GB2031091A

GB2031091A – Conduit swivel joint
– Google Patents

GB2031091A – Conduit swivel joint
– Google Patents
Conduit swivel joint

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Publication number
GB2031091A

GB2031091A
GB7922014A
GB7922014A
GB2031091A
GB 2031091 A
GB2031091 A
GB 2031091A
GB 7922014 A
GB7922014 A
GB 7922014A
GB 7922014 A
GB7922014 A
GB 7922014A
GB 2031091 A
GB2031091 A
GB 2031091A
Authority
GB
United Kingdom
Prior art keywords
sleeve
swivel joint
bearing
conduit
support
Prior art date
1978-09-28
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)

Granted

Application number
GB7922014A
Other versions

GB2031091B
(en

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Aeroquip AG

Original Assignee
Aeroquip AG
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
1978-09-28
Filing date
1979-06-25
Publication date
1980-04-16

1979-06-25
Application filed by Aeroquip AG
filed
Critical
Aeroquip AG

1980-04-16
Publication of GB2031091A
publication
Critical
patent/GB2031091A/en

1983-01-19
Application granted
granted
Critical

1983-01-19
Publication of GB2031091B
publication
Critical
patent/GB2031091B/en

Status
Expired
legal-status
Critical
Current

Links

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Discuss

Classifications

F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING

F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL

F16L—PIPES; JOINTS OR FITTINGS FOR PIPES; SUPPORTS FOR PIPES, CABLES OR PROTECTIVE TUBING; MEANS FOR THERMAL INSULATION IN GENERAL

F16L27/00—Adjustable joints, Joints allowing movement

F16L27/08—Adjustable joints, Joints allowing movement allowing adjustment or movement only about the axis of one pipe

F16L27/0804—Adjustable joints, Joints allowing movement allowing adjustment or movement only about the axis of one pipe the fluid passing axially from one joint element to another

F16L27/0808—Adjustable joints, Joints allowing movement allowing adjustment or movement only about the axis of one pipe the fluid passing axially from one joint element to another the joint elements extending coaxially for some distance from their point of separation

F16L27/0812—Adjustable joints, Joints allowing movement allowing adjustment or movement only about the axis of one pipe the fluid passing axially from one joint element to another the joint elements extending coaxially for some distance from their point of separation with slide bearings

F16L27/082—Adjustable joints, Joints allowing movement allowing adjustment or movement only about the axis of one pipe the fluid passing axially from one joint element to another the joint elements extending coaxially for some distance from their point of separation with slide bearings having axial sealing

