奥地利专利AT513507A4 bearings package

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专利摘要:
The invention relates to a wind turbine transmission (1) with a toothed wheel (2) mounted via a hydrodynamic bearing. The fixed bearing is a plain bearing combination of a radial bearing (6) with a radial bearing sliding surface (7), a first thrust bearing (8) with a Axiallagergleitfläche (9), which is arranged in an axial direction (10) adjacent to the radial bearing (6), and a second thrust bearing (14) which is also disposed adjacent to the radial bearing (6) and separated from the first thrust bearing (8) by the radial bearing (6). A lubricant supply device has a supply line (20) for a lubricant to the radial bearing sliding surface (7) of the radial bearing (6). In the radial bearing (6) a first and an asymmetrically designed second transverse groove (22, 24) are formed so that at least a part of the lubricant in the direction of the first and on the second thrust bearing (8, 14) is deflected and the first and the second axial bearing (8, 14) can be supplied with the lubricant exclusively via the radial bearing (6).
公开号:AT513507A4
申请号:T50064/2013
申请日:2013-01-30
公开日:2014-05-15
发明作者:
申请人:Miba Gleitlager Gmbh；
IPC主号:

专利说明:

1
The invention relates to a plain bearing assembly comprising a sliding bearing combination of a radial bearing with a radial bearing sliding surface and a first thrust bearing with a Axiallagergleitfläche, wherein the first thrust bearing is arranged in an axial direction adjacent to the radial bearing, and with a lubricant supply device, which is a supply line for a Includes lubricant for radial bearing sliding surface of the radial bearing. Furthermore, the invention relates to a wind turbine transmission with at least one gear wheel which is mounted on an axle via a sliding bearing package.
Known plain bearing applications from the engineering and engine construction usually require bearing solutions which are designed for either high axial or high radial forces, while the loads in the "secondary direction" play a minor role. In main wind turbine gearboxes, forces in both the axial and radial directions of the same order of magnitude arise due to helical gears and large elastic deformations. The requirement for the most compact and simple construction in a wind gearbox does not permit a spatial separation of the bearing points and thus makes the separation of the hydraulic systems more difficult.
In a fixed bearing arrangement with plain bearings, such as e.g. In a Planetenradlage- tion or in spur gears, consisting of two axial thrust washers, and a radial bearing a suitable oil supply to all contact partners must be ensured. Due to the functional principle of hydrodynamic plain bearings, the drag flow, a required oil volume flow results for each bearing point. At the oil inlet and oil outlet cross sections corresponding pressure levels are established. However, with a common oil supply of the three bearings, 2/27 N2012 / 31600 2 but the division into three separate oil streams before the bearing entrances may occur that the oil flow rates are not divided in the required manner and in extreme cases, a drying between the contact surfaces takes place. Thus, the function of hydrodynamic sliding bearings is no longer guaranteed.
In EP 2 284 420 B1 various types of transmissions or transmission designs are described in the use in wind turbines. Paragraphs [0002] to [0013] of this document also describe the requirements for and the associated problems of the individual bearings for the gear shafts or axles. It should therefore be made at this point to avoid repetition to this document.
From EP 2 383 480 A1 planetary gear for a wind turbine is known, at least one sun gear, a ring gear and a planet carrier, in which a plurality of planetary gears are mounted, a plurality of radial plain bearings for supporting the planetary gears, each comprising a sleeve of a sliding bearing material, either as an inner ring mounted on a planetary gear or mounted as an outer ring in a bore of a planetary gear, wherein an associated Lageraußen- or bearing inner ring is formed either by the bore of the planetary gear or by the Planetenradachse, a plurality Axialgleitlagern for supporting the planet gears, each comprising a first bearing element a slide bearing material, which is applied to a contact surface between a planet carrier cheek and an end face of a planetary gear either on the planet carrier cheek or on the front side of the planetary gear, wherein an associated second bearing element either by di e end face of the planet or is formed by the planet carrier cheek.
For lubrication of plain bearings three different options are described in this document. 1. Pressure lubrication for the loaded operation of the gearbox. The plain bearings are supplied with pressure oil from the planetary gear axle. The pressure oil supply is about 90 0 before the maximum of the load zone of the camp. 3/27 N2012 / 31600 3 2. Submerged lubrication for load-free operation of the gear unit. The plain bearings are supplied with oil via an oil reservoir in the planetary gear axle. The oil reservoir is filled with oil by the immersion of the planetary gear in the oil sump and passes this oil to the sliding bearing on. The oil is supplied approx. 110 ° before the maximum load zone of the bearing. The hydraulic connection of the pressure lubrication and the splash lubrication ensures a drainage of the oil. 3. Oil storage for the load-free operation of the transmission. The radial plain bearings are equipped with oil dam edges on the front sides of the planet gears, so that a defined oil level remains in the Rädialgleitlager. This ensures lubrication of the radial plain bearings in the load-free state.
For pressure lubrication of the axial and / or radial plain bearings may be provided an oil distribution ring which radially surrounds a Sonnenradachse and has a connection to an oil supply passage in a transmission housing, wherein at least one oil distribution channel is provided in the planet carrier, which is connected to the oil distribution ring and at a lubrication point ends up for a planetary gear bearing. In this case, in each of the Planetenradachsen two of an axis parallel to the Planetenradachse Ölverteilungskanalabschnitt outgoing, radially extending bores may be provided, and the sleeves each have two lubricant collection devices, between each of which a circumferential lubricating Stoffversorgungsnut is formed.
