WO2010022778A1 - Axial plain bearing and bearing segment for the same - Google Patents

Abstract

The axial plain bearing (20) performs substantially the same functions as a known tilting-segment axial plain bearing, but has different bearing segments (30). The bearing segment (30) for an axial plain bearing (20) has a head region (31) and a base region (33), with the head region (31) forming a sliding surface (35) which can be tilted relative to the base region (33). The tilting capability of the sliding surface (35) relative to the base region (33) is enabled by means of an elastic deformability of the bearing segment (30). A waisted intermediate region (32) is advantageously formed between the head region (31) and the base region (33), the elastic deformability of which enables the tilting capability of the sliding surface (35) relative to the base region (31). The bearing segment (30) may be formed in one or two pieces. In one embodiment, the bearing segment (30) has a duct (36) which extends through the base region (33) and through the head region (31). The axial plain bearing has at least one bearing segment according to the invention. The device has at least one axial plain bearing according to the invention.

Description

Axial sliding bearing and bearing segment for it

Technical area

The invention relates to axial sliding bearing and bearing segments for it. Furthermore, it relates to drive arrangements for mills and turbines with axial plain bearings. The invention relates to

Devices according to the preamble of the claims.

State of the art

Highly loaded axial plain bearings with a large diameter, as used for example in mills such as vertical roller mills or in hydropower plants with Kaplan or Francis turbines, typically have several bearing segments, each with a tilting segment. A tilting segment has a sliding surface for supporting a body to be supported (mill flange, turbine rotor) and can be tilted in each direction by typically about 0.1 °. This serves to allow each individual tilting segment to adapt to the local load and the oil film. Large and locally occurring loads can be compensated and the fact that the oil can be warmed by the high pressure and the sliding movement and sideways, so that the oil film is getting thinner and therefore at the inlet side of the tilting pad is slightly thicker than at the outlet side, can be taken into account ,

A bearing segment typically consists of three parts: a tilting pad, a pressure piece and a counterpart.

Usually, the tilting segment is a round or trapezoidal cut steel plate with a bearing metal coating to form a suitable

Sliding surface. On the back of Kippsegmentes a slightly cambered executed pressure piece made of high-strength or optionally hardened steel is embedded. As a counterpart to the cambered pressure piece a flat plate, also made of high-strength or hardened steel is used.

Since the pressure piece with its crowning superimposed on the flat counterpart, it can be tilted in a small angular range, and with him the tilting segment. It comes with the large-acting forces between pressure piece and counterpart to Hertzian pressure.

In order to achieve a uniform load on all tilting segments, the tilting segments, pressure pads and counterparts together must lie within a total thickness tolerance of approximately 0.02 mm. This is usually done by inserting a customizable spacer between

Pressure piece and tilting segment reached. The result of these measures is a uniform surface pressure in each tilting segment. Achieving the said total thickness tolerance is, however, expensive, since it requires the maintenance of very small individual tolerances of the three components of each bearing segment and / or a precise adjustment of the bearing segments by means of the spacer plates.

In the case of very large tilting segments, at least the starting operation is additionally assisted by means of high-pressure lubrication. For this purpose, an oil supply line is connected to the side of the tilting segment, which must have a certain flexibility, so that the line is not leaked by the - albeit small - movements of the tilting segment. The oil is passed through a transverse bore in the middle over the pressure piece and exits after passing through another, vertically extending bore in the sliding surface.

The connection of the oil supply lines is a labor-intensive process.

Presentation of the invention

It is an object of the invention to provide Axialgleitlager and bearing segments for Axialgleitlager, which do not have the above-mentioned disadvantages. Next, a corresponding device to be created.

Another object of the invention is the manufacturability of Axialgleitlagern and / or the To improve manufacturability of bearing segments for thrust bearings, in particular to simplify.

A further object of the invention is to simplify compliance with thickness or height tolerances in the production of axial plain bearings and / or bearing segments for axial plain bearings.

A further object of the invention is to simplify and / or accelerate the assembly of axial plain bearings and / or bearing segments for axial plain bearings. This can be on both new Mondays and on

Assemble mounts as part of repair or maintenance work.

Another object of the invention is to provide Axialgleitlager and / or bearing segments for Axialgleitlager, which have a very low weight.

Another object of the invention is to provide thrust bearings and / or bearing segments for thrust bearings, which consist of very few items.

