pressure of the other sheets. Thereby, axial forces are absorbed by the intermediate plate. Thus, pressing of the movable boot is prevented, as these forces would impair the function. As a result, the interaction between the movable part of the seal and the rigid outer contour is decoupled and movability is ensured. In the case of introducing only a further layer on the secondary seal, in addition to the intermediate plate, the same basic function can be achieved with a minimum number of components.

Further, preferably, the moving piece of the innermost layer is formed by a radial attachment portion of the shoe. Thus, the innermost moving piece is an integral part of the boot, thereby additionally reducing the number of components required and reducing the number of fastening processes required.

In order to achieve a particularly satisfactory sealing action of the seal, three layers are provided, wherein the axially innermost layer and the axially outermost layer have the same structure. Here, the axially innermost layer and the axially outermost layer each have a combination of a narrow moving piece and a wide fixed piece, an intermediate layer between them, a combination of a wide moving piece and a narrow fixed piece, or a combination of a wide moving piece and a narrow fixed piece, an intermediate layer between them, a narrow moving piece and a wide fixed piece.

Advantageously, the mobile plate is fixed to the boot. Furthermore, it is advantageous if the seal has a holder for the main seal, wherein the fastening plate is fastened to the holder. In this way, a reliable, interference-free connection is established between the mobile plate and the boot and/or between the fixed plate and the support, which connection does not loosen during operation. Due to the layered structure, the gap can be directly adjusted during the welding process. Furthermore, unevenness can be neglected, since the sheets are directly welded and the respective gaps can be adjusted by temporary spacer shims. This eliminates the need for clamping and assembly devices. The sheets are welded, soldered, caulked with a corresponding geometry, melted by a material-filling process, or fixed by screws or rivets, for example.

Furthermore, according to the invention, this object is achieved by two machine parts, wherein one machine part is mounted rotatably in the axial direction with respect to the other machine part and a circumferential gap is formed between the two machine parts, in which circumferential gap the above-mentioned seal is arranged, wherein the axial thickness of the axially innermost layer is selected such that the size of the gap between the shoe and the opposite machine part can be adjusted by the position of the auxiliary seal. The advantage here is that, due to the position of the tabs, the required contactless clearance between the seal and the machine part can be adjusted within technically acceptable limits by leveraging the auxiliary seal.

Preferably, in respect of a simplified embodiment of the secondary seal and the sheet precisely positioned axially on the boot, the axially innermost layer is arranged just as a spacer below the sealing layer without sealing action.

Drawings

Exemplary embodiments of the invention are described in more detail below with reference to the accompanying drawings, in which:

figure 1 shows a plan view of a sector of a seal with a main seal,

fig. 2 shows a plan view of a first embodiment of the seal, with a layer of secondary seal and radially overlapping segments,

figure 3 shows a cross-sectional view of the seal according to figure 2,

fig. 4 shows a plan view of a first embodiment of the seal, with a second layer to assist sealing,

figure 5 shows a cross-sectional view of the seal according to figure 4,

fig. 6 shows another cross-sectional view of the seal according to the first embodiment, with a third layer,

fig. 7 shows a plan view of a sector section of the seal, with a first layer of secondary seal,

FIG. 8 shows a plan view of a second embodiment of a seal with a layer of secondary seal and radially and circumferentially overlapping segments, an

Fig. 9 shows a cross-sectional view of a third embodiment of the seal.

Like reference numerals have the same meaning in the figures.

Detailed Description

Fig. 1 shows a part of a seal 2 for sealing a circumferential gap between two machine parts (not shown in detail here), which can be rotated in the axial direction relative to one another. The axial direction is symbolically identified by a point a, wherein the point a is intended to represent the center of the circle formed by the complete seal 2, although no pitch ratio is maintained in the figure. Fig. 1 also shows the radial direction R and the circumferential direction U.

The seal 2 comprises a main seal 4, which main seal 4 has a number of so-called shoes 6 for establishing a contact-free seal between the machine parts. To enable this function, the shoes 6 are each mounted elastically on the carrier 10 by means of a spring element 8. The shoe 6 is supported on a machine part by means of a support 10 so that the radial movement of the shoe can be used as a reaction to the fluid pressure applied to the shoe 6.

Furthermore, the seal 2 comprises a secondary seal 12 of layered construction, the secondary seal 12 sealing the spring element 8 in the axial direction a, wherein the secondary seal 12 has at least two layers adjacent to one another in the axial direction a.

The first layer 14 is shown in fig. 2 and 3. The first layer 14 is formed of two circular or fan-shaped sheets 16, 18 positioned radially side by side. The radially outer plate 16 is fixed by being supported on the bracket 10. The radially inner plate 18 is movable by being fixed to the shoe 6 and moves radially together with the shoe 6. The radial installation space is used asymmetrically by the two sheets 16, 18. One of the two flaps 16, 18 is wider and the other is narrower, wherein this distribution is arbitrary (the case shown here is that the radially outer stationary flap 16 is wider than the radially inner moving flap 18).

The layer 14 is welded directly to the main seal and the sheets 16, 18 should not touch each other at the maximum compression point, so that an internal gap 19 is formed between the two sheets 16, 18.

The second layer 20 of the seal 2 can be seen in fig. 4 and 5. The second layer 20 likewise comprises a stationary plate 22 and a multi-part moving plate 24, wherein the previously radially wider plate becomes narrower in the second layer than in the first layer and the previously radially narrower plate becomes wider in the second layer (in the case described here: the radially outer stationary plate 22 is narrower and the radially inner moving plate 24 is wider).