For splash lubrication of the axial and / or radial plain bearings can each be provided a bore in the Planetenradachsen, which forms a fillable by dipping the respective Planetenradachse in an oil sump oil reservoir. In this case, in each case one of the oil reservoir outgoing, radially extending bore may be provided in the Planetenradachsen, which ends at the sleeve. The sleeves can also each have in a region in which the outgoing from the oil reservoir bore hole, a lubricant collecting device, which is formed by a recess on the sleeve. 4/27 N2012 / 31600 4
DE 199 60 157 A1 describes the lubricant supply of a planetary drive for supplying by centrifugal lubricant moved to bearings of planetary gears of a first planetary gear set on first at one end to a wall of a planet carrier recorded first planetary pin and for supplying the lubricant to bearings of planetary gears at least longitudinally separated by the wall of the planet carrier from the first planetary gear set second planetary gear set, with a lubricant leading to the first planetary bolt first guide, each with at least one leading through the wall channel in the first planetary pin, each with at least one of the channel outgoing and Lubricant for supporting the planet gears of the first planetary set leading transverse channel and with a arranged on the side of the second planetary gear set second guide.
DE 10 2010 000 809 A1 describes a compact radial-axial bearing with a radial cylindrical radial roller bearing receiving an outer ring and an inner ring and a Axialkräfte receiving axial cylindrical roller bearing with a trained as a wave disk first rotor disk and a second disk designed as a housing disk, wherein the outer ring a Groove and in this groove, the first rotor disk and a first cylindrical roller ring are arranged such that a first side of the first rotor is supported in the axial direction on the inner ring of the radial cylindrical roller bearing, a second side of this rotor disk forms a first career for the first cylindrical roller ring and immediately on this second side, a spacer is arranged adjacent to, wherein further concentric with the spacer disc, the second rotor is arranged and with a first side, a second track for the first cylindrical roller ring image et and with a second side forms a third raceway for a second cylindrical roller ring, adjacent to the second running disk designed as a wave disk third running disk, a first side of this running disk forms a fourth raceway for the second cylinder roller ring and immediately adjacent to the spacer on this first side is arranged, and being on the second side of the third 5/27 N2012 / 31600 5
Running disk a clamping means is applied, by means of which a force in the axial direction of a shaft can be applied.
For lubricant supply, the radial cylindrical roller bearings on channels, which may be connected to the axial cylindrical roller bearing. Alternatively or in combination, the lubricant supply can also be realized via the free spaces in the region of the recess and the gap between the spacer and the second running disk.
DE 195 46 974 A1 describes a radial sliding bearing for electrical machines comprising a bearing housing, at least one solid lubricating ring which is secured coaxially on a shaft, and at least one bearing shell disposed within the bearing shell in which the shaft is rotatably supported, the bearing housing having a radial dividing plane and the bearing shell is a thin-walled bearing shell. The solid lubricating ring is in contact with an oil scraper through which the solid lubricant from an oil sump promoted oil in an oil channel is strippable, which fluidly connects the oil scraper and a running surface of the thin wall bearing shell such that lubricated by the oil scraper oil lubricates the tread of the thin wall bearing shell.
From DE 43 36 915 AI a sliding bearing combination of radial plain bearings and thrust bearings is known in which at least one annularly arranged Axialgleitlagerelement of at least one Axialgleitlager, which is each provided with at least one Axialgleitlagerfläche, arranged on a Radialgleitlagerschale frontally and secured to the Radialgleitlagerschale , The radial plain bearing shell has at least one lubricating pocket for supplying oil to the radial sliding bearing surface. The thrust bearing surface includes a plurality of wedge-shaped or pocket-shaped oil passage surface portions for forming a lubricating oil film or lubricant oil deposit between this thrust bearing surface and a journal bearing surface by rotation of these two surfaces relative to each other. 6/27 N2012 / 31600 6
The object of the invention is to provide a compact slide bearing for a wind turbine or a wind turbine transmission with a simple lubricant supply of the bearing surfaces of the slide bearing.
This object of the invention is achieved in the slide bearing assembly mentioned above in that in the radial bearing at least a first transverse groove is formed so that at least a part of the lubricant is deflected in the direction of the thrust bearing and the first thrust bearing is exclusively supplied via the radial bearing with the lubricant ,
Next, the object of the invention is achieved by the above-mentioned wind turbine gear, in which the sliding bearing assembly is formed according to the invention.
The invention makes use of the intrinsically disadvantageous, different hydrodynamic principles to their advantage by the total required volume flow of the radial and thrust bearing centrally over that sliding bearing with the higher pressure level, i. the radial bearing, is fed and from the plain bearing is supplied with the lower pressure level. The significantly lower lubricant requirement of the radial bearing is compensated by the transverse groove. Thus, the thrust bearing can be supplied with the necessary volume flow without pressure or flow control over the cross flow of the radial bearing and the transverse groove. The advantage here is that by a single point of introduction for the lubricant in the area of the bearing surface of the radial sliding bearing and the bearing surface of the thrust bearing can be supplied with the lubricant, so no complex construction with an additional lubricant supply for the Axialgleitlagerfläche is required. The volume flow to the Axialgleitlagerflächen over the cross section of the at least one transverse groove is easily adjustable. In addition, it is possible to reduce power losses, since due to the low cross-flow of the radial plain bearing, the hydrodynamic power loss can be dissipated only insufficient, in particular a high-speed drive stage of a Windkraftanalgengetriebes. In addition, with this lubricant supply of the plain bearing also improved cooling of the radial plain bearing is achieved due to the increased flow of lubricant. 7/27 N2012 / 31600 7