Another object of the invention is to provide thrust bearings and / or bearing segments for thrust bearings, which are particularly reliable.

Another object of the invention is to provide devices which have at least one such axial sliding bearing and thus solve at least one of the above tasks corresponding task.

At least one of these tasks is performed by a bearing segment, by an axial sliding bearing and by a Device solved with the features of the independent claims.

The bearing segment for an axial sliding bearing has a head region and a foot region, wherein a sliding surface is formed by the head region, which is tiltable with respect to the foot region. It is characterized in that the tiltability of the sliding surface relative to the foot region is made possible by an elastic deformability of the bearing segment. Unlike the known tilting-axial thrust bearings, the Verkippbarkeit the sliding surface is thus not caused by the mobility of two separate and correspondingly shaped parts to each other (cambered pressure piece and planar counterpart), but by the elastic deformability of the bearing segment.

This makes it possible to construct axial plain bearings and bearing segments for axial plain bearings from fewer individual parts. This in turn makes it easier to comply with (total) thickness tolerances for bearing segments. In one embodiment, the material of the

Bearing segment and the geometric configuration of the bearing segment selected such that an elastic deformability of the bearing segment to achieve a predetermined maximum Verkippbarkeit the sliding surface relative to the foot area is possible.

In one embodiment, mold and

Material composition of the bearing segment chosen so that when the maximum loads for which the bearing segment is designed, only elastic deformations of the bearing segment occur. In particular, no plastic deformation of the bearing segment should occur even when these maximum loads occur.

In one embodiment, the bearing segment has an integrally formed intermediate part which is connected to the

Achieving a Verkippbarkeit the sliding surface relative to the foot region is elastically deformable, in particular wherein the tilting of the sliding surface relative to the foot region is effected substantially solely by elastic deformation of the integrally formed intermediate part.

In one embodiment, the foot portion of the support of the bearing segment, in particular the bearing segment is in the installed state in the foot area in contact with at least one further part of the

thrust bearing; In particular, the foot region serves for fastening the bearing segment to at least one further part of the axial sliding bearing, for example to a bearing base element or a base. In one embodiment, the sliding surface of the

(sliding) storage of an object to be stored, typically the storage of a rotatable about a vertical axis object.

In one embodiment, the bearing segment is designed such that the sliding surface is oriented substantially horizontally, the bearing segment is installed in an axial sliding bearing.

In one embodiment, the bearing segment has an intermediate region between the head region and the foot region _ -j_

on, which has an elastic deformability, by which the tiltability of the sliding surface relative to the foot region is made possible.

In one embodiment, the intermediate region is formed waisted.

In one embodiment, the intermediate region is concave in a section perpendicular to the sliding surface.

Such embodiments enable a defined tiltability of the sliding surface relative to the foot region. In one embodiment, the intermediate region has a first section, which adjoins the head region and tapers in the direction of the foot region, with a radius of curvature which increases in the direction of the foot region and possibly is partially constant. In one embodiment, the intermediate region has a first section which, in a section perpendicular to the sliding surface, has a smaller radius of curvature at its end facing the sliding surface than at its end facing the foot region. In one embodiment, the course of the

Radius of curvature of the first section in the direction of the foot region substantially steadily increasing, possibly partially constant, but not decreasing.

In one embodiment, the intermediate region has a second section, which adjoins the foot region and tapers in the direction of the head region, with a curvature radius which increases in the direction of the head region and may be partially constant. In one embodiment, the intermediate region has a second section which, in a section perpendicular to the sliding surface, has a smaller radius of curvature at its end facing the foot region than at its end facing the head region.

In one embodiment, the course of the radii of curvature of the second section in the direction of the head region is substantially steadily increasing, possibly partially constant but not decreasing. By thus forming the first and / or second portion, it is possible to minimize or even practically avoid the occurrence of tensile forces in the intermediate region under loads such as occur when operating an axial sliding bearing. This increases the life. In one embodiment, the bearing segment has a channel extending through the foot region through the head region. This channel can be used for a high-pressure oil supply through the foot region up to the sliding surface and / or for receiving a fastening means by means of which the bearing segment is held. As fasteners, for example, screws come into question.

In one embodiment, the channel extends substantially vertically (in the installed state of the bearing segment in an axial sliding bearing).

