Title of Invention	"SLEWING RING "
Abstract	The slewing ring (1) comprises a retainer (6) in metal of a certain hardness substantially equal to the hardness of rings (3,4), which is arranged between two the rings (3,4), the retainer is integral in rotation with rolling elements (2), and holds these elements regularly spaced apart in raceway (5). At least one contact ring (7a,7b,7c,7d) made of a material of different hardness to the hardness of the rings (3,4) and of the retainer (6), is arranged between two members formed by retainer (6) and by one of the two rings (3,4), the contact ring prevents any direct contact between these two members (3,6; 4,6) and is fixed to one of these two members (3, 6;4,6) and is able to come into contact with the other (6,3,-6,4) .

Title of Invention

"SLEWING RING "

Abstract

The slewing ring (1) comprises a retainer (6) in metal of a certain hardness substantially equal to the hardness of rings (3,4), which is arranged between two the rings (3,4), the retainer is integral in rotation with rolling elements (2), and holds these elements regularly spaced apart in raceway (5). At least one contact ring (7a,7b,7c,7d) made of a material of different hardness to the hardness of the rings (3,4) and of the retainer (6), is arranged between two members formed by retainer (6) and by one of the two rings (3,4), the contact ring prevents any direct contact between these two members (3,6; 4,6) and is fixed to one of these two members (3, 6;4,6) and is able to come into contact with the other (6,3,-6,4) .