According to a preferred embodiment, it is provided that the sliding bearing assembly in addition to the first thrust bearing and a second thrust bearing comprises wherein this second thrust bearing is also disposed adjacent to the radial bearing and separated from the first thrust bearing by the radial bearing. It can be provided in this way a simple to be lubricated fixed bearing, in particular for a wind turbine gearbox.
It is advantageous if the second axial bearing can be supplied exclusively via the radial bearing with the lubricant via at least one second transverse groove, whereby the above-mentioned effects can be further improved, in particular the improved cooling of the radial plain bearing.
It is possible that the at least one first transverse groove is formed asymmetrically to the at least one second transverse groove. This structural design of the transverse grooves the bearing loads can be borne without great effort by the volume flows of lubricant can be adapted to the particular needs of each slide bearing.
In particular, it is provided that the at least one first transverse groove has a smaller flow cross-section than the at least one second transverse groove. It is possible in this way to build up different pressure levels across the flow cross sections and to realize different volume flows, whereby the risk of dry running in sections of sliding surfaces can be better avoided. By a correspondingly smaller outlet cross section in the direction of the unloaded thrust bearing is achieved that the oil flow and thus the losses are at the unloaded bearing minimal.
On the other hand, it is alternatively or additionally also possible for the at least one first transverse groove to be offset in the circumferential direction of the radial plain bearing by a predefinable angle value from the at least one second transverse groove. By means of this design variant, it is possible to achieve, in particular in the start-up phase, a chronological sequence of the full supply of lubricant, so that bearing surfaces bearing the highest loads are preferably supplied with the lubricant. 8/27 N2012 / 31600 8
According to another embodiment, it can be provided that the first thrust bearing form a first lubricant gap and the second thrust bearing form a second lubricant gap, the first lubricant gap having a smaller flow cross-section than the second lubricant gap. In this way, the lubricant crossflows in the two directions can be better regulated on the axial sliding bearings.
In order to be able to achieve the compactness of the slide bearing assembly and thus also to better design the lubricant supply to the individual slide surfaces, it is preferably provided that the first and the second axial slide bearing are arranged directly adjacent to the radial slide bearing.
It can further be provided that the radial slide bearing is divided into two partial radial bearings arranged side by side in the axial direction. It can thus be improved, the lubricant supply of the radial sliding bearing, as the sliding surfaces of a single Teilradialgleitlagers is smaller by the division of two Teilradialgleitlagers and thus the distribution of the lubricant can be done faster on the entire storage area. In addition, it is thus also possible to design very wide bearings according to the invention, since only one Axialgleitlager must be supplied via a respective Teilradialgleitlager with the lubricant.
It can be provided that the supply line for the lubricant between the two Teilradialgleitlagern is arranged, whereby the design effort for the Schm ierm ittelzuführung can be reduced even with very wide bearings.
For a better understanding of the invention, this will be explained in more detail with reference to the following figures.
Each shows in a schematically simplified representation:
Figure 1 shows a detail of a wind turbine gearbox in the region of a slide bearing cut in side view.
Figure 2 is a radial slide bearing in view of the sliding surface. 9/27 N2012 / 31600 9
3 shows a variant of a radial sliding bearing in view of the sliding surface.
Fig. 4 shows a detail of a variant of a wind turbine gear in the field of sliding bearing cut in side view.
By way of introduction, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or the same component names, wherein the disclosures contained in the entire description can be mutatis mutandis to the same parts with the same reference numerals or component names. Also, the location information chosen in the description, such as top, bottom, side, etc. related to the immediately described and illustrated figure and are to be transferred to the new situation mutatis mutandis when a change in position.
Fig. 1 shows a cross section through a section of a wind turbine transmission 1. The wind turbine gearbox 1 is in the form of a (simple) planetary gear.
As is known, wind turbines comprise a tower at whose upper end a nacelle is arranged, in which the rotor is mounted with the rotor blades. This rotor is via a transmission with a generator, which is also located in the nacelle, operatively connected, which is translated via the transmission, the low speed of the rotor in a higher rotational speed of the generator rotor. Since such embodiments of wind turbines belong to the prior art, reference should be made at this point to the relevant literature.
The wind turbine transmission 1 has at least one gear 2. This gear 2 is arranged in the wind turbine gear 1 in meshing engagement between a second and a third gear (both not shown). For this purpose, the at least one gear 2 has an outer end toothing 3.