In one embodiment, the bearing segment is formed in one piece or two pieces. This allows a simplified manufacturability and a simplified Mountability of the bearing segment can be achieved and a simpler compliance with the total thickness tolerance.

In one embodiment, the intermediate region is formed integrally with the foot region. In one embodiment, the intermediate region is formed integrally with the head region.

In one embodiment, the bearing segment is made in a manufacturing process that involves casting a metal. As a result, a simple manufacturability can be achieved, the bearing segment can be produced in one casting.

In one embodiment, the bearing segment is at least partially made of a cast material.

In one embodiment, the bearing segment consists essentially or completely of a casting material.

Cast material has a relatively small modulus of elasticity, so that a given tilt angle can be effected by relatively small forces, which allows the construction of particularly flexible bearing segments. In one embodiment, the bearing segment has a surface between the sliding surface and the bearing surface opposite the sliding surface, at least a portion of which is machined to obtain a more uniform surface finish; in particular to achieve a lower surface roughness, ie to achieve a smoother surface. For example, the surface may be over-twisted. Such a treatment of Surface reduces cracking and breakage and thus contributes to an increased life.

In one embodiment, the bearing segment is machined at least in the intermediate region in the aforementioned type. In one embodiment, the bearing segment consists at least in part of a tempered steel. By thermal treatment, tempered steel has a higher tensile strength, which leads to a better long-term stability and simplifies the dimensioning of the bearing segment. The bearing segment can be formed for example by turning or by casting. Preferably, at least the intermediate region consists of a tempered steel.

The bearing segments according to the invention can be used in axial sliding bearings.

An axial sliding bearing according to the invention has at least one bearing segment according to the invention.

In one embodiment, the axial sliding bearing has a bearing bottom element to which the bearing segment is fastened by means of a fastening means, wherein the

Bearing segment has a through the foot region to extend through the head portion channel, in which at least a part of the fastening means is arranged. As fasteners such as screws or threaded rods in question. Bearing segments can also be set in other ways, for example by means of clamping claws. In one embodiment of the axial sliding bearing, the fastening means forms a channel which is provided for passing through with a lubricant for a high-pressure lubricant supply of the bearing segment. This channel may be formed by, for example, a central bore in the fastener, for example. Typically, an oil is used as the lubricant.

Axial sliding bearing according to the invention can be used in various devices. For example, in mills or more precisely in drive arrangements for mills; For example, in roll bowl mills, for storing the mill flange of the rolling bowl. Or they can be used in turbines such as Kaplan or Francis turbines for storing the turbine rotor. A device, in particular a machine, according to

Invention has an axial sliding bearing according to the invention.

In one embodiment, the device is a drive arrangement for a mill, in particular for a roller mill, or a turbine, in particular a Kaplan turbine or a Francis turbines.

Further embodiments and advantages will become apparent from the dependent claims and the figures.

Brief description of the drawings

In the following the subject invention will be explained in more detail with reference to embodiments and the accompanying drawings. Show it:

Figure 1 is a known from the prior art Kippsegment-Axialgleitlager in a perspective view of a section.

2 shows a section through an axial sliding bearing, partially schematized;

Fig. 3 is a perspective view of a bearing segment;

4 shows a perspective view of a section through the bearing segment according to FIG. 3; Fig. 5 is a perspective view of a bearing segment;

Fig. 6 is a slightly perspective view of a section through a bearing segment;

Fig. 7 shows a section through a drive arrangement for a roller mill, teilschematisiert.

The reference numerals used in the drawings and their meaning are listed in the list of reference numerals. For the understanding of the invention non-essential parts are not shown in part. The described embodiments are exemplary of the subject invention and have no limiting effect. Ways to carry out the invention

Fig. 1 shows a known from the prior art Kippsegment-Axialgleitlager 50 in a perspective view of a section. Such tilting axial thrust bearings have already been described. The Kippsegment- axial plain bearing 50 has a plurality of bearing segments, which are arranged along a circular path and each consist of a tilting segment 51, a pressure piece 52 and a counterpart 53. The pressure piece 52 is executed cambered on its counterpart 53 facing side, so that a tilting movement of the tilting pad 51 with respect to the vertical is possible.