Description

1 GB 2 031091 A 1
SPECIFICATION
Conduit swivel joint The invention pertains to a swivel joint for 70 incorporation into a high pressure rigid con duit system wherein the joint permits limited angular conduit deformation, and relative rota tive movement, between conduits.
Swivel joints are utilized in rigid conduit systems wherein conduits connected in end to-end relationship require relative conduit movement either in an angular or rotative manner and where the integrity of the conduit system is to be preserved during such defor mation. In the past, swivel joints have incor porated ball and socket arrangements, elas tomeric seals, rotative seals and other me chanical devices which permit the intercon nected conduits limited relative movement.
Typical examples of patented conduit joints are shown in my Patent Nos. 3,390,899; 3,680,895; 3,734,546 and 3,853,337.
In the installation of offshore oil and gas drilling installations rigid conduits are used to extend between the drilling platform and the submerged wellhead, and swivel joints are often used ifi such systems to accommodate misalignments, water current effects, torque forces, and other factors imposing stress upon the conduit systems. As such joints are often located at hundreds of feet below the water surface the exterior of the joint is subjected to very high fluid pressure, while the joint inter iors communicating with a well, may also be subjected to very high pressures as high as 6,000 psi.
Swivel joints presently available for use under such adverse conditions have not prov en as dependable and rugged as desired, It will be appreciated that a swivel joint located several hundred feet below the water surface must have very high reliability characteristics under adverse operating conditions, and it is an object of the invention to provide a conduit swivel joint capable of meeting the prerequs ites of such applications.
It is another object of the invention to provide a conduit swivel joint for use in high pressure rigid conduit systems wherein the joint is capable of maintaining its fluid integ rity with respect to both internal and external pressures under limited angular associated conduit deflection, and under associated con duit rotative forces.
Another object of the invention is to provide a conduit swivel joint utilizing elastomeric assembled components wherein initial relative conduit rotative forces are absorbed within an elastomer, and where greater relative rotative forces are absorbed in rotative bearing struc ture.
A further object of the invention is to pro vide a conduit swivel joint utilizing an elas tomeric bearing wherein initial torque forces 130 between associated conduits deform the elastomer while higher torque forces rotate the entire bearing structure.
Another object of the invention is to provide a conduit swivel joint utilizing thrust bearings and sealing means wherein failure of the thrust bearings will not affect sealing characteristics of the joint, and wherein redundant seals are utilized for sealing against internal and external fluid pressures.
In the practice of the invention a body affixed to a fluid conduit supports a tubular sleeve to which another conduit is attached. The sleeve is supported upon an annular elastomeric bearing assembly, and an annular retainer adjustably mounted upon the body frictionally maintains the sleeve and bearing assembly assembled to the body. A lost motion splined relationship between the sleeve and elastomeric bearing permits initial torque forces imposed upon the sleeve to deform the elastomer without rotating the bearing assembly upon thrust bearings mounted upon the body and retainer. However, major rotational deflection of the sleeve relative to the bearing will produce a positive rotation of the entire bearing assembly upon its thrust bearings to prevent overstressing of the elastomer.
The elastomer bearing uses a plurality of annular conical rings or washers embedded into the elastomer material which aids in keeping the elastomer centered with respect to the axis of joint rotation, and such conical rings add stiffness to the elastomer relative to axial angular deformation while aiding the torsion absorbing characteristics of the elastomer.
The aforementioned objects and advantages will be appreciated from the following descrip- tion and accompanying drawings wherein:
Figure 1 is a diametrical, sectional, elevational view of a conduit swivel joint in accord with the invention, Figure 2 is an elevational, sectional view as taken along Section 11-11 of Fig. 1, Figure 3 is an elevational view of the elastomer bearing assembly, per se, the upper half being shown in section, and Figure 4 is an elevational sectional view of the bearing assembly as taken along Section IV-IV of Fig. 3.
With reference to Fig. 1, the general relationship of the major components of a conduit swivel joint is accord with the invention will be understood. The swivel joint is generally indicated at 10, and is usually installed by being interposed between a pair of rigid conduits, represented at 12 and 14. The conduits are attached to the joint by weld beads 16.
The joint includes a body 18 to which an annular retainer 20 is mounted by a plurality of threaded bolts 22. A tubular sleeve 24 is maintained within the body by the retainer 20, and the elastomeric bearing assembly is generally indicated at 26. The conduit 12 is 2 GB2031 091A 2 attached to the body 18, while the conduit 14 is welded to the free end of the sleeve 24 as will be appreciated from Fig. 1.
The body 18 is provided with a bore 28, concentric and communicating with the bore of conduit 12, which opens into a recess 30. The recess 30 includes a pair of O-ring seals 32, and an annular wiper ring 34 for cooperation with other joint components as will be later noted. An annular conical thrust bearing 36 is mounted upon the recess surface 38, and this thrust bearing is in axial opposed relationship to a similar thrust bearing mounted upon retainer 20.
The retainer 20 is also of an annular configuration including an inner opening 40, an oblique radially extending surface 42 upon which thrust bearing 44 is mounted, and the retainer includes an axially extending lip which is sealingly engaged by O-rings 32, Fig. 1. The threaded bolts 22 extend through openings 45 defined in the retainer for threaded engagement with threaded bores 46 defined in body 18, and a shoulder 48 defined upon the retainer is in spaced opposed axial relationship to a body defined shoulder 40 separated by a preload washer or spacer 52. The preload bolts 22 are provided with heads 54 and are preferably of the Allen sockettype.
The bearings 36 and 44 may be of the glass filled Teflon type, and the retainer 20 is provided with a plurality of annular grooves intersecting the cylindrical opening 40 in which annular lip seals 56 and 58 are located as is the elastomeric seal 60.