In the embodiment of the wind turbine transmission 1 as a planetary gear, in particular as the main gear of a wind turbine, the second gear is designed as a sun gear with a spur gear, which with a shaft, the 10/27 N2012 / 31600 10th
Generator rotor leads, rotatably connected. The sun gear is usually surrounded by a plurality of gears 2, the planetary gears, for example two, preferably three or four.
The third gear is designed as a ring gear, which surrounds the at least one gear 2 and the gears 2 in the radial direction and which also has at least partially on an inner surface a toothing, in meshing engagement with the outer end teeth 3 of the gear 2 and Gears 2 is. The ring gear is rotatably connected to a rotor shaft of the rotor of the wind turbine or rotatably connected to the housing of the wind turbine gearbox 1.
The teeth of the gears in the wind turbine transmission 1 can be designed as a straight or helical teeth.
The at least one gear 2 (in the following only a gear 2 is described, these embodiments are also applicable to all or more gears 2) is a Gleitlagerpaket 4 on an axis 5, so for example a planetary pin (the so-called planetary axis ) stored. This axis 5 can either be integrally formed with at least part of a gear carrier, in particular a planet carrier, or it is used as a separate component in holes of the gear carrier.
It should be noted that not only single-stage versions of such wind turbine transmissions 1 in the invention are possible, but also multi-stage, for example, two or three stages, including in at least one gear 2, in particular a planet, more spur gears can be integrated, are also Also parallel gear, as described for example in the aforementioned EP 2 284 420 B1, can be displayed within the scope of the invention. Reference is therefore made to this document, which belongs to this description to representational description. Accordingly, the wind turbine transmission 1 may have a simple planetary gear and a parallel two- or multi-stage planetary gear or generally more planetary gear. 11/27 N2012 / 31600 11
It should also be noted that the invention is not only used in planetary gears of wind turbines, but generally in transmissions for wind turbines for transmission shafts, in particular for the translation of the slow speed of the rotor of a wind turbine into a higher speed, or in the storage of waves in wind turbines can be used, for example, the rotor shaft or the shaft which carries the ring gear of a planetary gear.
It should also be noted that in this description the terms "axis" and "wave" are used interchangeably.
The plain bearing assembly 4 comprises at least one radial bearing 6 (hereinafter used synonymously for radial sliding bearings) with a radial bearing sliding surface 7 and a first axial bearing (hereinafter used interchangeably for axial sliding bearings) 8 with an axial bearing sliding surface 9,
The first thrust bearing 8 is arranged in an axial direction 10 next to the radial bearing 6, wherein it is arranged in the embodiment of FIG. 1 immediately adjacent to the radial bearing 6. For this purpose, the sliding bearing assembly 4 comprises a carrier element 11 on which the radial bearing 6 is arranged on the radially inner side and the axial bearing is arranged on one of the axial end faces.
However, there is also the possibility that, as will also be explained below, at least the radial bearing 6 is designed as a multi-layer sliding bearing. In this case, the carrier element 11 may form the carrier layer or the bearing back of the radial sliding bearing 6.
Dashed line is also indicated in FIG. 1, however, that in the case of a multi-layer plain bearing, the radial bearing 6 can also have a separate supporting layer 13 in addition to a sliding layer 12. In this case, the radial bearing 6 is arranged on this supporting layer 13 on the carrier element 11.
It should be noted, however, that generally on the bearing back of the radial bearing 6 and / or the thrust bearing 8, an antifretting layer may be arranged, as is known from the sliding bearing technology. 12/27 N2012 / 31600 12
In the embodiment variant of the plain bearing assembly 4 according to FIG. 1, this preferably has, in addition to the first axial bearing 8, a second axial bearing 14. This second thrust bearing 14 is also disposed in the axial direction 10 next to the radial bearing 6, in particular immediately adjacent to the radial bearing 6, wherein preferably the second thrust bearing 14 is disposed on the support member 11 or the support layer 13 of the radial bearing 6. In this case, the second thrust bearing 14 is separated from the first thrust bearing 8 by the radial bearing 6. The first thrust bearing 8 can thus be arranged on a first axial end face 15 and the second thrust bearing 14 on a second axial end face 16 of the carrier element 11 or the support layer 13.
The plain bearing package 4 is arranged in a housing 17 and preferably connected to this, for example in the form of a press fit or by means of a material-locking and / or positive connection.
In the use of the sliding bearing package 4 for the storage of the gear 2 of the wind turbine transmission 1 can be dispensed with the housing and the sliding bearing package 4 may be connected directly to the gear body, i. be arranged in a bore of the gear 2, wherein here again, the said connection techniques for connecting the sliding bearing assembly 4 can be applied to the gear 2.
In general, it is preferred if the connection of the sliding bearing assembly 4 with the gear 2 or the housing 17 only via the support layer 13 of the radial bearing 6 or the support member 11 takes place.
Preferably, the first thrust bearing 6 and the second thrust bearing 14 are spaced apart from the housing 17 or the gear 2 is arranged.
Although the first thrust bearing 8 and / or the second thrust bearing 14 preferably only have the sliding layer 12, this or these can - as shown in Fig. 1 by dashed lines - also be formed as a multi-layer sliding bearing and in addition to the sliding layer 12, at least the support layer 13 have. 13/27 N2012 / 31600 13
Preferably, the plain bearing package 4 is used to form a (exclusively) hydrodynamic fixed bearing. For this purpose, a first pressure collar 18 and a second pressure collar 19 can be arranged on the axis 5. These may either be attached to the axle 5 or be formed integrally therewith. Optionally, the pressure collars 18, 19 but also attached to the housing 17 or integrally formed therewith.