A rotatably mounted on the Axialgleitlager 50 object such as a mill flange of a

Rolling bowl (not shown in Fig. 1), can be stored by the tiltability of the tilting segment 51 friction and stable, even if the object is unevenly loaded and deformed. On the smooth surface of the Kippsegmente an oil film is provided. To supply oil is not shown in Fig. 1

Provided oil supply line, which must be flexible in order not to leak in the occurring tilting movements of the tilting segment. By means of the invention, an axial sliding bearing can be provided which fulfills all the essential functions of a tilting-pad axial sliding bearing, such as the tilting-pad thrust bearing 50 shown in FIG. 1, but has different types of bearing segments. The basic structure of the axial sliding bearing 20 is similar to that of the Kippsegment- axial plain bearing 50 of FIG. 1, but it has bearing segments 30 which are constructed differently than the bearing segments of the axial sliding bearing 50 of FIG 1. Of course, bearing segments 30 according to the invention can also be used in differently constructed axial plain bearings. The bearing segments 30 have a head region 31, a foot region 33 and a waisted intermediate region 32 therebetween. The sliding surface 35 of the bearing segment is part of the head portion 31 and can be advantageously formed by a bearing material, which is applied for example by flame spraying, arc spraying or casting. In order to counteract a convex deformation of the sliding surface 35 under load and a correspondingly reduced surface pressure, the sliding surface may be concave. The bearing segments 30 are fixed in a bearing bottom element 22 of the axial sliding bearing 20, for example, clamped.

Storing the bearing segments 30 is important to prevent rotation of the bearing segments 30 and also to avoid lateral lifting of the bearing segments 30 of the pad (bearing bottom element 22), as would otherwise occur in the event of heavy loads.

A tilting of the sliding surface 35, which inevitably results during the operation of an axial sliding bearing, is caused by the elastic deformation of the bearing segment 30 reached. The shape of the bearing segment 30 is advantageously chosen so that the forces occurring during operation in the intermediate region 32 cause predominantly compressive stresses and remain substantially in the elastic range and do not lead to plastic deformation of the bearing segment 30.

The elasticity of the material of the bearing segment 30, for example, quantified by the modulus of elasticity, thus allows the tilting of the sliding surface 35 and substantially affects the Verkippbarkeit the sliding surface 35 relative to the foot portion 33. Another Grosse, of the tiltability of the sliding surface 35 opposite the foot region 33 is significantly dependent, is the geometric configuration of the bearing segment 30, in particular where the bearing segment 30 has a (relative to other areas of the bearing segment) small cross-sectional area. The said cross-sectional area is typically to be determined parallel to the sliding surface 35.

In Fig. 2, a reference to the Axialgleitlager radial coordinate R is shown dotted, will be returned to later. A rotational direction of an article to be stored by means of the axial sliding bearing is perpendicular to the bearing segment 30 on the axis of the radial coordinate R and perpendicular to the plane of the drawing.

Fig. 3 shows a perspective view of a bearing segment 30 with a substantially trapezoidal sliding surface 35, with rounded corners. The bearing segment 30 can be created in one piece in a casting process. The Surface 37 in the intermediate region 32 can be advantageously post-processed in order to create a uniform and smooth surface 37, for example, the surface 37 in the intermediate region 32 may be over-twisted. In the foot region 33, the bearing segment 30 bores 38, which serve the attachment of the bearing segment 30 on the bearing bottom element 22 (see Fig. 2). For example, they can accommodate fasteners such as screws. The radial coordinate R is also shown in FIG. 4 shows a perspective view of a section through the bearing segment 30 according to FIG. 3 perpendicular to the sliding surface 35 and approximately through the coordinate axis designated R in FIG. 3. Vertically through the bearing segment 30 extends a channel 36, which can serve the lubrication of the thrust bearing by a lubricant such as oil flows through it. In the case of hydrodynamic lubrication, the lubricant is conveyed by the sliding movement of the object to be stored on the sliding surface 35; in the case of hydrostatic lubrication, the lubricant is conveyed by means of a pump (at high pressure) through the channel 36 onto the sliding surface 35. The provision of the channel 36 (as well as the channel 26 presented below) requires no further, and in particular no flexible lubricant line, as is the case in the prior art.

Fig. 5 shows a perspective view of a

Bearing segment 30 with a substantially round

Sliding surface 35. The structure of the bearing segment 30 is otherwise essentially equal to that of the bearing segment 30

Fig. 4. The intermediate region 32 may be formed-at least in part-substantially rotationally symmetrical.