Full Text	2 The present invention pertains to a slewing ring, in particular a ball bearing. A slewing ring is known of the type comprising rolling elements, two concentric metal rings having a predetermined hardness, one inner and one outer, mobile in rotation relative to one another and defining a raceway for said rolling elements, and a retainer made of a metal having a hardness substantially equal to the hardness of the rings, the retainer being arranged between the two rings, and being integral in rotation with the rolling elements, said retainer holding the rolling elements regularly spaced apart in the raceway. A major disadvantage of this type of ring is that during the rotation movement, the retainer comes into contact with the rings and undergoes wear due to resulting friction. This wear leads firstly to pollution of the lubricant whose properties are thereby weakened, and secondly to reduced lifetime of the rings. On this account solutions have been put forward : heat and/or chemical treatment of the surface of the rings at the point of contact with the retainer (for example US 2001/48781 orEPO 531 082), because this treatment should not be applied to the raceway, it is difficult to implement especially with large diameter rings; or providing the retainer with porous elements containing a lubricant (for example GB 1 396 220 and JP 10 089 365), which enormously complicates the fabrication of the retainer. The problem raised is to obtain a slewing ring in which the pollution of the lubricant is highly reduced and whose lifetime is considerably increased. The solution to this problem is a slewing ring of the aforesaid type comprising at least one circular contact ring made of a material having a hardness different from the hardness of the rings and the hardness of the retainer, said contact ring being housed in a groove made in one of the two 2A rings, and the retainer coming into contact against said circular contact element, preventing any direct contact between the retainer and the ring in which the groove is made. Therefore, the use of a contact ring according to the invention makes possible to easily produce slewing rings, with economical advantages. The wearing of their component elements of the slewing ring of the invention is considerably reduced (even eliminated). On this account, there are no more metal particles to pollute the lubricant (which therefore remains its properties longer) Consequently the time delay between two periodic lubrications of the slewing ring can be increased and the risk of retainer rupture is reduced (even eliminated). In addition, the noise generated by the slewing ring is strongly reduced. This is the case even with large diameter rings (at least 1m diameter). Accordingly the present invention provides a slewing ring comprising rolling elements, two concentric metal rings having a predetermined hardness, one inner and one outer, mobile in rotation relative to one another and defining a raceway for said rolling elements, and a retainer made of a metal having a hardness substantially equal to the hardness of the rings, the retainer being arranged between the two rings, and being integral in rotation with the rolling elements, said retainer holding the rolling elements regularly spaced apart in the raceway, characterized in that it comprises at least one circular contact ring made of a material having a hardness different from the hardness of the rings and the hardness of the retainer, said contact ring being housed in a groove made in one of the two rings, and the retainer coming in contact against said circular contact ring, preventing any direct contact between the retainer and the ring in which the groove is made. Other particularities and advantages will be understood from the following detailed description of a particular embodiment given as a non-restrictive example and illustrated by the appended drawing. 2B The single figure shows a partial axial-sectional view of a slewing ring according to the present invention. As can be seen in the figure, in known manner, a slewing ring 1 comprises : rolling elements 2 (in this example ball elements 2), two concentric rings 3, 4 (one inner 3 and one outer 4), in steel, mobile in rotation relative to one another and forming a raceway 5 for ball elements 2, and a retainer 6 in steel arranged between the two rings 3, 4, extending in the axial direction of slewing ring 1 on either side of the ball elements 2, the retainer being integral in rotation with the ball elements and holding them regularly spaced apart in the raceway 5. Also, the slewing ring 1 comprises contact elements also called contact rings 7a, 7b, 7c, 7d is arranged between two members formed by retainer 6 and by one of the two rings 3, 4. 3 The contact ring prevents any direct contact between these two members 3 or 4, 6, and fixed to one of these two members 3 or 4, 6 and is fixed to one of these two members 3 or 4, 6 and comes into contact with the other. Here the slewing ring 1 contains four contact elements (contact rings) 7a, 7b, 7c, 7d : - two 7a, 7b are arranged between the retainer 6 and the outer ring 4, prevent any direct contact between these two members 4, 6, and are fixed to the outer ring 4 and come into contact with retainer 6; and - two 7c, 7d are arranged between retainer 6 and inner ring 3, prevent any direct contact between these two members 3, 6, and are fixed to the inner ring 3 and come into contact with retainer 6. As can be seen, the contact elements 7a, 7b attached to the outer ring 4 are arranged in axial direction on either sides of the raceway 5, as well as the contact elements 7c, 7d which are attached to inner ring 3. This substantially symmetrical arrangement of the four contact elements 7a, 7b, 7c, 7d in relation to raceway 5 provides perfect equilibrium of slewing ring 1 with absolutely