The plain bearing package 4 further comprises a lubricant supply device, which is not shown in detail in Fig. 1 except for a part of a supply line 20 for the lubricant, in particular a lubricating oil.
The supply line 20 is guided through the housing 17 and optionally the gear 2 and designed as a bore in this / this. If no housing 17 is used, the illustrated part of the supply line 20 may also be arranged only in the gear 2.
The supply line 20 opens into the radial sliding bearing surface 7 of the radial bearing 6, so that via the supply line 20, the lubricant of this radial sliding bearing surface 7 is supplied according to arrow 21. Preferably, the supply line 20 is arranged in the upper, less loaded region of the sliding bearing assembly 4, as shown in Fig. 1.
The supplied lubricant is distributed over the radial bearing sliding surface 7 in order to form a lubricant film between it and the axis 5.
In addition, according to the invention, the lubricant supply of the first thrust bearing 8 and in particular also of the second thrust bearing 14 also takes place via the supply line 20, so that no further supply lines for the lubricant to these thrust bearings 8, 14 are formed. In other words, the first thrust bearing 8 and in particular also the second thrust bearing 14 are supplied with lubricant exclusively via the radial bearing 6.
For this purpose, at least one first transverse groove 22 is formed in the radial bearing sliding surface 7, as shown in FIG. 2, which shows the radial bearing 6 in plan view of the radial sliding bearing surface 7. At least part 14/27 N2012 / 31600 14 of the lubricant is deflected in the direction of the axial bearing via this first transverse groove 22 in accordance with arrow 23 (FIG. 1).
To supply the second axial bearing 14, at least one second transverse groove 24 is formed in the radial bearing sliding surface 7. However, this second transverse groove 24 is formed only when the sliding bearing package 4 (FIG. 1) has two axial plain bearings.
The transverse grooves 22, 24 are open in the region of the radial bearing sliding surface 7 and extend from the mouth of the feed line 29 into the axial end faces 25 and 26 of the radial bearing 6.
In order to better meet the lubricant requirements of the thrust bearings 8 and 14, the at least one first transverse groove 22 and the at least one second transverse groove 24 can be formed asymmetrically with respect to one another. For this purpose, for example, the first transverse groove 22 may have a first flow cross section 27 and the second transverse groove 24 may have a second flow cross section 28, wherein the first flow cross section 27 is smaller than the second flow cross section 28, as can be seen from FIGS. 2 and 3. With regard to the width and / or the depth and / or the cross-sectional shape of the transverse groove 22, the first flow cross-section 27 may differ from the second flow cross-section 28.
In general, the transverse grooves 22 and 24 are preferably produced by machining the sliding layer 12.
The transverse grooves 22, 24 may have a width in the circumferential direction of the radial bearing 6, which corresponds to an angle value selected from a range of 1 ° to 20 0 corresponds.
Further, the transverse grooves 22, 24 may have a depth in the radial direction selected from a range of 1% to 100% of the wall thickness of the thrust bearing 8, 14, respectively.
The cross-sectional shape of the transverse grooves 22, 24 may be rectangular, square, triangular, polygonal, etc., with the rectangular or square or triangular being preferred. 15/27 N2012 / 31600 15
Further, the edges formed at the junctions of the walls of the transverse grooves 22, 24 may be rounded to improve the flow behavior of the lubricant.
As can be seen from FIG. 3, a plurality of transverse grooves 22 and / or transverse grooves 24 can be arranged next to one another and spaced from one another in the circumferential direction of the radial bearing 6. It is also possible that the number of first transverse grooves 22 differs from the number of second transverse grooves 24 in the radial bearing sliding surface 7.
In general, the number of first transverse grooves 22 may be selected from a range of 1 to 4.
The number of second transverse grooves 24 may also be selected from a range of 1 to 4.
Either more first transverse grooves 22 or more second transverse grooves 24 may be formed in the radial bearing sliding surface 7, whereby in this connection consideration may also be given to the flow cross section 27 or 28 with regard to the number of transverse grooves 22 and / or transverse grooves 24. It can be reduced as a larger flow cross-section 27 and 28, the number of transverse grooves 22 and 24, and vice versa.
In addition, there is the possibility that the transverse grooves 22 and / or 24 arranged side by side in the circumferential direction of the radial bearing 6 differ from each other with respect to the width and / or the depth and / or the cross-sectional shape. For example, the width and / or the depth in the direction of the higher loaded area of the radial bearing 6, which is usually not shown in the lower portion of the plain bearing, become larger. Likewise, the cross-sectional shape in the circumferential direction of the radial bearing 6 can be considered changed, for example, a triangular cross-sectional shape in the upper region and a rectangular-shaped cross-sectional shape in the lower region of the radial bearing 6 may be formed. 16/27 N2012 / 31600 16
The statements "above" and "below" refer to the installation position of the radial bearing 6, so that "above" the area above the axis 5 (Fig.1) and "below" the area below the axis 5 denote.
Dashed line is indicated in Fig. 3 that the first transverse groove 22 and / or the second transverse groove 24 may be formed not only as axial grooves, but may also have a different course to the axial direction.