An intermediate gap 25 exists between the layers 14, 20 so that the layers 14, 20 are positioned in a contactless manner with respect to each other.

The alternation of narrow and wide panels causes the wider moving panels 24 of the second layer 20 to overlap the wider securing panels 16 of the first layer 14. A barrier to the fluid flowing in the axial direction a is thus formed, so that the space behind the auxiliary seal 12, in particular the spring element 8, is axially sealed.

As an alternative to the embodiment according to fig. 2 to 5, the first layer 14 may be constituted by a wider mobile piece in combination with a narrower fixed piece, and the second layer 20 may be constituted by a narrower mobile piece in combination with a wider fixed piece.

Here, the sheets 16, 18, 22, 24 of each layer 14, 20 have the same axial thickness or are at least located at the same axial position. The anchor sheets 16, 22 in particular serve here as a preparation surface for the respective next layer, i.e. the height of the anchor sheet of the layer lying above it is formed by the anchor sheets 16, 22. This can also be seen in fig. 6, where a third layer 26 is introduced. The third layer 26 includes wider securing tabs 28, supplemented by narrower moving tabs 30. In the embodiment shown, the first layer 14 and the third layer 26 therefore have the same structure. The thickness and the clearance are designed such that the axial pressure always ensures contact of the sheets 16, 18, 22, 24, but prevents jamming between each other or due to the axial elasticity of the boot 6.

The fastening tabs 16, 22, 28 are in particular circular, semicircular or fan-shaped tabs. The moving sheets 18, 24, 30 are segmented. The number of moving pieces 18, 24, 30 corresponds to the number of shoes 6, and in the case of only radial overlap, the length of the moving pieces in the circumferential direction U also corresponds approximately to the length of the shoes 6. With a circumferential U overlap, the total length of all the moving pieces 18, 24, 30 in the circumferential direction U corresponds approximately to the total length of all the shoes 6.

It is also conceivable that the third layer 26 according to fig. 6 only comprises wider fixing tabs 28, which overlap the wider moving tabs 24 of the second layer 20.

Fig. 7 and 8 show another embodiment according to the present invention. From fig. 7, the first layer 14 of the secondary seal 12 can be seen, which is identical to the first layer 14 according to fig. 2. In the further layer 32, the anchor sheet 22 is likewise identical to the anchor sheet 22 according to fig. 4. However, the segmented moving piece 34 is configured to be longer in the circumferential direction so that the moving piece 34 overlaps the moving piece 18 of the first layer 14. Thus, between the two layers 14, 32, an overlap occurs both in the radial direction R and in the circumferential direction U.

Similarly to the radial overlap, this construction also starts with a sheet 16 that is uninterrupted in the circumferential direction U in the radially outer immovable region, and with a segmented sheet 18 of each shoe 6 that is independent of one another in the movable region. This layer 14 is welded directly to the main seal, caulked, welded through corresponding grooves, or melted through additive manufacturing and does not come into contact at the maximum compression point. This basic position is required to avoid friction.

Here, the moving pieces 24, 30 and/or the fixing pieces 22, 28 may also be structurally formed as one unit and assembled, respectively.

In contrast, the next layer 32 differs from the first embodiment in that: the overlap occurs in the circumferential direction U from one movable shoe 6 to the next shoe 6. The next layer is overlapped according to the same principle but in the opposite direction. Here, during welding, brazing or caulking, the layers 14, 32 placed on top of each other may be separated from each other by thin spacer shims in order to minimize friction and achieve the envisaged gap described above. This allows sealing under axial compression loads without the shoe 6 and spring element 8 becoming jammed despite the flexibility of the plates 16, 18, 22, 24, 28, 30 themselves.

In this embodiment, as a last and optional layer, a single somewhat thick protective sheet (not shown here) may be arranged continuously in the radially outer region, which protective sheet overlaps under the radially inner region with the segmented, mutually independent sheets 34. If no lamellae are introduced in the radially outer immovable region in the lower layer, the corresponding gap (axial structural height of the lamellae) must be taken into account. If this optional sheet is incorporated, the sheet must be strong so that pressure can be transmitted to the stack of sheets. Introducing a minimum gap by a temporary thin intermediate layer during joining is also advantageous to avoid greater friction.

Fig. 9 shows a further embodiment in which the sealing action of the secondary seal 12 is established exclusively by the second layer 20 and the third layer 26. The first layer 36 is a spacer layer and here includes a narrow stationary plate 16 and a narrow moving plate 18, with a large internal gap 19 between the stationary plate 16 and the moving plate 18. The axial position of the sealing layers 20, 26 is defined by the layer 34, which is formed by the stationary plate 16 and the moving plate 18 and does not directly act as a seal, below the sealing layers 20, 26, so that the required contact-free gap between the seal and the rotatable machine part (rotor) can be adjusted within technically acceptable limits. If the position of the secondary seal 12 is shifted axially upstream by the thicker distance layer 36, the gap between the primary seal 4 and the rotating machine component is opened. If the distance layer 36 is reduced and thus the position of the secondary seal 12 is shifted axially downstream, the gap between the primary seal 12 and the rotating machine component closes. Thus, by adjusting the thickness of the intermediate layer prior to final joining, a quality test can be performed on each seal, and the appropriate thickness of the spacer layer 36 can be selected to meet the requirements for the clearance between the primary seal 4 and the rotating machine component, and then final assembly and joining can be performed.