no point of contact between retainer 6 and either one of the two rings 3, 4. This particular configuration is of particular interest for slewing ring 1 whose rolling elements 2 describe a circle of large diameter (for example at least lm, even 1.5m or over), and especially for rings used to orient devices subjected to strong pressures such as the slewing ring 1 used to direct blades in relation to the rotor of a wind turbine nacelle according to wind force. In the present example, the contact elements 7a, 7b, 7c, 7d are circular rings force fitted into corresponding grooves 8 made in concentric rings 3, 4. As can be seen in the figure, the cross-section of these circular rings may be trapezoidal, rectangular or semi-circular. The circular rings are made of a compact material, i.e. non-porous. Preferably they are made of a single piece. In conventional manner the slewing ring 1 also includes seals to retain the lubricant within the housing defined by 4 the two rings 3, 4 and in which the ball elements 2 and retainer 6 are confined. Slewing ring 1 may therefore include in particular lipped seals denoted 9, 10 in figure 1, each comprising a base 5 9a,10a, inserted in a corresponding notch 11,12 of respective ring 3, 4, and a lip 9b, 10b bearing upon a corresponding transverse surface 14,13 of the other ring 4,3. Evidently, the present invention is not limited to the above-described embodiment. 10 It would be possible for example to have contact elements solely between' the inner ring and the retainer or between the outer ring and the retainer, although this would give the present invention much lesser efficacy. It would also be possible not to have any contact element 15 (contact ring) on either side of the raceway (in axial direction)- It would also be possible for the contact elements to be fixed to the retainer. It would also be possible for the contact elements to be 20 made of any polymer material other than polyamide, for example of polytetrafluoroethylene or polyimide. These contact elements could also be made of non-ferrous metal, for example a copper or bronze alloy. It would also be possible to use other fixation means for 25 the contact elements depending upon the constituent materials: they could be fixed chemically {bonded for example), metallurgically {welded or brazed for example) or mechanically {clipped or bolted for example). It would also be possible to use rolling elements other 30 than ball elements, for example rollers. 5 WE CLAIM: 1. Slewing ring (1) comprising rolling elements (2), two concentric metal rings (3, 4) having a predetermined hardness, one inner (3) and one outer (4), mobile in rotation relative to one another and defining a raceway (5) for said rolling elements (2), and a retainer (6) made of a metal having a hardness substantially equal to the hardness of the rings (3, 4), the retainer being arranged between the two rings (3, 4), and being integral in rotation with the rolling elements (2), said retainer holding the rolling elements regularly spaced apart in the raceway (5), characterized in that it comprises at least one circular contact ring (7a, 7b, 7c, 7d) made of a material having a hardness different from the hardness of the rings (3, 4) and the hardness of the retainer (6), said contact ring being housed in a groove (8) made in one of the two rings (3, 4), and the retainer (6) coming in contact against said circular contact ring, preventing any direct contact between the retainer (6) and the ring (3, 4) in which the groove (8) is made. 2. Slewing ring (1) as claimed in claim 1, wherein the rings (3, 4) and retainer (6) are made of steel, and the contact rings (7a, 7b, 7c, 7d) are made of a non-ferrous material. 3. Slewing ring (1) as claimed in claim 1 or 2, wherein each of the inner ring (3) and outer ring (4) comprises at least one groove (8) in which a contact ring (7a, 7b, 7c, 7d) is housed. 4. Slewing ring (1) as claimed in any of claims 1 to 3, wherein at least one groove (8), in which a contact ring (7a, 7b, 7c, 7d) is housed, is formed on either side of the raceway (5). 6 5. Slewing ring (1) as claimed in any of claims 1 to 4, wherein the contact ring (7a, 7b, 7c, 7d) has a trapezoidal, rectangular or semi-circular cross-section. 6. Slewing ring as claimed in any of claims 1 to 5, wherein each contact ring (7a, 7b, 7c, 7d) is made of a compact, non-porous material. 7. Slewing ring (1) as claimed in any of claims 1 to 6, wherein each contact ring (7a, 7b, 7c, 7d) is made of a non-ferrous metal, for example, a copper or bronze alloy. 8. Slewing ring (1) as claimed in any of claims 1 to 6, wherein each contact ring (7a, 7b, 7c, 7d)is made of polymer, for example polyamide or polytetrafluoroethylene. 9. Slewing ring (1) as claimed in any of claims 1 to 8, wherein the contact ring (7a, 7b, 7c, 7d) is mechanically, metallurgical ly or chemically fixed to the corresponding ring (3, 4). 10. Slewing ring (1) as claimed in any of claims 1 to 9, wherein the rolling elements (2) are ball elements (2). 11. Slewing ring, substantially as herein described, particularly with reference to the accompanying drawing. The slewing ring (1) comprises a retainer (6) in metal of a certain hardness substantially equal to the hardness of rings (3,4), which is arranged between two the rings (3,4), the retainer is integral in rotation with rolling elements (2), and holds these elements regularly spaced apart in raceway (5). At least one contact ring (7a,7b,7c,7d) made of a material of different hardness to the hardness of the rings (3,4) and of the retainer (6), is arranged between two members formed by retainer (6) and by one of the two rings (3,4), the contact ring prevents any direct contact between these two members (3,6; 4,6) and is fixed to one of these two members (3, 6;4,6) and is able to come into contact with the other (6,3,-6,4) .