For example, the first transverse groove 22 and / or the second transverse groove 24 may be oblique and include an angle 29 with the axial direction 10. Likewise, the first transverse groove 22 and / or the second transverse groove 24 may have a curved course. There are also mixed forms possible, as a mixture of first transverse grooves 22 and / or the second transverse grooves 24 in the axial direction and obliquely to the axial direction or arcuately, wherein the direction of a plurality of first transverse grooves 22 and / or a plurality of second transverse grooves 24 in the circumferential direction of the radial bearing 6 may be different, so for example, a first transverse groove 22 and / or a second transverse groove 24 extends in the axial direction in the region of the apex of the radial bearing 6 and a further first transverse groove 22 and / or second transverse groove 24 in a different area from the apex of the radial bearing 6 or arcuate runs.
Furthermore, there is the possibility that a plurality of first transverse grooves 22 and / or second transverse grooves 24 are flow-connected to one another via an additional groove in the circumferential direction of the radial bearing 6 or at an angle to the circumferential direction of the radial bearing 6.
As can be seen from FIG. 3, the at least one second transverse groove 24 can be arranged offset in the circumferential direction of the radial bearing 6 by a predefinable angle value relative to the at least one first transverse groove 22. The angle value can be selected from a range of 2 0 to 20 °.
In Fig. 3, a further embodiment of the lubricant distribution is shown. In this case, the supply line 20 opens into a distribution groove 30, which extends for example with its longitudinal extent in the circumferential direction of the radial bearing 6. The at least one first transverse groove 22 and optionally the at least one second transverse groove 24 extend as a result from this distribution groove 30 into the end faces 25 and optionally 26 of the radial bearing 6. This embodiment variant can be provided in particular a plurality of first transverse grooves 22 and optionally a plurality of second transverse grooves 24 are arranged.
As can be seen from FIG. 1, the first thrust bearing 8 is spaced apart from the pressure collar 18, forming a first lubricant gap 31, and the second thrust bearing 14 is arranged at a distance from the pressure collar 19 to form a second lubricant gap 31. In this case, the first lubricant gap 31 may have a smaller flow cross-section than the second lubricant gap 32, that is, the distance between the Axiallagergleitfläche 7 of the first thrust bearing 6 and the pressure collar 18 is smaller than the distance between a Axiallagergleitflä-che 33 of the second thrust bearing 14 and the pressure collar 19th ,
The pressure collar 18 may be arranged spaced from the housing 17 or the gear 2, whereby a flow channel 34 is formed between them, via which the lubricant can be discharged according to arrow 35 from the region of the sliding bearing package 4. The discharged lubricant can be supplied to a corresponding collecting device to re-introduce it from there into the lubricant circuit, optionally after cooling.
The same applies to the pressure collar 19.
In contrast to the embodiment of FIG. 1, in this case the radial bearing 6 is divided into at least two partial Radialgleitlager 36, 37 arranged side by side in the axial direction 10, wherein a gap is formed between them , The two Teilradialgleitlager 36, 37 may be formed according to the above embodiments as a single-layer or multi-layer sliding bearing. 18/27 N2012 / 31600 18
The first thrust bearing 8 is arranged in this embodiment on the left in Fig. 4 Teilradialgleitlager 36 and the second thrust bearing 14 on the right in Fig. 4 Teilradialgleitlager 37. Since only one axial bearing 8 or 14 is arranged per partial radial plain bearing 36, 37, the partial radial plain bearing 36 preferably only has the transverse grooves 22 (eg FIG. 2) and the partial radial plain bearing 37 only the transverse grooves 24 (eg FIG. 2) to supply them via the thrust bearing 8 and 14 with the lubricant.
The lubricant supply of the two Radallagergleitflächen 7 is again via the supply line 20, which in this case preferably as an axial bore, e.g. in the housing 17, is branched off from the radial bores 38, 39, which lead to the radial bearing sliding surfaces 7.
Alternatively, as shown in broken lines in FIG. 4, the supply line 20 for the lubricant may also be arranged between the two partial radial bearings 36, 37. In this case, between the two partial radial bearings 36, 37, a feed web 40 may be arranged on the housing, which extends into the region of the partial radial plain bearings 36, 37. The transverse grooves 22 and 24 extend over the entire axial extent of the sliding layers 12 of the partial radial plain bearings 36, 37.
The radial bearing 6 or the Teilradialgleitlager 36, 37 may be performed in principle in the form of plain bearings shells. However, these are preferably designed as bearing bushes.
A multilayer plain bearing in the sense of this description consists at least of the support layer 13 and a sliding layer 12, which is applied to the support layer 13. The sliding layer 12 forms the running surface for the axis fifth
In addition to this two-layered embodiment of the multilayer plain bearing, it is also possible within the scope of the invention for intermediate layers to be arranged between the sliding layer 12 and the support layer 13, for example a bearing metal layer and / or at least one bonding layer and / or one diffusion barrier layer. 19/27 N2012 / 31600 19
Examples of materials for the individual layers of the multilayer plain bearing are described in AT 509 624 B1, to which reference is made in this regard and which belongs to this scope to the description of the present invention.
For the sake of order, it should finally be pointed out that, for a better understanding of the construction, wind turbine transmission 1 of this or its constituent parts have been shown in an inaccurate manner and / or enlarged and / or reduced in size. 20/27 N2012 / 31600
LIST OF REFERENCE NUMBERS
Wind Turbine Gearbox
gear
External spur gearing
bearings package
axis
radial bearings
Radiallagergleitfläche
thrust
Axiallagergleitfläche
axially
support element
Overlay
backing
thrust
face
face
casing
thrust collar
thrust collar
supply line
arrow
transverse groove
arrow
transverse groove
face
face
Flow area
Flow area
angle
distribution groove
lubricant gap
lubricant gap
Axiallagergleitfläche
flow channel
arrow
Partial radial bearings
Partial radial bearings
radial bore
radial bore
Feedbridge 21/27 N2012 / 31600