The sleeve 24 is of a tubular configuration having an internal bore 62 substantially identical to that of body bore 28, or slightly smaller, and the sleeve includes an integral radially extending flange 64 having a conical bearing surface 66 which is engaged by the bearing 36 and the ring 34, Fig. 1. The nose of the sleeve is provided with a plurality of circurnferentially spaced spline projections 68, 110 Figs. 1 and 2, and the central region of the exterior surface of the sleeve is formed with a cylindrical surface 69, while the flange 64 includes the flat radial surface 70 for engage- ment by the elastomer bearing assembly 26, as will be described.
The annular elastomer bearing assembly construction will be appreciated from Figs. 1 and 3. This assembly includes a first annular collar 72 in spaced axial relationship to a second collar 74, and an elastomeric material 76, such as rubber, neoprene, urethane, or the like, is bonded to the collars 72 and 74. The collar 72 includes a flat radial surface 78 for engaging the sleeve flange surface 70, and the threaded bore 80 permits a plurality of screws 82 extending through axial openings defined iri the flange 64 to affix the collar to the flange. The collar 72 includes an obliquely disposed radially extending surface 84, and convex surface 86 for aiding in the bonding and assembly with the elastomeric material.
The collar 74 includes an obliquely dis- posed surface 88 in axial opposed relationship to the surface 84, and this collar also includes a cylindrical, axially extending tubular extension 90 closely received within the retainer opening 40. The external surface of the exten- sion 90 is sealingly engaged by the seals 56, 58 and 60, and the collar includes a bearing surface 92 engaging the thrust bearing 44, Fig. 1.
Internally, the extension 90 includes a plu- rality of spline recesses 94, and from Fig. 2 it will be appreciated that the circumferential dimension of the spline recesses 94 is significantly less than the circumferential dimension of the spline projections 68 defined on the sleeve 24, thus, a lost motion exists between the sleeve 24 and the extension 90 with respect to rotational displacement between the sleeve and extension.
A plurality of conical rings 96 are em- bedded in the elastomer material 76 intermediate the collars 72 and 74, and the rings are in spaced relationship wherein elastic material is located therebetween. These washers aid in stiffening the elastic bearing assembly with respect to angular deflection of the conduits 12 and 14, and also aids in keeping the elastic material 76 centered during rotational deformation thereof.
The bearing unit 26 will be fabricated sep- arately from the sleeve 24 in molding equipment capable of injecting and forming the elastomeric material about the collars 72 and 74 and the bearing assembly is bolted to the sleeve flange 64 by screws 82. The bearing assembly 26 and the flange 64 together constitute bearing support structure for the sleeve 24, and the sleeve is maintained within the body 10 by the retainer 20.
It will be appreciated that as the bolts 22 mounting the retainer upon the body are tightened the axial dimension between the thrust bearings 36 and 44 decreases, which imposes a frictional force upon the flange 64 and collar 74. The final value of this frictional force will depend upon the spacing between the shoulders 48 and 50 as determined by the preload spacers 52, and by utilizing spacers of various thickness the degree of preloading on the bearing assembly can be accu- rately regulated. Of course, due to the resilient nature of the material 76 the preloading of the thrust bearings against the bearing assembly will cause some radial outward deformation of the elastomer, and the extent of preloading is such as to insure that the maximum rotational deformation permitted occurs within the elastic material prior to the sleeve rotating upon the bearings 36 and 44 relative to the body and retainer.
In use, the joint 10 interconnects the con- i; 3 GB2031 091A 3 the spirit and scope of the invention. For instance, the projections 68 and recesses 94 can take many forms, such as defining projections on extension 90 to be received within 70 recesses in a split collar mounted on sleeve 24. Of course, such keying means must permit the relative rotational lost motion desired between sleeve 24 and extension 90, but the exact form of the keying structure is not 75 critical.
duits 12 and 14, and fluid within the conduits will not escape in view of the sealed and assembled relationships between the body 18, retainer 20 and sleeve 24. For instance, in the event of failure of the bearings 36 or 44 the seal 56 will prevent the escape of fluid from the joint, and the seal 58 will prevent fluid from leaking into the joint in the event the joint is located many hundreds of feet below the water surface. The seal 60 aids in sealing the joint against fluid leakage internally or externally.
A radial clearance exists between the sleeve 24 and the collar extension 90, which permits limited angular deviation of the conduits 12 and 14 with respect to each other, and resiliency provided by the elastic material 76 permits such angular deviation.
When the conduits 12 and 14 are subjected to relative rotational torque forces such torque forces will cause the spline projections 68 to rotate within the extension recesses 94, and due to the lost motion provided by the dimensional characteristics of this spline relationship such rotational forces will cause a twisting or deformation within the elastic material 76 through collar 72 which provides a biasing force counter to the torque forces resisting such torque forces without imposing destructive stresses upon the joint. Relative rotational displacement about the axis of the conduits up to approximately 20′ is possible solely through deformation within the elastic material 76.
If more than a 20 rotational displacement between the conduits 12 and 14 occurs the projections 68 will engage the side of the recesses 94 producing a positive engagement between the sleeve and extension which will rotate the extension 90 and collar 74. At such occurence both the sleeve 24 and entire bearing assembly 26 will be rotated through a like degree of rotation upon the bearings 36 and 44, and the conduit 12 may be rotated a full 360′, or more, relative to the conduit 14 without imposing destructive forces upon the swivel joint.
It will therefore be appreciated that the swivel joint of the invention provides an initial biasing torque force for relative rotational conduit movement of 20′ or less, and yet produces a bearing support permitting complete rotation without overstressing the joint components. The apparatus provides a biasing coun- ter torque at all displacements and the torque forces required to assure sequential operation of the elastic deformation and bearing rotation are accurately regulated by use of the spacers 52. The aforedescribed equipment is of a highly dependable nature capable of maintaining an efficient sealing relationship even though bearing failure occurs.
It is appreciated that various modifications to the inventive concepts may be apparent to those skilled in the art without departing from 130