Full Text

2
The present invention pertains to a slewing ring, in particular a ball bearing.
A slewing ring is known of the type comprising rolling elements, two concentric metal rings having a predetermined hardness, one inner and one outer, mobile in rotation relative to one another and defining a raceway for said rolling elements, and a retainer made of a metal having a hardness substantially equal to the hardness of the rings, the retainer being arranged between the two rings, and being integral in rotation with the rolling elements, said retainer holding the rolling elements regularly spaced apart in the raceway.
A major disadvantage of this type of ring is that during the rotation movement, the retainer comes into contact with the rings and undergoes wear due to resulting friction. This wear leads firstly to pollution of the lubricant whose properties are thereby weakened, and secondly to reduced lifetime of the rings.
On this account solutions have been put forward : heat and/or chemical treatment of the surface of the rings at the point of contact with the retainer (for example US 2001/48781 orEPO 531 082), because this treatment should not be applied to the raceway, it is difficult to implement especially with large diameter rings; or providing the retainer with porous elements containing a lubricant (for example GB 1 396 220 and JP 10 089 365), which enormously complicates the fabrication of the retainer.
The problem raised is to obtain a slewing ring in which the pollution of the lubricant is highly reduced and whose lifetime is considerably increased.
The solution to this problem is a slewing ring of the aforesaid type comprising at least one circular contact ring made of a material having a hardness different from the hardness of the rings and the hardness of the retainer, said contact ring being housed in a groove made in one of the two

2A rings, and the retainer coming into contact against said circular contact element, preventing any direct contact between the retainer and the ring in which the groove is made.
Therefore, the use of a contact ring according to the invention makes possible to easily produce slewing rings, with economical advantages. The wearing of their component elements of the slewing ring of the invention is considerably reduced (even eliminated). On this account, there are no more metal particles to pollute the lubricant (which therefore remains its properties longer) Consequently the time delay between two periodic lubrications of the slewing ring can be increased and the risk of retainer rupture is reduced (even eliminated). In addition, the noise generated by the slewing ring is strongly reduced. This is the case even with large diameter rings (at least 1m diameter).
Accordingly the present invention provides a slewing ring comprising rolling elements, two concentric metal rings having a predetermined hardness, one inner and one outer, mobile in rotation relative to one another and defining a raceway for said rolling elements, and a retainer made of a metal having a hardness substantially equal to the hardness of the rings, the retainer being arranged between the two rings, and being integral in rotation with the rolling elements, said retainer holding the rolling elements regularly spaced apart in the raceway, characterized in that it comprises at least one circular contact ring made of a material having a hardness different from the hardness of the rings and the hardness of the retainer, said contact ring being housed in a groove made in one of the two rings, and the retainer coming in contact against said circular contact ring, preventing any direct contact between the retainer and the ring in which the groove is made.
Other particularities and advantages will be understood from the following detailed description of a particular embodiment given as a non-restrictive example and illustrated by the appended drawing.

2B
The single figure shows a partial axial-sectional view of a slewing ring according to the present invention.
As can be seen in the figure, in known manner, a slewing ring 1 comprises :
rolling elements 2 (in this example ball elements 2),
two concentric rings 3, 4 (one inner 3 and one outer 4), in steel, mobile in rotation relative to one another and forming a raceway 5 for ball elements 2, and
a retainer 6 in steel arranged between the two rings 3, 4, extending in the axial direction of slewing ring 1 on either side of the ball elements 2, the retainer being integral in rotation with the ball elements and holding them regularly spaced apart in the raceway 5.
Also, the slewing ring 1 comprises contact elements also called contact rings 7a, 7b, 7c, 7d is arranged between two members formed by retainer 6 and by one of the two rings 3, 4.