In principle, various forms of sliding surfaces 35 come into question. Advantageously, the shape is optimized so that a good surface pressure is achieved. Different forms between round and trapezoidal come into question.

Fig. 6 shows a slightly perspective view of a section through a bearing segment 30. In contrast to the in FIGS. 2-5 illustrated one-piece bearing segments 30, the bearing segment 30 shown in Figure 6 is formed in two pieces. it consists of a bearing segment part 30a, which essentially forms the head part 31, and a bearing segment part 30b, which essentially forms the intermediate part 32 and the foot part 33. The parts 30a and 30b are fixed to each other. As a result, different materials adapted to their respective task can be used for the different parts 30a, 30b. For example, can

Part 30b, which forms the intermediate region 32 of a tempered (casting) material and part 30a, which forms the head portion 31, consist of a non-tempered (cast) material. In the right-hand half of FIG. 6, the respective (local) radii of curvature r 1 to r 5 are shown by way of example at several points P 1 to P 5 of the intermediate region 32. From Pl to P3, the radii of curvature increase, and are approximately constant near P3 (approximately cylindrical shape), and of P3 to P5, the radii of curvature decrease again. The corresponding two sections 32a and 32b of the intermediate part 32 are indicated in the left half of FIG. A corresponding geometric design of the

Intermediate area 32 is advantageously also provided in the other embodiments (cf., FIGS. 2 to 5).

By such a geometric configuration of the intermediate region 32, the occurrence of tensile stresses in deformations of the intermediate region 32 with tilting of the sliding surface 35 relative to the foot region 33 can be minimized, which causes an increased service life of the bearing segment 30.

The bearing segment 30 of FIG. 6 has a channel 36 which serves to receive a fastening means 35, for example a screw. On the one hand part 30a of the bearing segment 30 is fastened by the fastening means 35 and on the other hand by fastening means 35 the bearing segment 30 can be fastened to one or more parts of an axial sliding bearing, for example to a bearing base element 22 (cf., Fig. 2).

The fastening means 35 may also, as shown in Fig. 6, also have a channel 26, for example, a central bore. This channel 26 may serve, in the same way as the channel 36 of FIG. 4, the lubrication of the axial sliding bearing.

The foot region 33 can be arranged eccentrically relative to the sliding surface 35 with respect to the direction of rotation of a body to be supported. This can cause a tilting moment can be counteracted, which acts on the bearing segment 30 due to sliding forces in operation, and it can be achieved a better run-in behavior for the oil film. Advantageously, the foot region 33 is offset along the direction of rotation relative to the sliding surface center. In Fig. 6, this can not be seen, since the direction of rotation is almost perpendicular to the plane, with slight tilting against the top right. On the other hand, it can be clearly seen in FIG. 6 that the foot region 33 can be arranged, in relation to a radial coordinate relative to an axial sliding bearing (approximately from right to left in FIG. 6), between the ends of the sliding surface related to this radial coordinate, in particular to the outside (in Fig. 6 to the left), for example in the case of outwardly widening example trapezoidal sliding surfaces 35th

7 shows a partial schematic of a section through a drive arrangement 1 for a roller mill, which has an axial sliding bearing 20 according to the invention and thus at least one bearing segment 30 according to the invention.

It should be noted that it may well be provided to use one or more known from the prior art bearing segments and one or more bearing segments 30 according to the invention in a thrust bearing together. This can occur, for example, by replacing individual defective bearing segments of an axial sliding bearing by bearing segments of the invention. Axially sliding bearing 20 rotatably axially supports a mill flange 2, which is driven by an electric motor 5 via a drive flange 14 and a gear arrangement 4 formed by a planetary gear. The corresponding heavy-duty drive arrangement is arranged in a housing 6 which has two sub-housings 6a (containing the electric motor 5) and 6b (containing the gear arrangement 4) and a base plate 6c mounted on a foundation 3. The electric motor 5 has a stator 8 and a bearing by means of two bearings 9, 10 rotor 7, which is connected to the sun gear of the planetary gear clutch-free, which has a ring gear 12 and one or more planetary gears 13. The axis of rotation of the mill flange, the central axis of the planetary gear and the rotor axis of the electric motor 5 coincide with the same vertical axis A.