权利要求:
Claims (10)
[1]
1 sliding bearing package (4) comprising a sliding bearing combination of a radial bearing (6) with a Radialagergleitfläche (7) and a first thrust bearing (8) with a Axiallagergleitfläche (9), wherein the first thrust bearing (8) in an axial direction ( 10) next to the radial bearing (6) is arranged, as well as with a lubricant supply device, which comprises a supply line (20) for a lubricant for Radialagergleitfläche (7) of the radial bearing (6), characterized in that in the radial bearing (6) at least a first Quemut (22) is formed, so that at least a part of the lubricant in the direction of the first thrust bearing (8) is deflected and the first thrust bearing (8) exclusively via the radial bearing (6) can be supplied with the lubricant.
[2]
2. plain bearing assembly (4) according to claim 1, characterized in that this next to the first thrust bearing (6) and a second thrust bearing (14) wherein the second thrust bearing (14) also next to the radial bearing (6) and arranged by the first thrust bearing ( 8) is separated by the radial bearing (6).
[3]
Third plain bearing package (4) according to claim 2, characterized in that the second thrust bearing (14) exclusively via the radial bearing (6) with the lubricant via at least one second transverse groove (24) can be supplied.
[4]
4. plain bearing package (4) according to claim 3, characterized in that the at least one first transverse groove (22) is formed asymmetrically to the at least one second transverse groove (24).
[5]
5. plain bearing assembly (4) according to claim 4, characterized in that the at least one first transverse groove (22) has a smaller flow cross-section (27) than the at least one second transverse groove (24). 22/27 N2012 / 31600 2
[6]
6. plain bearing package (4) according to one of claims 3 to 5, characterized in that the at least one first transverse groove (22) in the circumferential direction of the radial bearing (6) offset by a predefinable angle value to at least one second transverse groove (24) is formed.
[7]
7. plain bearing package (4) according to one of claims 2 to 6, characterized in that the first thrust bearing (8) a first lubricant gap (31) and the second thrust bearing (14) form a second lubricant gap (32), wherein the first lubricant gap ( 31) has a smaller flow cross-section than the second lubricant gap (32).
[8]
8. plain bearing assembly (4) according to one of claims 1 to 7, characterized in that the first and the second Axialgleitlager (8, 14) immediately adjacent to the radial bearing (6) are arranged.
[9]
9. plain bearing assembly (4) according to one of claims 1 to 7, characterized in that the radial bearing (6) is divided into two in the axial direction (10) juxtaposed Teilradialgleitlager (36, 37).
[10]
10. wind turbine transmission (1) with at least one gear (2) which is mounted on an axle (5) via a sliding bearing (4), characterized in that the sliding bearing assembly (4) is designed according to one of the preceding claims. 23/27 N2012 / 31600