3 The contact ring prevents any direct contact between these two members 3 or 4, 6, and fixed to one of these two members 3 or 4, 6 and is fixed to one of these two members 3 or 4, 6 and comes into contact with the other.
Here the slewing ring 1 contains four contact elements (contact rings) 7a, 7b, 7c, 7d :
- two 7a, 7b are arranged between the retainer 6 and the outer ring 4, prevent any direct contact between these two members 4, 6, and are fixed to the outer ring 4 and come into contact with retainer 6; and
- two 7c, 7d are arranged between retainer 6 and inner ring 3, prevent any direct contact between these two members 3, 6, and are fixed to the inner ring 3 and come into contact with retainer 6.
As can be seen, the contact elements 7a, 7b attached to the outer ring 4 are arranged in axial direction on either sides of the raceway 5, as well as the contact elements 7c, 7d which are attached to inner ring 3.
This substantially symmetrical arrangement of the four contact elements 7a, 7b, 7c, 7d in relation to raceway 5 provides perfect equilibrium of slewing ring 1 with absolutely no point of contact between retainer 6 and either one of the two rings 3, 4. This particular configuration is of particular interest for slewing ring 1 whose rolling elements 2 describe a circle of large diameter (for example at least lm, even 1.5m or over), and especially for rings used to orient devices subjected to strong pressures such as the slewing ring 1 used to direct blades in relation to the rotor of a wind turbine nacelle according to wind force.
In the present example, the contact elements 7a, 7b, 7c, 7d are circular rings force fitted into corresponding grooves 8 made in concentric rings 3, 4. As can be seen in the figure, the cross-section of these circular rings may be trapezoidal, rectangular or semi-circular. The circular rings are made of a compact material, i.e. non-porous. Preferably they are made of a single piece.
In conventional manner the slewing ring 1 also includes seals to retain the lubricant within the housing defined by

4
the two rings 3, 4 and in which the ball elements 2 and retainer 6 are confined.
Slewing ring 1 may therefore include in particular lipped
seals denoted 9, 10 in figure 1, each comprising a base
5 9a,10a, inserted in a corresponding notch 11,12 of respective
ring 3, 4, and a lip 9b, 10b bearing upon a corresponding
transverse surface 14,13 of the other ring 4,3.
Evidently, the present invention is not limited to the above-described embodiment. 10 It would be possible for example to have contact elements solely between' the inner ring and the retainer or between the outer ring and the retainer, although this would give the present invention much lesser efficacy.
It would also be possible not to have any contact element 15 (contact ring) on either side of the raceway (in axial direction)-
It would also be possible for the contact elements to be fixed to the retainer.
It would also be possible for the contact elements to be
20 made of any polymer material other than polyamide, for example
of polytetrafluoroethylene or polyimide. These contact
elements could also be made of non-ferrous metal, for example
a copper or bronze alloy.
It would also be possible to use other fixation means for
25 the contact elements depending upon the constituent materials:
they could be fixed chemically {bonded for example),
metallurgically {welded or brazed for example) or mechanically
{clipped or bolted for example).
It would also be possible to use rolling elements other 30 than ball elements, for example rollers.

5
WE CLAIM:
1. Slewing ring (1) comprising rolling elements (2), two concentric metal rings (3, 4) having a predetermined hardness, one inner (3) and one outer (4), mobile in rotation relative to one another and defining a raceway (5) for said rolling elements (2), and a retainer (6) made of a metal having a hardness substantially equal to the hardness of the rings (3, 4), the retainer being arranged between the two rings (3, 4), and being integral in rotation with the rolling elements (2), said retainer holding the rolling elements regularly spaced apart in the raceway (5), characterized in that it comprises at least one circular contact ring (7a, 7b, 7c, 7d) made of a material having a hardness different from the hardness of the rings (3, 4) and the hardness of the retainer (6), said contact ring being housed in a groove (8) made in one of the two rings (3, 4), and the retainer (6) coming in contact against said circular contact ring, preventing any direct contact between the retainer (6) and the ring (3, 4) in which the groove (8) is made.
2. Slewing ring (1) as claimed in claim 1, wherein the rings (3, 4) and retainer (6) are made of steel, and the contact rings (7a, 7b, 7c, 7d) are made of a non-ferrous material.
3. Slewing ring (1) as claimed in claim 1 or 2, wherein each of the inner ring (3) and outer ring (4) comprises at least one groove (8) in which a contact ring (7a, 7b, 7c, 7d) is housed.
4. Slewing ring (1) as claimed in any of claims 1 to 3, wherein at least one groove (8), in which a contact ring (7a, 7b, 7c, 7d) is housed, is formed on either side of the raceway (5).