Claims (13)

1. A conduit swivel joint comprising, in combination, a first body having an axial passage, a second body having an axial passage coaxial with said first body passage, conduit attachment means defined on said bodies for attaching conduits thereto in communication with the associated passage, and support means interconnecting said bodies for relative rotative movement about the passage axes thereof, said support means including elastomer means permitting limited relative rotative movement by deformation of said elastomer material and including bearing means permitting bearing supported relative rotative movement of said bodies, and torque regulating means mounted upon said first body regulating the torque required to pro- duce bearing supported relative rotative movement of said bodies after deformation of said elastomer material.

2. In a conduit swivel joint as in claim 1 wherein said support means includes a pair of annular axially spaced collars having an elastomeric material bonded thereto.

3. In a conduit swivel joint as in claim 2, a plurality of annular ring members in axially spaced relationship embedded into said elas- tomeric material intermediate said collars.

4. In a conduit swivel joint as in claim 2, a bearing engaging surface defined on at least one of said collars for engagement with a bearing defined on said first body, said torque regulating means axially positioning said bearing defined on said first body to vary the degree of frictional engagement thereof with said bearing engaging surface.

5. In a conduit swivel joint as in claim 1, intermeshing lost motion keying means defined on said second body and support means to produce positive rotation of said support means relative to said first body upon a predetermined relative angular deflection occuring between said first and second bodies.

6. A conduit swivel joint comprising, in combination, a body having a passage defined therein having an axis, a first bearing surface defined on said body transversely disposed to said axis and concentric thereto, a tubular sleeve having an axial passage coaxial and communicating with said body passage, conduit attachment means defined on said body and sleeve for attachment of conduits in corn- 4 GB 2 03109 1 A 4 munication with the respective passages thereof, an annular retainer having a central opening releasably mounted upon said body in axial opposed relation to said bearing surface, fastening means releasably mounting said retainer upon said body, a second bearing surface defined on said retainer concentric to said body axis and in axial opposed relation to said first bearing surface, said sleeve ex- tending through said retainer opening, and an elastic sleeve support interposed between and engaging said bearing surfaces elastically supporting said sleeve upon said body for relative rotation thereto about said body axis, said sleeve support including an elastomeric material internally deforming to permit limited relative rotation between said body and sleeve under initial torque forces prior to said entire sleeve support rotating relative to both of said bearing surfaces.

7. In a conduit swivel joint as in claim 6, means associated with said retainer adjustably regulating the torque required to rotate said sleeve support relative to both of said bearing surfaces.

8. In a conduit swivel joint as in claim 7 wherein said fastening means comprises threaded bolts extending in a direction substantially parallel to the axis of said body and said means regulating the torque required to rotate said sleeve support comprises spacers determining the axial spacing between said body and retainer and the axial spacing between said first and second bearings.

9. In a conduit swivel joint as in claim 6, said support including an outwardly radially extending flange defined on said sleeve engaging said first bearing surface and a tubular assembly including a first annular collar fixed relative to said flange, a second annular collar axially spaced from said first collar engaging said second bearing surface, and an elastomer bonded to said collars.

10. In a conduit swivel joint as in claim 9 wherein said second collar includes a tubular extension extending into said retainer opening, and seal means interposed between said extension and said retainer opening.

11. In a conduit swivel joint as in claim 6, keying means defined on said sleeve and sleeve support adapted to directly transfer torque between said sleeve and support upon predetermined rotational displacement of said sleeve about said body axis occuring.

12. In a conduit swivel joint as in claim 11, said keying means including intermeshing spline recesses and spline projections, said spline recesses being of substantially greater dimension than said projections in the circum- ferential direction to produce a circumferential lost motion permitting elastic deformation in said sleeve support prior to rotation of said sleeve relativeto both said first and second bearing surfaces.