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同族专利:

公开号 | 公开日

DK2951451T3|2017-07-31|

CN104956101B|2017-09-01|

US9683602B2|2017-06-20|

AT513507B1|2014-05-15|

US20150369284A1|2015-12-24|

KR20150113088A|2015-10-07|

EP2951451A1|2015-12-09|

CN104956101A|2015-09-30|

EP2951451B1|2017-04-26|

ES2634912T3|2017-09-29|

KR102099873B1|2020-04-13|

WO2014117195A1|2014-08-07|

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法律状态:
2017-12-15| PC| Change of the owner|Owner name: MIBA GLEITLAGER AUSTRIA GMBH, AT Effective date: 20171113 |

2021-09-15| MM01| Lapse because of not paying annual fees|Effective date: 20210130 |

优先权:

申请号 | 申请日 | 专利标题

ATA50064/2013A|AT513507B1|2013-01-30|2013-01-30|bearings package|ATA50064/2013A| AT513507B1|2013-01-30|2013-01-30|bearings package|

EP14711906.9A| EP2951451B1|2013-01-30|2014-01-27|Slide bearing set|

PCT/AT2014/050028| WO2014117195A1|2013-01-30|2014-01-27|Slide bearing set|

ES14711906.9T| ES2634912T3|2013-01-30|2014-01-27|Sliding Bearing Package|

KR1020157023218A| KR102099873B1|2013-01-30|2014-01-27|Slide bearing set|

US14/763,006| US9683602B2|2013-01-30|2014-01-27|Slide bearing set|

DK14711906.9T| DK2951451T3|2013-01-30|2014-01-27|SLIDING BEARING KIT|

CN201480006262.7A| CN104956101B|2013-01-30|2014-01-27|sliding bearing group|

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