6
5. Slewing ring (1) as claimed in any of claims 1 to 4, wherein the contact ring (7a, 7b, 7c, 7d) has a trapezoidal, rectangular or semi-circular cross-section.
6. Slewing ring as claimed in any of claims 1 to 5, wherein each contact ring (7a, 7b, 7c, 7d) is made of a compact, non-porous material.
7. Slewing ring (1) as claimed in any of claims 1 to 6, wherein each contact ring (7a, 7b, 7c, 7d) is made of a non-ferrous metal, for example, a copper or bronze alloy.
8. Slewing ring (1) as claimed in any of claims 1 to 6, wherein each contact ring (7a, 7b, 7c, 7d)is made of polymer, for example polyamide or polytetrafluoroethylene.
9. Slewing ring (1) as claimed in any of claims 1 to 8, wherein the contact ring (7a, 7b, 7c, 7d) is mechanically, metallurgical ly or chemically fixed to the corresponding ring (3, 4).
10. Slewing ring (1) as claimed in any of claims 1 to 9, wherein the rolling elements (2) are ball elements (2).
11. Slewing ring, substantially as herein described, particularly with reference to the accompanying drawing.
The slewing ring (1) comprises a retainer (6) in metal of a certain hardness substantially equal to the hardness of rings (3,4), which is arranged between two the rings (3,4), the retainer is integral in rotation with rolling elements
(2), and holds these elements regularly spaced apart in raceway (5). At least one contact ring (7a,7b,7c,7d) made of a material of different hardness to the hardness of the rings
(3,4) and of the retainer (6), is arranged between two members formed by retainer (6) and by one of the two rings (3,4), the contact ring prevents any direct contact between these two members (3,6; 4,6) and is fixed to one of these two members
(3, 6;4,6) and is able to come into contact with the other
(6,3,-6,4) .

Documents:

00476-kol-2004-abstract.pdf

00476-kol-2004-claims.pdf

00476-kol-2004-correspondence.pdf

00476-kol-2004-description(complete).pdf

00476-kol-2004-drawings.pdf

00476-kol-2004-form-1.pdf

00476-kol-2004-form-18.pdf

00476-kol-2004-form-2.pdf

00476-kol-2004-form-3.pdf

00476-kol-2004-form-5.pdf

00476-kol-2004-g.p.a.pdf

00476-kol-2004-letters patent.pdf

00476-kol-2004-priority document others.pdf

00476-kol-2004-priority document.pdf

476-KOL-2004-FORM 27.pdf

476-kol-2004-granted-abstract.pdf

476-kol-2004-granted-claims.pdf

476-kol-2004-granted-description (complete).pdf

476-kol-2004-granted-drawings.pdf

476-kol-2004-granted-form 2.pdf

476-kol-2004-granted-specification.pdf

476-kol-2004-priority document.pdf

476-kol-2004-translated copy of priority document.pdf

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Patent Number

201430

Indian Patent Application Number

476/KOL/2004

PG Journal Number

07/2007

Publication Date

16-Feb-2007

Grant Date

16-Feb-2007

Date of Filing

11-Aug-2004

Name of Patentee

DEFONTAINE

Applicant Address

RUE SAINT ELOI, 85530 LA BRUFFIERE,

Inventors:

#	Inventor's Name	Inventor's Address
1	TERVE DANIEL	LA COURNEUVE 44230 ST SEBASTIAN S/LOIRE,
2	CHATRY DIDIER	ST SYMPHORIEN 85530 LA BRUFFIERE FRANCE.

PCT International Classification Number

F 16 C 33/30

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	N 03 10220	2003-08-27	France