13. A conduit swivel joint constructed and arranged substantially as herein described with reference to and as illustrated in the accompanying drawings.
Printed for Her Majesty’s Stationery Office by Burgess & Son (Abingdon) Ltd-1 980. Published at The Patent Office, 25 Southampton Buildings, London, WC2A 1 AY, from which copies may be obtained.
i 4 z

GB7922014A
1978-09-28
1979-06-25
Conduit swivel joint

Expired

GB2031091B
(en)

Applications Claiming Priority (1)

Application Number
Priority Date
Filing Date
Title

US05/946,707

US4236737A
(en)

1978-09-28
1978-09-28
Conduit swivel joint

Publications (2)

Publication Number
Publication Date

GB2031091A
true

GB2031091A
(en)

1980-04-16

GB2031091B

GB2031091B
(en)

1983-01-19

Family
ID=25484850
Family Applications (1)

Application Number
Title
Priority Date
Filing Date

GB7922014A
Expired

GB2031091B
(en)

1978-09-28
1979-06-25
Conduit swivel joint

Country Status (6)

Country
Link

US
(1)

US4236737A
(en)

JP
(1)

JPS5848792B2
(en)

FR
(1)

FR2437561A1
(en)

GB
(1)

GB2031091B
(en)

NL
(1)

NL178029C
(en)

NO
(1)

NO154026C
(en)

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Assignee
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EP0037113A2
(en)

*

1980-04-01
1981-10-07
Fmc Corporation
Constant motion swivel joint

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Assignee
Title

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(en)

*

1981-10-05
1984-08-28
The B. F. Goodrich Company
Swivel

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*

1982-10-21
1985-01-01
Aeroquip Corporation
Vibration attenuating coupling

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1983-09-19
1985-05-14
Caterpillar Tractor Co.
Weld joint structure for an elastomeric flexible coupling

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1984-07-24
1988-11-04
Technip Geoproduction

METHOD AND DEVICE FOR MAINTAINING SEALING BETWEEN PARTS THAT CAN MOVE IN RELATION TO ONE ANOTHER

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1989-08-29
Sundstrand Corporation
Elastomeric shaft coupling for concentric shafts

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1988-09-20
Sundstrand Corportion
Torque transmitting elastomeric shaft coupling with spline backup

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Aeroquip Corporation
Flexible quick disconnect coupling with vibration absorbing member

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Duramax, Inc.
Torque control device for rotary mine drilling machine

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1995-04-18
1998-08-11
Continental Emsco Co.
Flexible joint for facilitating bending of tubular segments

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1997-08-13
1999-09-14
Continental Emsco Company
Elastomeric subsea flex joint and swivel for offshore risers

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*

1999-03-15
2003-02-25
William L. Hinks
Shaft bearing-seal assembly penetrating the wall of a pressure vessel

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*

2000-03-09
2004-12-28
William Lloyd Hinks
Shaft bearing-seal assembly penetrating the wall of a pressure vessel

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2000-05-30
2002-05-14
Wellstream, Inc.
Swivel joint and method for connecting conduits

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2004-12-20
2006-09-15
Metso Minerals Tampere Oy

Hydraulically controllable cone crusher and axial bearing combination for the crusher

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2009-12-18
2013-01-29
Eaton Corporation
Compliant conduit connector

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2016-05-24
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Rotorcraft bearing with rotation slip joint

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Articulated fluid delivery system with remote-controlled spatial positioning

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1978

1978-09-28
US
US05/946,707
patent/US4236737A/en
not_active
Expired – Lifetime

1979

1979-06-25
GB
GB7922014A
patent/GB2031091B/en
not_active
Expired

1979-07-10
NL
NLAANVRAGE7905387,A
patent/NL178029C/en
not_active
IP Right Cessation

1979-09-11
JP
JP54116637A
patent/JPS5848792B2/en
not_active
Expired

1979-09-27
NO
NO793107A
patent/NO154026C/en
unknown

1979-09-27
FR
FR7924076A
patent/FR2437561A1/en
active
Granted

Cited By (2)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

EP0037113A2
(en)

*

1980-04-01
1981-10-07
Fmc Corporation
Constant motion swivel joint

EP0037113A3
(en)

*

1980-04-01
1982-07-28
Fmc Corporation
Constant motion swivel joint

Also Published As

Publication number
Publication date

NL178029C
(en)

1986-01-02

NO793107L
(en)

1980-03-31

US4236737A
(en)

1980-12-02

FR2437561A1
(en)

1980-04-25

FR2437561B1
(en)

1984-12-28

NL178029B
(en)

1985-08-01

JPS5547087A
(en)

1980-04-02

JPS5848792B2
(en)

1983-10-31

GB2031091B
(en)

1983-01-19

NO154026C
(en)

1986-07-02

NL7905387A
(en)

1980-04-01

NO154026B
(en)

1986-03-24

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Legal Events

Date
Code
Title
Description

1995-02-22
PCNP
Patent ceased through non-payment of renewal fee

Effective date:
19940625

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