Of course, axial slide bearings according to the invention can also be used in drive assemblies of a different design and also in devices of a different kind. The proposed in the context of the invention Axialgleitlager typically have a diameter between 1 m and 5 m, a maximum of between 0.5 m and 10 m.

The bearing segments contemplated by the invention typically have a height of 15 cm to 25 cm, a maximum of 10 cm to 40 cm, and a sliding surface of typically 20 cm to 70 cm, a maximum of 10 cm to 100 cm, length extension. LIST OF REFERENCE NUMBERS

1 drive arrangement for a mill, in particular for a roller mill

2 mill flange

3 foundation

4 gear arrangement, planetary gear

5 electric motor 6 housing

6a lower part housing βb upper part housing

6c floor element, floor plate element

7 rotor 8 stator

9 bearings

10 bearings

11 sun wheel

12 ring gear 13 planetary gear

14 output flange

20 axial sliding bearings

22 bearing bottom element

25 fasteners 26 channel

30 bearing segment

30a bearing segment part

30b bearing segment part 31 head area

32 intermediate area 32a section

32b section

33 foot area 35 sliding surface

36 channel

37 surface

38 bore

50 Tilting axial thrust bearings 51 Tilting segment

52 pressure piece

53 counterpart

A axis, vertical P1, P2, P3, P4, P5 points rl _f r2, r3, r4, r5 radii of curvature

R radial coordinate

Claims

A bearing segment (30) for an axial sliding bearing (20) comprising a head portion (31) and a foot portion (33), wherein a sliding surface (35) is formed by the head portion (31) which is tiltable with respect to the foot portion (31) , characterized in that the Verkippbarkeit the sliding surface (35) relative to the foot region (31) by an elastic deformability of the bearing segment (30) is made possible.

Second bearing segment (30) according to claim 1, characterized in that between the head portion (31) and the foot portion (33) has an intermediate portion (32) having an elastic deformability, by the tiltability of the sliding surface (35) opposite the foot area (31) is possible.

3. bearing segment (30) according to claim 2, characterized in that the intermediate region (32) is formed waisted.

4. bearing segment (30) according to claim 2 or claim 3, characterized in that the intermediate region (32) adjacent to the head portion (31) and in the direction of the foot portion (33) tapered first portion (32 a) with in the direction of the foot area (31) increasing and possibly partially constant radius of curvature (rl, r2, r3).

5. bearing segment (30) according to one of claims 2 to 4, characterized in that the intermediate region (32) adjacent to the foot portion (33) and in the direction of the head portion (31) tapered second portion (32b) with in the direction of Head region (31) increasing and possibly partially constant radius of curvature (R5, R4, R3).

6. bearing segment (30) according to one of the preceding claims, characterized in that it has a through the foot region (33) to the head region (31) extending channel (36).

7. bearing segment (30) according to one of the preceding claims, characterized in that it is formed in one piece or two pieces.

8. bearing segment (30) according to one of the preceding claims, characterized in that it consists at least partly of a casting material.

9. bearing segment (30) according to one of the preceding claims, characterized in that it between the sliding surface (35) and the sliding surface opposite End of the bearing segment (30) has a surface (37), of which at least one part is machined to achieve a more uniform surface finish.

10. bearing segment (30) according to one of the preceding claims, characterized in that it consists at least in part of a tempered steel.

11. Axialgleitlager (20) comprising at least one bearing segment (30) according to one of the preceding

Claims .

12. Axialgleitlager (20) according to claim 11, characterized in that it comprises a bearing bottom element (22) on which the bearing segment (30) by means of a fastening means (35) is fixed, wherein the bearing segment (30) through the foot area ( 33) to extending through the head portion (31) extending channel (36), in which at least a part of the fastening means (25) is arranged.

13. Axialgleitlager (20) according to claim 12, characterized in that the fastening means (25) forms a channel (26) which is provided for flowing through with a lubricant for a high-pressure lubricant supply of the bearing segment (30).

14. Device (1) comprising an axial sliding bearing (20) according to one of claims 11 to 13.

15. Device (1) according to claim 14, characterized in that it comprises a drive arrangement (1) for a mill, in particular a drive arrangement (1) for a roller mill (1), or a turbine, in particular a Kaplan turbine or a Francis Trubin is,